Osaka F 500 User manual

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

F 500/ F 500-RS

DIGITAL ELECTRONIC

REFRIGERATION UNITS

CONTROLLER

USER MANUAL

FOREWORD

This manual contains the information

necessary for the product to be installed

correctly and also instructions for its

maintenance and use; we therefore recommend

that the utmost attention is paid to the

following instructions and to save it.

This document is the exclusive property of

OSAKA which forbids any reproduction and divulgation , even

in part, of the document, unless expressly authorized.

OSAKA SOLUTIONS, SL reserves the right to make any formal

or functional changes at any moment and without any notice.

Whenever a failure or a malfunction of the device may cause

dangerous situations for persons, thing or animals, please

remember that the plant has to be equipped with additional

devices which will guarantee safety.

OSAKA and its legal representatives do not assume any

responsibility for any damage to people, things or animals

deriving from violation, wrong or improper use or in any case

not in compliance with the instrument’s features.

INDEX

INSTRUMENT DESCRIPTION

1.1

GENERAL DESCRIPTION

1.2

FRONT PANEL DESCRIPTION

PROGRAMMING

2.1

FAST PROGRAMMING OF SET POINT

2.2

STANDARD MODE PARAMETERS PROGRAMMING

2.3

PARAMETER PROTECTION USING THE PASSWORD

2.4

CUSTOMIZED MODE PARAMETER PROGRAMMING

(PARAMETERS PROGRAMMING LEVEL)

2.5

RESET PARAMETERS TO DEFAULT VALUE/LEVEL

2.6

KEYBOARD LOCK FUNCTION

2.7

SETTING THE CURRENT TIME AND DATE

2.8

PROGRAMMING EVENTS TO OCCUR AT DEFINED

TIMES

2.9

DISPLAYING HACCP ALARMS

INFORMATION ON INSTALLATION AND USE

3.1

PERMITTED USE

3.2

MECHANICAL MOUNTING

3.3

ELECTRICAL CONNECTIONS

3.4

ELECTRICAL WIRING DIAGRAM

FUNCTIONS

4.1

ON / STAND-BY FUNCTION

4.2

“NORMAL”MODE, “ECONOMIC” MODE AND “TURBO”

MODE

4.3

MEASURING AND DISPLAY

4.4

DIGITAL INPUTS

4.5

OUTPUTS AND BUZZER CONFIGURATION

4.6

TEMPERATURE CONTROL

4.7

COMPRESSOR PROTECTION FUNCTION AND DELAY

AT POWER-ON

4.8

DEFROST CONTROL

4.8.1

AUTOMATIC DEFROST STARTS

4.8.2

MANUAL DEFROST

4.8.3

END DEFROST

4.8.4

DEFROSTS IN EVENT OF EVAPORATOR PROBE

ERROR

4.8.5

DEFROST DISPLAY LOCK

4.9

EVAPORATOR FANS CONTROL

4.10

ALARM FUNCTIONS

4.10.1

TEMPERATURE ALARMS

4.10.2

EXTERNAL ALARMS (DIGITAL INPUTS)

4.10.3

OPEN DOOR ALARM

4.11

HACCP FUNCTION (ALARM RECORDING)

4.11.1

HACCP TEMPERATURE ALARMS

4.11.2

HACCP POWER FAILURE (BLACK-OUT) ALARMS

4.11.3

HACCP ALARMS FROM DIGITAL INPUTS

4.12

FUNCTION OF KEYS “STAND-BY” AND “DOWN/AUX”

4.13

EVENTS THAT CAN BE PROGRAMMED TO OCCUR

AT DEFINED TIMES

4.14

RS 485 SERIAL INTERFACE

4.15

ACCESSORIES

4.15.1

PARAMETERS CONFIGURATION BY “KEY USB”

4.15.2

“X2” REMOTE DISPLAY

PROGRAMMABLE PARAMETERS TABLE

PROBLEMS , MAINTENANCE AND GUARANTEE

6.1

SIGNALLING

6.2

CLEANING

6.3

GUARANTEE AND REPAIRS

TECHNICAL DATA

7.1

ELECTRICAL DATA

7.2

MECHANICAL DATA

7.3

MECHANICAL DIMENSIONS, PANEL CUT-OUT AND

MOUNTING

7.4

FUNCTIONAL DATA

7.5

INSTRUMENT ORDERING CODE

1 - INSTRUMENT DESCRIPTION

1.1 - GENERAL DESCRIPTION

The F 500 / F 500-RS model is a digital electronic microprocessor

controller that can be used typically for refrigeration applications. It

has temperature control with ON/OFF regulation and control of

defrosting at defined times (Real Time Clock Defrosting), at time

intervals, by arrival at temperature or by length of time of continuous

compressor operation through stopping the compressor, electric

heating or hot gas/cycle inversion. The appliance has special

defrosting optimisation functions and functions to reduce the

amount of energy used by the controlled system.

The instrument has up to 4 relay outputs, up to 4 inputs

configurable for PTC, NTC and Pt1000 temperature probes, and 2

digital inputs. It can also be equipped with an internal buzzer for

acoustic notification of alarms; an RS485 serial communication

interface with MODBUS-RTU communication protocol; and a

calendar clock.

The clock allows you to define the times of defrosting events,

auxiliary output switching, switching of the regulating set point,

instrument on/off, etc. (max 14 daily and 98 weekly events)

Another feature of the calendar clock version of the instrument is

that it has the HACCP function which can store the last 10 alarms

that have occurred (alarm type, start, duration and temperature

peaks)

The 4 outputs can be used to control the compressor or the

temperature control device, the defroster, the evaporator fans and a

configurable auxiliary device (Light, Alarm, second evaporator, etc.)

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

The 4 temperature probe inputs can be used to regulate cell

temperature, measure evaporator temperature, and measure two

auxiliary temperatures (e.g. product temperature, condenser

temperature, temperature of a second evaporator, etc.).

Two digital inputs are always available and, as an alternative to the

Pr3 and Pr4 temperature probe inputs, two other digital inputs can

be configured.

The 4 digital inputs can be configured to execute various functions

such as cell door signal, defrost commands, selecting a different

temperature-regulating set point, reporting an external alarm,

activating a continuous cycle, activating the auxiliary output, etc.

1.2 - FRONT PANEL DESCRIPTION

1 - Key SET : Used for setting the Set point (press and release) and

for programming the function parameters (hold pressed for 5 sec.)

In programming mode is used to enter in parameters edit mode and

confirm the values. In programming mode it can be used together

with the UP key to change the programming level of the

parameters.

When the keyboard is locked it can be used together with the UP

(hold pressed for 5 sec.) key to unlock the keyboard.

2 - Key DOWN/Aux : In programming mode is used for decreasing

the values to be set and for selecting the parameters. In normal

mode it can also be programmed via the parameter “t.Fb” to carry

out other functions (hold pressed for 1 sec.) such as activating the

Aux output, starting up the continuous cycle, etc. (see functions of

keys STAND-BY and Down).

3 - Key UP/DEFROST : In normal mode can be used to start/stop

manual defrosting (hold pressed for 5 sec.). In programming mode

is used for increasing the values to be set and for selecting the

parameters. In programming mode can be used togetherwith Key

SET to change parameters level. Pressed together with the Key

SET for 5 sec. allow the keyboard unlock

4 - Key STAND-BY : Used (press and release) for visualising the

instrument variables (measured temperatures etc.). In programming

mode can be used to come back in normal mode (hold for 2 sec.).

In normal mode it can also be programmed via the parameter “t.UF”

to carry out other functions (hold pressed for 1 sec.) such as

turning on and off (stand-by) the device, activating the Aux output,

starting up the continuous cycle, etc. (see functions of keys STAND-

BY and Down).

5 - Led SET : In normal mode it serves to indicate when a key is

pressed. In programming mode indicates the programming level of

the parameters.

6 - Led OUT - COOL : Indicates the output status (compressor or

temperature control device) when the istrument is programmed for

cooling operation; on (on), off (off) or inhibited (flashing).

7 - Led OUT - HEAT : Indicates the output status (compressor or

temperature control device) when the istrument is programmed for

heating operation; on (on), off (off) or inhibited (flashing).

8 - Led DEFROST : Indicates defrosting in progress (on) or

drainage time in progress (flashing)

9 - Led FAN : Indicates fan output status on (on), off (off) or

delayed after defrosting (flashing)

10 - Led ALARM : Indicates the alarm status (on), off (off) and

silenced or memorized (flashing)

11 - Led AUX : Indicates AUX output status on (on), off (off) or

inhibited (flashing)

12 - CLOCK LED : Indicates that the internal clock is running. If

flashing slowly, it means that there is a clock error (clock chip not

working). If flashing rapidly, it means the clock battery is drained.

13 - Led Stand-By: Indicate the Stand-by status.

2 -PROGRAMMING

2.1 -FAST PROGRAMMING OF SET POINT

Press the Key SET then release it and the display will show “SP”

(or “SPE”) alternating with the set value.

To change it press the UP key to increase the value or DOWN to

decrease it.

These keys increase or decrease the value one digit at a time, but if

the button is pressed for more than one second the value increase

or decreases rapidly, and after two seconds pressed, the speed

increases even more to all the desired valued to be reached rapidly.

However, through par. "t.Ed” is possible to determine whether and

which Sets are set with the fast mode by button SET.

The parameter is programmable with a value between oF and 4

which means that:

oF = Nothing is set with the Key SET (the SET pressed and

released has no effect)

1 = can be adjusted only SP (normal)

2 = can be adjusted only SPE (economic)

3 = can be adjusted both SP and SPE

4 = can be adjusted the active set (SP or or SPE)

5 = can be adjusted SP and SPH (“Turbo” or ind. “Heating”)

6 = can be adjusted SP, SPE and SPH

For example, if the parameter "t.Ed" = 1 or 3, the procedure is as

follows:

Press Key SET then release it and the display will show "SP"

alternate value.

To modify press key UP or DOWN to increase the value to

decrease.

If there is only the Set Point 1 ("t.Ed" = 1) once the desired value by

pressing the SET button to exit the Set programming mode.

If is also programmable the EconomicSet Point ("t.Ed" = 3) by

pressing and releasing the SET key again the display will show

"SPE" alternate to the set value.

To modify press key UP or DOWN like Set “SP”.

When the desired value is set press the Key SET to exit from Set

Point programming mode.

Exiting the Set mode is achieved by pressing the SET key or

automatically if no key is pressed for 10 seconds. After that time the

display returns to the normal function mode.

2.2 - STANDARD MODE PARAMETERS PROGRAMMING

To access the instrument’s function parameters when password

protection is disable, press the Key SET and keep it pressed for

about 5 seconds, after which the display will visualised the code

that identifies the first group of parameters (“ ]SP “).

Using the UP and DOWN keys, the desired group of parameters

can be selected and pressing the SET key, the display will show the

first parameter code of the group.

Using the UP and DOWN keys, the desired parameter can be

selected and pressing the SET key, the display will alternately show

the parameter code and its setting that can be changed with the UP

and DOWN keys.

Once the desired value has been set, press the Key SET again: the

new value will be memorised and the display will show only the

code of the selected parameter.

Pressing the UP and DOWN keys, it is possible to select another

parameter and change it as described.

To come back at the group selection mode keep the STAND-BY

key pressed for 1 sec. until will show the code group.

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

Pressing the UP and DOWN keys, it is possible to select another

group of parameters, another parameter and change it as

described.

To exit the programming mode, do not press any key for about 30

seconds, or keep the STAND-BY key pressed for 2 sec. until it exits

the programming mode.

2.3 - PARAMETER PROTECTION USING THE PASSWORD

The instrument has a parameter protection function using a

password that can be personalised, through the “t.PP” parameter.

If one wishes to have this protection, set the password number

desired in the parameter “t.PP”. When the protection is activate,

press the SET key to access the parameters and keep it press for

about 5 seconds, after which the display will show “r.P” .

At this point press SET, the display show “0”, using the UP and

DOWN keys, set the password number programmed and press the

Key SET.

If the password is correct, the display will visualise the code that

identifies the first group of parameters and it will be possible to

program the instrument in the same ways described in the previous

section.

Protection using a password can be disabled by setting the

parameter “t.PP” = oF.

Note: If the Password gets lost, just swith off and on the instrument

supply, push SET key during the initial test and keeping the key

pressed for 5 seconds.

In this way it’s possible to have access to all the parameters, verify

and modify the par. “t.PP”.

2.4 - CUSTOMIZED MODE PARAMETER PROGRAMMING

(PARAMETERS PROGRAMMING LEVEL)

The password protection hides all the configuration parameters

behind a factory set password to avoid unwanted changes being

made to the programming of the controller.

To make a parameter accessible without having to enter the

password when “t.PP” password protection is activate follows this

procedure.

Enter the programming using the Password “t.PP” and select the

parameter which is desired to be accessible with no password

protection.

Once the parameter has been selected, if the SET led is blinking,

this means that the parameter is programmable by entering the

password (it’s then “protected”) if it’s instead on, this means the

parameter is programmable without password (not protected).

If you want to change the accessibility of the parameter push SET

key, keep it pressed and press together also the key UP.

The led SET will change its state indicating the new access level of

the parameter (on = not protected; blinking = protected by

password).

In case some parameters are not protected, when one tries to have

access at the programming, the display will show all the parameters

not protected and the par. “r.P” (through which will be possible to

have access to the “protected” parameters).

With regard to setting unprotected parameters, an exception is

HACCP alarm-related parameters (“H.01”, “H.02”, etc. which are

visible only when there are alarms stored in memory) whose display

level can be set via the “t.HA” parameter.

If “t.HA” = 1, parameters relating to stored HACCP alarms are

visible only within the ]HA group (which can be displayed like all

other groups without a password if t.PP=oF or by entering the set

t.PP password).

If “t.HA” = 2, parameters relating to stored HACCP alarms are

visible both within the "]HA" group (which can be displayed like all

other groups without a password if t.PP=oF or by entering the set

t.PP password) and as unprotected parameters if the t.PP

parameter is given a password.

2.5 - RESET PARAMETERS TO DEFAULT VALUE/LEVEL

The instrument allows the reset of the parameters to values

programmed in factory as default.

To restore to the values of default the parameters set the value -48

to “r.P” password request.

Once confirmed the password with the Key SET the display it

shows "---" for 2 sec. therefore the instrument effects the

parameters reset.

2.6 - KEYBOARD LOCK FUNCTION

On the instrument it’s possibile to lock completely the keyboard.

This function is particularly useful when the regulator is reachable

by the users and it’s desired to avoid any modification.

To activate the keyboard lock it’s enough program the par. “t.Lo” to

a different value to oF.

The value program to this parameter it is the time of inactivity of the

keys afterwhich the keyboard will be locked.

Insofar not pressing any key for the time "t.Lo" the instrument

automatically disable the normal functions of the keys.

When the keyboard is lock, if any of the key is pushed, on the

display will appear “Ln” to indicate the active lock.

To unlock the keyboard it’s enough to contemporarily push Key

SET and UP and keep them pushed for 5 sec., afterwhich the label

“LF” will appear on the display and all the keys functions will be

available again .

2.7 - SETTING THE CURRENT TIME AND DATE

If the instrument is supplied with the internal calendar/clock, this

must be enabled and programmed to the current time and day of

the week using the “c.CL” parameter, and to the current date using

the “c.dt” parameter.

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

After selecting the “c.CL” parameter, press the SET key repeatedly

to cycle through the following in the order shown:

“h.” and the hours (e.g. “h.14”)

“n.” and the minutes (e.g. “n.52”)

“d.” and the day of the week (e.g. “d.1”)

The days are numbered as follows:

d. 1 = Monday

d. 2 = Tuesday

d. 3 = Wednesday

d. 4 = Thursday

d. 5 = Friday

d. 6 = Saturday

d. 7 = Sunday

+ the option oF which considers the clock to be disabled.

After selecting the “c.CL” parameter, press the SET key repeatedly

to cycle through the following in the order shown:

“y” and current year (ex. “y.10)

“M” and current month (ex. “M.05”)

“d” and current date (ex. “d.31”)

When the internal clock is running, the Clock LED will come on.

If it is on and steady, this indicates that, since the time the clock

was enabled, the power supply to the instrument has never failed

and therefore the current time is presumably correct.

If it is flashing, this indicates that at some point since the clock was

enabled the power supply has certainly failed and therefore the

current time may not be correct.

In this condition, pressing any key cancels the signal and the LED

returns to solid (on and not flashing).

2.8 - PROGRAMMING EVENTS TO OCCUR AT DEFINED TIMES

All events are programmable through the 14 parameters “c.01” ...

“c.14” contained in the “ ]cE” group.

Exactly as for current time, because the parameters for time-related

functions require multiple values to be input, these parameters are

programmed in the following way:

After selecting the desired parameter, press the SET key repeatedly

to cycle through the following:

“h.” and the hours (e.g. “h.13”)

“n.” and the minutes (e.g. “n.40”)

“d.” and the day of the week (e.g. “d.1”)

“t.” and the type of event to be executed at the programmed time

(e.g. t.1).

The days are numbered as follows:

d. 1 = Monday

d. 2 = Tuesday

d. 3 = Wednesday

d. 4 = Thursday

d. 5 = Friday

d. 6 = Saturday

d. 7 = Sunday

d. 8 = every day

d. 9 = Monday, Tuesday, Wednesday, Thursday, Friday

d. 10 = Monday, Tuesday, Wednesday, Thursday, Friday, Saturday

d.11 = Saturday and Sunday

d.oF = no day (event disabled)

The instrument offers 14 event programming parameters, allowing a

maximum of 14 x 7 = 98 weekly events to be scheduled (using d.8).

For the types of events that can be programmed, see the relevant

section.

2.9 - DISPLAYING HACCP ALARMS

The so-called HACCP (Hazard Analysis and Critical Control Points)

function causes the instrument to record the last 10 alarms that

have occurred together with information that is useful for

determining the criticality of the alarm.

The function is available only for instruments that have the calendar

clock.

The following HACCP alarms can be stored in memory:

HACCP alarm code

Alarm

Maximum temperature alarm H1

Minimum temperature alarm L1

Maximum temperature alarm H2

Minimum temperature alarm L2

Power failure alarm (black-out)

Alarm from digital input

These alarms are displayed by the same display procedure as for

the programming parameters by accessing parameters “H.01” ...

“H.10” contained in the ]HA group.

Exactly as for current time and events, because the parameters

relating to time-related functions require multiple values to be input,

these parameters are programmed in the following way:

After selecting the desired parameter, press the SET key repeatedly

to cycle through the following:

- Alarm type (A. = see HACCP alarm codes)

- Alarm start time HACCP ( y. =year, M. =month, d. =day, h.

=hours, n. =minutes)

- HACCP alarm duration ( E. = hours, e. = minutes)

- Critical temp. (max. peak if Hi alarm or min. peak if Lo or other

alarm)

The instrument automatically sorts these parameters from most

recent (H.01) to oldest (H.10) whenever an alarm is recorded or

deleted.

If more than 10 alarms occur, the instrument deletes the information

about the oldest alarm by overwriting it with the most recent alarm.

When this occurs the instrument increments by one the value of the

“H.dL” parameter by which it is possible to display the number of

alarms the instrument has been forced to delete when these

exceeded the permitted memory.

After selecting the parameter for the alarm which the user wishes to

display, if the label flashes this indicates that the alarm has never

been displayed (and therefore not recognised).

To recognise it, simply access the parameter via the SET key and

display it.

The next time the parameter label is displayed it will be shown solid

(not flashing).

If the alarm is still ongoing at the time of its display, the data are

displayed but the alarm is not recognised.

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

In the event of unrecognised (and therefore still ongoing) HACCP

alarms, the instrument displays the message “HAC” alternating

with the normal display.

Within the parameter the data will be displayed sequentially as the

SET key is repeatedly pressed.

The alarm is deleted by holding down the Down key for more than 5

seconds while one of the data of the alarm is displayed.

Similarly the value of the “H.dL” parameter can be reset by holding

down the Down key for more than 5 seconds while the value is

being displayed)

For HACCP alarm configuration and operation, see the relevant

section.

3 - INFORMATION ON INSTALLATION AND USE

3.1 - PERMITTED USE

The instrument has been projected and

manufactured as a measuring and control device

to be used according to EN60730-1 for the

altitudes operation until 2000 ms. The use of the

instrument for applications not expressly permitted

by the above mentioned rule must adopt all the necessary

protective measures.

The instrument CANNOT be used in dangerous environments

(flammable or explosive) without adequate protection.

The instrument used with NTC 103AT11 probe (identifiable by the

printed code “103AT-11” visible on the sensor part) or Pt1000 is

compliant with standard EN 13485 ("Thermometers for measuring

the air and product temperature for the transport,storage and

distribution of chilled, frozen, deep-frozen/quick-frozen food and ice

cream”) with the following classification: [EN13485 air, S, A, 1,-

50°C +90°C]

Remember that the end user must periodically checks and verify the

thermometers in compliance with standard EN 13486.

The installer must ensure that EMC rules are respected, also after

the instrument installation, if necessary using proper filters.

Whenever a failure or a malfunction of the device may cause

dangerous situations for persons, thing or animals, please

remember that the plant has to be equipped with additional devices

which will guarantee safety.

3.2 - MECHANICAL MOUNTING

The instrument, in case 78 x 35 mm, is designed for flush-in panel

mounting. Make a hole 71 x 29 mm and insert the instrument, fixing

it with the provided special brackets. We recommend that the

gasket is mounted in order to obtain the front protection degree as

declared. Avoid placing the instrument in environments with very

high humidity levels or dirt that may create condensation or

introduction of conductive substances into the instrument. Ensure

adequate ventilation to the instrument and avoid installation in

containers that house devices which may overheat or which may

cause the instrument to function at a higher temperature than the

one permitted and declared. Connect the instrument as far away as

possible from sources of electromagnetic disturbances such as

motors, power relays, relays, solenoid valves, etc.

3.3 - ELECTRICAL CONNECTION

Carry out the electrical wiring by connecting only one wire to each

terminal, according to the following diagram, checking that the

power supply is the same as that indicated on the instrument and

that the load current absorption is no higher than the maximum

electricity current permitted. As the instrument is built-in equipment

with permanent connection inside housing, it is not equipped with

either switches or internal devices to protect against overload of

current: the installation will include an overload protection and a

two-phase circuit-breaker, placed as near as possible to the

instrument, and located in a position that can easily be reached by

the user and marked as instrument disconnecting device which

interrupts the power supply to the equipment. It is also

recommended that the supply of all the electrical circuits connected

to the instrument must be protect properly, using devices (ex. fuses)

proportionate to the circulating currents. It is strongly recommended

that cables with proper insulation, according to the working voltages

and temperatures, be used. Furthermore, the input cable of the

probe has to be kept separate from line voltage wiring. If the input

cable of the probe is screened, it has to be connected to the ground

with only one side. We recommend that a check should be made

that the parameters are those desired and that the application

functions correctly before connecting the outputs to the actuators so

as to avoid malfunctioning that may cause irregularities in the plant

that could cause damage to people, things or animals.

3.4 - ELECTRICAL WIRING DIAGRAM

4 - FUNCTIONS

4.1 - ON / STAND-BY FUNCTION

The instrument, once powered up, can assume 2 different

conditions:

- ON : means that the controller uses the control functions.

- STAND-BY : means that the controller does not use any control

function and the display is turned off except for the Stand-by led.

If there is no power, and then power returns, the system always

sets itself in the condition it was in before the black-out.

The ON/Stand-by function can be selected:

- Pressing the Key STAND-BY for at least 1 sec. if the parameter

"t.UF" = 3 or 5

-Pressing the key DOWN/AUX for at least 1 sec. if the parameter

"t.Fb" = 3 or 5

- using the digital input if the parameter “i.xF” = 7 or 15

- by programming a programmable event through the clock (if

present)

4.2 - "NORMAL", "ECONOMICAL" AND "TURBO" OPERATING

MODES

The instrument can be used to enter up to 3 different regulating set

points: Normal - “SP”; Economical - “SPE”; and “Turbo” - “SPH”.

Associated with each of these is the corresponding differential

(hysteresis): normal - “r.d”; Economical - “r.Ed”; and “Turbo” -

“r.Hd”.

Switching between the various modes can be automatic or manual

"NORMAL-ECONOMICAL" MODE OPERATION

Can be used where it is necessary to switch between two different

operating temperatures (e.g. day/night or working days/holidays)

NORMAL/ECONOMICAL mode can be selected manually:

–by pressing the STAND-BY key if parameter "t.UF" = 2

–by pressing the DOWN/AUX key if parameter "t.Fb" = 2

–by a digital input if parameter “i.xF” = 6

NORMAL/ECONOMICAL mode can be selected automatically:

–after the door has been closed for time “i.Et” (switching from

Norm. to Eco)

–when the door is opened if the SPE set point is active from

parameter “i.Et” (switching from Eco to Norm.)

- after the door has been closed for time “i.tt” since activation of the

SPE set point from parameter “i.Et” (switching from Eco to Norm.)

- at times defined through the clock by programming events t.6

(switch to Eco mode) and t.7 (switch to normal mode). For further

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OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

information see the section on programming events through the

clock.

Example of automatic switching between Eco mode and normal

mode. During working hours the door is frequently opened and the

controller stays in normal mode. When the door has not been

opened for time “i.Et”, the controller switches to Eco mode. As soon

as the door is opened again, the controller reverts to normal mode.

This function requires use of a digital input configured as “i.xF” = 1,

2 or 3 (door open input)

If “i.Et” = oF, selection of Eco/Norm. mode via the digital input

configured as door, is deactivated.

If “i.tt” = oF, switching the mode from Eco to Normal due to time-out

is deactivated.

(1) –The time i.Et is reset every time the door is opened. In the

case shown, the door is always closed.

(2) –The time i.tt stops when the door is opened and the instrument

immediately switches to "normal" mode. In the case shown, the

door is always closed.

When in economical mode, the label “Eco” is displayed.

If “i.dS”= Ec, in economical mode the instrument displays “Eco” all

the time. Otherwise the label "Eco" appears approx. every 10

seconds alternating with the normal display set by the “i.dS”

parameter.

Selection of Eco mode is always also combined with the function of

turning off the Auxiliary output if used as a window light (“o.Fo”= 3).

"TURBO –NORMAL –ECONOMICAL" MODE OPERATION

"Turbo" mode can be selected manually:

–by pressing the STAND-BY key if parameter "t.UF" = 4

–by pressing the DOWN/AUX key if parameter "t.Fb" = 4

–by a digital input if parameter “i.xF” = 8

"Turbo" mode can be selected automatically:

- on leaving Eco mode (only if “r.HC” = C3)

- every time the instrument is switched on (only if “r.HC” = C3 and

Pr1 > SPE+r.Ed)

The instrument quits "turbo" mode automatically at the end of time

“r.tC” or manually using the programmed command (key or digital

input) and the instrument always returns to normal mode.

"Turbo" mode can be applied manually, for example when the user

wishes to lower the temperature of the products quickly after

loading the refrigerator.

However, "Turbo" mode is applied automatically to restore product

temperature at the end of economical mode.

Setting “r.HC” = C3 gives the following operating cycle:

(1) - The time i.Et is reset every time the door is opened and in the

case shown the door is always closed.

(2) –The time i.tt stops when the door is opened and the instrument

immediately switches to "Turbo" mode. In the case shown, the door

is always closed.

When switched on, the instrument starts in the mode it was in when

it was switched off ("Normal" or “Eco”) unless the temperature at

switch-on is > SPE+r.Ed. In this case (see fig.) a "Turbo" cycle is

automatically initiated.

After time “r.tC” the instrument automatically enters "Normal" mode.

If the door is opened frequently the instrument stays in "Normal"

mode. If however it is not opened for time “i.Et” it automatically

switches to "Eco" mode.

The instrument remains in "Eco" mode until the door is opened

again or, if set, until the time-out “i.tt”.

On leaving "Eco" mode the instrument therefore runs a "Turbo"

cycle to allow product temperature to be restored, after which it

reverts to "Normal" mode and so on.

When “turbo” mode is on, this is indicated by the characters “trb”

shown on the display, alternating with the normal display.

The Set point "SP" can be set with a value between the

programmed value in parameter. “S.LS” and the programmed

value in parameter “S.HS”.

The Set point "SPE" can be set with a value between the

programmed value in parameter. “SP” and the programmed value

in parameter “S.HS”.

The Set point "SPH" can be set with a value between the

programmed value in parameter. “S.LS” and the programmed

value in parameter “SP”.

Note: in the examples that follow, the Set point is generally

indicated as "SP" and the histeresis as “r.d”, how when operating

the instrument will work according to the Set point and histeresis

selected as actives.

4.3 - MEASURING AND DISPLAY

All the parameters concerning measuring are contained in the group

“]In”.

Via the parameter “i.SE” it is possible to select the type of probes

that one wishes to use and which can be: thermistores PTC KTY81-

121 (Pt), NTC 103AT-2 (nt) or Pt1000 (P1).

Via the parameter “i.uP”, it is possible to select the temperature

unit of measurement the desired measurement resolution (C0=°C /

1° ; C1=°C / 0.1° ; F0= °F / 1°; F1= °F / 0.1°).

The instrument allows the measuring to be calibrated, that can be

used for re-calibrating the instrument according to application

needs, through the parameters “i.C1” (for the input Pr1),“i.C2” (for

the input Pr2) ,“i.C3” (for the input Pr3) ,“i.C4” (for the input Pr4).

The functions carried out by Pr2, Pr3 and Pr4 probes is defined by

the parameters “i.P2”, “i.P3” and “i.P4”

This parameters can be configured for the following functions:

= EP - Evaporator probe: used to managing the defrost and the

evaporator fans (see relative functions).

= Au - Auxiliary Probe: can be used as a display-only probe but it is

also possible to assign temperature alarms to it (possible uses:

product probe, anti-freeze probe, etc.)

r.E d

SPE

SP r.d

P r1

Tem p .

"E C O "

i.E t

"N o rm ." tim e

D O O R

"N o rm ."

D A Y (s ho p o pe n) N IG H T (s ho p c lo se ) D A Y (s ho p o pe n)

S P H

Te m p.

r.H d

tim e

P r1

r.tC

SP r.d

S P E r.E d

r.tC

"T u rb o" "N o rm ." "E C O "

i.E t (1 ) i.tt (2)

"T urbo "

r.H C = C 3

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

= cd - Condenser Probe: can be used as a display-only probe but it

is also possible to assign temperature alarms to it in order to give

alarms relating to condenser malfunction (e.g. dirty/clogged

condenser).

= 2E - Evaporator Probe 2: the probe performs the functions

described later for controlling defrosts in the second evaporator in

twin-evaporator plants.

= dG - Digital input (see digital inputs functions)

If probe Pr2 and/or Pr3 and/or Pr4 is/are not used, set the relative

parameter “i.P2”and/or “i.P3” and/or “i.P4” = oF.

It is not possible to program more parameters for the same function

(priority goes to lowest input).

Using the parameter “i.Ft”, it is possible to set the time constant for

the software filter for measuring the input values to be able to

reduce the sensitivity to measurement disturbances (increasing the

time).

Through the parameter “i.dS”, it is possible to fix the normal

visualisation on the display that can be the measurement of the

probe Pr1 (P1), the measurement of the probe Pr2 (P2), the

measurement of the probe Pr3 (P3), the measurement of the probe

Pr4 (P4), the active set point value (SP), the label “Eco” when the

instrument is in Eco mode (Ec) or it can have the numerical display

switched off (oF).

Through the parameter “i.CU”, it is possible to program an

measure offset that will be applied to the temperature show on the

display (only if i.dS”= P1, P2, P3, P4, Ec).

The normal visualisation on the display is established by par. “i.dS”,

but it is possible to visualise all the variables and the highest and

lowest Pr1 peak measurement values in rotation by quickly

pressing and releasing Key STAND-BY.

The display will alternately show the code that identifies the variable

and its value.

The variable are:

“Pr1” - Pr1 temperature

“Pr2” - Pr2 temperature

“Pr3” - Pr3 temperature ( on/oF state if is progr. as digital input )

“Pr4” - Pr4 temperature ( on/oF state if is progr. as digital input )

“Lt” and the lowest Pr1 peak temperature

“Ht” and the highest Pr1 peak temperature

and , if real time clock is enable:

“h.” - current hour

“n.” - current minutes

“d.” - current day of the week

When the instrument is switched off, peak values are always re-set.

However, it is also possible to reset these values if the instrument is

switched on by using the DOWN key hold for 3 sec. during peak

visualization.

The display will show “---” and peak memory will be reset.

The exit of this visualisation mode occurs automatically 15 seconds

after the last pressing on the Key STAND-BY.

Please remember that visualisation of the Pr1 probe can be

changed by the defrosting display lock function, by using the

parameter “d.dL” (see defrost function).

4.4 - DIGITAL INPUTS

All the parameters concerning digital inputs are contained in the

group “]In”.

The instrument has 2 digital inputs for voltage-free contacts whose

function is defined by the parameters “i.1F” and “i.2F” and whose

action can be delayed by the time period set in the parameters

“i.1t” and “i.2t”.

In addition, the instrument may have 2 further digital inputs for

voltage-free contacts as an alternative to the measurement inputs

Pr3 and Pr4.

In order to use these inputs digitally, the user must set the relevant

parameter “i.P3” or “i.P4” = dG.

The function performed by these digitally configured inputs is

defined by the parameters “i.3F” and “i.4F” while the action is

instantaneous and cannot be delayed.

The parameters “i.1F” , “i.2F”, “i.3F”, “i.4F” can be configured for

the following functions:

= 0 - No function

= 1 -Cell door opening by contact normally open: on closing the

digital input the instrument visualises oP and the variable set in

parameter “i.dS” alternately on the display. With this function mode,

the action of the digital input also activates the time that can be set

in parameter "A.oA" after which the alarm is activated to signal that

the door has been left open.

= 2 -Cell door opening with fan stop by contact normally open: on

closing the digital input the fans are stopped and the instrument

visualises oP and the variable set in parameter “i.dS” alternately on

the display. With this function mode, the action of the digital input

also activates the time that can be set in parameter "A.oA" after

which the alarm is activated to signal that the door has been left

open and the fan restart.

= 3 - Cell door opening with compressor and fan stop by contact

normally open: similar to “i.Fi” = 5 but with fan and compressor stop.

At the intervention of the door open alarm alarm compressor and

fan restarts.

= 4 - External alarm signal by contact normally open: on closing the

digital input the alarm is activated and the instrument visualises AL

and the variable set in parameter “i.dS” alternately on the display.

= 5 - Signalling of external alarm with disablement of all the control

outputs by contact normally open: on closing the digital input all the

control outputs are disabled, the alarm is activated and the

instrument visualises AL and the variable set in parameter “i.dS”

alternately on the display.

= 6 - Selecting the active set point (SP/SPE) with contact normally

open: on closing the digital input the temperature set point “SPE” is

activated. When instead the input is open the set point “SP” is

active.

= 7 - Switching on/switching off (Stand-by) of instrument by contact

normally open: on closing the digital input the instrument is

switched on while it is placed in Stand-by when opened.

= 8 - "Turbo" cycle activation command with normally-open contact:

closing the input starts a "turbo" cycle.

= 9 - Remote command of auxiliary output AUX with normally-open

contact: closing the input activates the auxiliary output as described

in the "o.Fo" = 2 operating mode of the auxiliary output.

= 10 - Disable recording of HACCP alarms: closing the input

disables the recording of HACCP alarms.

= 11 - Reset recording of HACCP alarms: closing the input deletes

all recorded HACCP alarms.

= 12 - External "PrA" alarm notified and "ot" output deactivated by

normally-open contact: closing the input deactivates the output

configured as "ot" and activates the alarm, and the instrument

display shows PrA alternating with the variable defined by the “i.dS”

parameter.

= 13 - External “HP” alarm notified and “ot” output deactivated by

normally-open contact: closing the input deactivates the output

configured as “ot” and activates the alarm, and the instrument

display shows HP alternating with the variable defined by the “i.dS”

parameter.

= 14 - External “LP” alarm notified and “ot” output deactivated by

normally-open contact: closing the input deactivates the output

configured as “ot” and activates the alarm, and the instrument

display shows LP alternating with the variable defined by the “i.dS”

parameter.

= 15 - Forcing a programmed Switch-on/Switch-off (Stand-by)

event - closing the input switches the instrument from the ON state

to the Stand-by state and vice versa, until the next event. Therefore,

if switch-on/stand-by events are programmed using the clock, action

by this mode forces the state until the next event.

= 16 - Defrosting start command with contact normally open: on

closing the digital input 1 (and after the “i.ti” time) a defrosting cycle

is activated.

= 17 - Defrosting end command with contact normally open: on

closing the digital input 1 (and after the “i.ti” time) a defrosting cycle

is ended if in progress or defrosting is inhibited.

= -1, -2, -3, etc. - Like function with positive values but with function

logic reversed (contact normally closed)

Note: Where multiple digital inputs are configured for the same

function, the instrument will treat the contacts as if they were

parallel (and consequently regard the result as an OR function).

4.5 - OUTPUTS AND BUZZER CONFIGURATION

All the parameters concerning outputs configuration are contained

in the group “]Ou”.

The instrument outputs can be configured by the relative

parameters “o.o1” , “o.o2”, “o.o3”, “o.o4”.

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

The outputs can be configured for the following functions:

= ot - to control the compressor or however, the temperature control

device

= dF - to control the defrosting device (1)

= Fn - to control the evaporator fans

= Au - to control the auxiliary device

= At - to control a silenceable alarm device through a contact that is

normally open, and then closed when the alarm sounds

= AL - to control an alarm that cannot be silenced through a contact

that is normally open and closed when the alarm sounds.

= An - to control an alarm with a memory function through a contact

that is normally open and closed when the alarm sounds.

= -t - to control a silenceable alarm device through a contact that is

normally closed, and then open when the alarm sounds.

= -L - control an alarm that cannot be silenced through a contact

that is normally closed and open when the alarm sounds.

= -n - to control an alarm with a memory function through a contact

that is normally closed and open when the alarm sounds.

= on - Output on when the instrument is in on state. This mode can

be used to control lights, non-misting resistance on room door or

other utilities

= HE - to control an heating device in neutral zone control mode

(“r.HC” = nr).

= 2d - to control the defrosting device n. 2

= L1 - Light output managed by Normal / Economy mode.

This output will be on in Normal mode and off in Economy mode

operation.

= L2 - Internal Light output managed by digital input. This output will

be on when door is opened (only if “i.xF”= 1, 2, 3).

= oF - Disabled output

The function carried out for auxiliary output (par. desired output =

Au) is defined by the parameter “o.Fo” and the function is

conditioned by the time set in parameter “o.tu”.

The parameter “o.Fo” can be configured for the following functions:

= oF - Auxiliary output not active

= 1 - Temperature control output delayed with contact normally

open: the auxiliary output is activated with delay that can be set on

the parameter "o.tu" compared to the output configured as ot. The

output is then turned off at the same time as the ot output is

disabled. This function mode can be used as a command for a

second compressor or for all other working utilities according to the

same ot output conditions, but which must be delayed after the start

up of the compressor to avoid excess electricity absorption.

= 2 - Activation by front key (STAND-BY or DOWN/AUX) or by

digital input or by Real Time Clock : the output is activated by

pressing the keys STAND-BY or DOWN/AUX suitably configured

(“t.UF” or “t.Fb” = 1), by a digital input suitably configured (“i.xF” = 9)

or by Real Time Clock event. The commands by keys or digital

inputs have a bi-stable function. Which means that when first

pressed, the output is activated while the second is disabled. In this

mode, the AUX output can be turned off automatically after a certain

time that can be set on the parameter "o.tu". With "o.tu" = oF the

output is activated and deactivated only manually, using the key

(STAND-BY or DOWN/AUX). Differently, the output, once activated,

is turned off automatically after the set time. This function can be

used, for example, as a cell light command, for non-misting

resistance or other utilities.

If are programmed activation / deactivation events of the auxiliary

output by Real Time Clock the action of the keys or digital input

mode force output status until the next event.

The internal buzzer (if present) can be configured by par. “o.bu” for

the following functions:

oF = Buzzer always disable

1= Buzzer signal active alarms only

2= Buzzer signal key pressed only (no alarm)

3= Buzzer signal active alarms and key pressed

4.6 - TEMPERATURE CONTROL

Most of the parameters for temperature control functions are found

in the “]rE” group.

The instrument's method of regulation is of ON/OFF type acting on

the "ot"- and "HE"-configured outputs in response to: the reading of

the Pr1 probe; the active set point(s) “SP” (or “SPE” and/or

“SPH”); the intervention differential “r.d” (or “r.Ed” and/or “r.Hd”);

and the operating mode “r.HC”.

Via the parameter “r.HC” the following functions can be obtained:

= C (Cooling) or = H (Heating)

As regards the operating mode programmed in the "r.HC"

parameter, the regulator automatically assumes that the differential

has positive values for a Refrigeration control (“r.HC”=C), negative

values for the Heating control (“r.HC”=H).

= nr (Neutral Zone or Cooling and Heating a single set point)

If the parameter “r.HC” is programmed such that “r.HC” = nr the

output configured as “ot” operates with a cooling action (as “r.HC” =

C) whereas the output configured as “HE” operates with a heating

action. In this case the regulating set point for both outputs is

whichever of SP, SPE and SPH is active, and the intervention

differential (“r.d” or “r.Ed” or “r.Hd”) is automatically assumed by the

regulator to have positive values for the cooling action, negative

values for the heating action.

= HC (Cooling and Heating with two independent set points)

Similarly, if the parameter “r.HC” is programmed such that “r.HC” =

HC, the output configured as “ot” operates with a cooling action (as

“r.HC” = C) whereas the output configured as “HE” operates with a

heating action.

In this case the regulating set point for the "ot" output is whichever

of SP, SPE and SPH is active, whereas for the output "HE" the set

point is SPH.

The intervention differential for the “ot” output will be whichever is

active (“r.d” or “r.Ed” or “r.Hd”) and the regulator will automatically

assume it has positive values (in the case of Cooling) whereas for

the output "HE" it will be "r.HD" with values assumed to be negative

(in the case of Heating).

In this mode, activating the "turbo" cycle causes the instrument to

operate with neutral-zone regulation with set point SPH.

= C3 (Cooling with three automatic modes)

r.H C =C

(ot)

O ut

P r1

Tem p.

off

ON ON

off

r.H C =H

ONON

O ut

(ot)

tim e

r.d

off

Tem p.

P r1

off

tim e

r.d

off

O ut

(ot)

(H E )

off

P r1

Tem p.

off

r.d

tim e

off

(ot)

O ut

(H E )

O ut ON

off off

P r1

Tem p.

tim e

r.d

r.H C = H C

SPH r.H d

off

ON ON

off off

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

The instrument still cools but this selection activates automatic

switching between the three modes, Normal, Eco and Turbo, as

already described in the section on operating modes.

All time protections described in the next paragraph (P.P1, P.P2,

P.P3) always act only on the output configured as “ot”.

In the event of probe error, it is possible to set the instrument so

that that the output “ot”continues to work in cycles according to the

times programmed in the parameter “r.t1” (activation time) and

“r.t2” (deactivation time).

If an error occurs on the probe the instrument activates the output

for the time “r.t1”, then deactivates it for the time “r.t2” and so on

whilst the error remains.

Programming “r.t1” = oF the output in probe error condition will

remain switched off.

Programming instead “r.t1” to any value and “r.t2” = oF the output in

probe error condition will remain switched on.

Remember that the temperature regulation function can be

conditioned by the “Compressor Protection and output delay at

power-on”, “Defrost”, “Door open” and “external alarm with outputs

disable” functions.

4.7 - COMPRESSOR PROTECTION FUNCTION AND DELAY AT

POWER-ON

All the parameters concerning compressor protection functions are

contained in the group “]Pr”.

The function “Compressor Protection” aims to avoid close start ups

of the compressor controlled by the instrument in cooling

applications.

This function foresees 3 time controls on the switching on of the

output configured as “ot” associated with the temperature regulation

request.

The protection consists of preventing the output being switched on

during the times set in the parameters “P.P1”, “P.P2” and “P.P3”

and therefore that any activation occurs only after all the times has

finished.

First control (par. “P.P1” ) foresees a delay to the output activation

(switching-on delay).

Second control (par. “P.P2” ) foresees an inhibition to the

activation of the output by a time delay that starts when the output

is turning off (delay after switching-off).

Third control (par. “P.P3” ) foresees an inhibition to the activation of

the output "Out" by a time delay that starts when the output was

turning on last time (delay between switching-on).

During the output inhibition the led OUT (Cool o Heat) blinking.

It is also possible to prevent activation of the output after the

instrument is turned on, for the time set in the parameter “P.od”.

During the power on delay phase, the display shows the indication

od, alternating with the normal visualisation.

All the functions are disabled by relative parameters = oF.

4.8 - DEFROST CONTROL

The defrosting control acts on the outputs configured as “ot” and

“dF”.

All the parameters concerning defrost control are contained in the

group “]dF”.

The type of defrosting that the instrument must carry out is set by

the parameter “d.dt” that can be programmed:

= EL - WITH ELECTRICAL HEATING (or BY STOPPING

COMPRESSOR): during defrosting, the output “ot” is deactivated

while the output “dF” is enabled.

The defrost will be by Stopping compressor if not using the “dF”

output

= in - WITH HOT GAS or INVERSION OF CYCLE:

during defrosting the outputs “ot” and “dF” are enabled

= no - WITHOUT COMPRESSOR OUTPUT CONDITIONING:

during defrosting, the output “ot” continuous to operate in order to

temperature controller while the output “dF” is enabled.

= Et - WITH ELECTRICAL HEATING AND DEFROSTING

TEMPERATURE CONTROL: during defrosting, the output “ot” is

deactivated while the output “dF” operate as evaporator

temperature control. In this mode the defrost lenght is by time-out

(time "d.dE"). During the defrost "dF" output it behaves as an

heating mode temperature control with Set = "d.tE" and fixed

differential at 1°C and operate in order to evaporator probe (EP).

4.8.1 - STARTING AUTOMATIC DEFROSTS

The automatic control of defrost occours:

- Defrosting at defined times –“Real Time Clock Defrosting”

- By interval times (regular or dynamic)

- By Evaporator temperature

- By continuous compressor running time

In order to avoid pointless defrosting the parameter “d.tS” in “d.dC”

= rt, ct, cS mode is foreseen that sets the enablement temperature

for defrosting

If the temperature measured by the probe is higher than set in the

parameter “d.tS” the defrosting is inhibited.

- Defrosting at defined times –“Real Time Clock Defrosting”

Setting the parameter “d.dC” = cL disables defrosting at intervals

(parameters “d.di” and “d.Sd”) and enables any defrosting events

programmed for defined times by means of the parameters “c.01”,

“c.02”, “c.03”, “c.04”, “c.05”, “c.06”, “c.07”, “c.08”, “c.09”,

“c.10”, “c.11”, “c.12”, “c.13” and “c.14”.

In this mode the instrument can therefore manage up to a maximum

of 14 daily defrosting events (14x7 = 98 weekly defrosts with d.8).

The events are programmable at will, including daily, using the

following settings:

d.1 = Monday ... d.7 = Sunday

d. 8 = every day

d. 9 = Mon, Tue, Wed, Thur, Fri

d.10 = Mon, Tue, Wed, Thur, Fri, Sat

d.11 = Sat and Sun

d.oF = none

Tem p .

off

tim e

r.d

off off off

ON ON

P r1

O ut

(ot)

off

P .P 2 P .P 2 P .P 2

Tem p.

tim e

r.d

ON ON

off off

P r1

O ut

(ot)

P .P 3

off

Te m p.

P .P 3 P .P 3

tim e

r.d

off off

ON ON

P r1

(ot)

O ut

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

These options make it possible to control the starting of differing

defrosts for working days and non-working days to suit one's own

requirements.

For further detailed information and programming examples, see

the section on programmable events.

Note: Remember that for “Real Time Clock Defrosting” the user

must set “d.dC” = cL and the internal clock must be present and

enabled.

- Defrost by regular interval time

Counting mode interval and automatic defrost starts is set through

the parameter "d.dC" that can be programmed:

= rt - intervals with counts the total function time (instrument on)

This mode results that currently used in the refrigerators systems.

= ct - intervals with counts only the compressor function time

(output “ot” switched on)

Mode typically used in the positive temperature refrigerators system

with defrost by stopping compressor.

= cS - the instrument carries out a defrosting cycle at each

compressor stop (i.e. at each deactivation of the output “ot”) or

however at defrost interval end with counts the total function time

(instrument on).

If "d.di" = oF the defrost happens only to the compressor stop.

This mode is used only on particular refrigerator system in which is

desired to always have the evaporator to the maximum efficiency

conditions every compressor cycle.

The automatic defrost function is activate when at the parameter

“d.di” is set the defrost interval time.

The first defrost after swiching on can be set by par. “d.Sd”

This allows to perform the first defrost to a different interval from

"d.di." time.

If it is desired that to every instrument power on a defrost cycle is

realized (as long as the conditions set in the parameters “d.tS” and

"d.tE" apply) program the par. "d.Sd" = oF.

This allows the evaporator to be permanently defrosted, even when

frequent interruptions to power supply occur that may cause the

cancellation of the various defrosting cycles.

Instead if is desired all defrost to the same interval program "d.Sd"

= "d.di."

Automatic defrost function by interval is disable when “d.di” = oF.

“Dynamic Defrost Intervals System”.

If “d.dd” = 0 the Dynamic defrost is disable.

Note: For this function is necessary to use the evaporator probe,

program “d.dC” = rt, ct or cS and set “d.dd” = any value (not 0)

This mode allows to dynamically reduce in progress the defrost

interval counting ("d.di" or "d.Sd" if is the first defrost), anticipating

so the execution of a defrost when it was necessary, in order to an

algorithm that allows to notice a decrease performances of

refrigerator thermal exchange.

Besides it maintains activates the defrost by evaporator

temperature mode that it allows a further possibility of control of the

defrost in order to notice a decrease performances of refrigerator

thermal exchange.

The algorithm allows to esteem a reduction of thermal exchange in

base to the increase of the difference of temperature between Pr1

(controlled temperature) and evaporator (“EP” probe) that is

memorized by the instrument in proximity of the Set Point.

The advantage of the “Dynamic Defrost Interval” is the possibility to

program a defrost interval time more longer than normal.

The instrument will have the possibility to anticipate the defrost if

necessary or to start the cycle after the programmed time.

If the system results set correctly is possible to to avoid many non

necessary defrosting cycles (and therefore to obtain an energy

saving) that could instead happens in the normal operation when, to

guarantee with greater certainty the system efficency , the defrost

interval is programmed at a too low time.

Example “dynamic defrost intervals system” with a reduction “d.dd”

= 40 % and end defrost by temperature.

By par.: “d.dd” - DEFROST INTERVAL PERCENTAGE

REDUCTION is possible to establish the percentage of reduction of

the remaining time to start defrost when the conditions for the

reduction happen.

If par. "d.dd" = 100% at the first increase of the memorized

difference of temperature between cell (Pr1) and evaporator (> 1 °)

a defrost start immediately

For correct functioning the instrument needs a first reference value

of the temperature difference between cell and evaporator.

Every variation of the value of the Active Set Point, of the differential

"r.d", the start of a continuous cycle or the a defrost execution

delete this reference value and any reduction will be performed

until the acquisition of a new reference value.

- Defrost by evaporator temperature

The instrument starts a defrost cycle when the evaporator

temperature (“EP” probe) goes below the “d.tF” programmed

temperature for “d.St” programmed time.

This system can be used in heat pump defrost system (in this case

the defrosting intervals are usually disabled) or to guarantee a

defrost if the evaporator reaches very low temperatures that

normally result symptomatic of a bad thermal exchange in

comparison to the normal working conditions.

If “d.tF” = -99.9 the function is disable.

The function is active in all modes of defrost operation ("d.dC" = cL,

rt, ct, cS).

- Defrost by continuous compressor running time

The instrument start a defrost cycle when the compressor is turned

on continuously for the time "d.cd”.

This function is used because the continuous operation of the

compressor for an extended period is usually symptomatic of a bad

thermal exchange in comparison to the normal working conditions.

If "d.cd" = oF the function is disabled.

The function is active in all modes of defrost operation ("d.dC" = cL,

rt, ct, cS).

4.8.2- MANUAL DEFROST

To start up a manual defrosting cycle, press the key UP/DEFROST

when it is not in programming mode and keep it pressed for about 5

seconds after which, if the conditions are correct, the led Defrost will

light up and the instrument will carry out a defrosting cycle.

To stop a defrosting cycle, press the key UP/DEFROST during a

defrost cycle and keep it pressed for about 5 sec.

4.8.3 - DEFROST ENDS

With 1 evaporator

The automatic defrosting cycle can be ended by time or, if an

evaporator probe is used (“EP” probe), when a temperature on the

evaporator is reached.

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

If the evaporator probe is not used the duration cycle is set by the

parameter “d.dE”.

If instead the evaporator probe is used the defrost cycle end when

the temperature measured by the evaporator probe exceeds the

temperature set in the parameter “d.tE”.

If this temperature is not reached in the time set in the parameter

“d.dE”, defrosting is interrupted.

If the temperature measured by the probe is higher than the

temperature set in the parameter "d.tS" and “d.tE” the defrosting is

inhibited.

Examples: defrosting A ends due to reaching of temperature “dtE”,

defrosting B ends at the end of the “d.dE” time as the temperature

“d.tE” is not reached, defrosting C does not take place as the

temperature is higher than “d.tS”.

Example of electric defrost with evaporator temperature control: The

defrost end after "d.dE" programmed time. During defrost the “dF”

output switch on/off to control evaporator temperature in heating

mode with set point “d.tE” and 1° differential (Hysteresis).

With 2 evaporators

The instrument can also be used to control defrosts in twin-

evaporator systems (and in single evaporators large enough to

require two defrost control areas) by means of two defrost outputs

and two probe inputs for the two evaporators.

Defrosts are always launched simultaneously for both evaporators

and therefore the output configured as “2d” is always activated

jointly with the output configured as “dF”.

If the two evaporator probes are not used, the end of a defrost, in

the sense of deactivation of the defrosting outputs, happens

separately at the end of the times defined individually in the

parameters "d.dE" (for output "dF" which controls evaporator 1

defroster) and "d.d2" (for output "2d" which controls evaporator 2

defroster). The instrument can also be used to control defrosts in

twin-evaporator systems (and in single evaporators large enough to

require two defrost control areas) by means of two defrost outputs

and two probe inputs for the two evaporators.

Schematic example of plant with two evaporators with electric

defrosting.

However, the end of a defrost as a controller phase always occurs

when both times come to an end.

If the user wishes each of the two evaporators to have a probe, one

input must be configured as evaporator 1 probe (“i.Px” = EP) and

one input as evaporator 2 probe (“i.Px” = 2E).

In this case the instrument controls defrosting using the following

criteria:

–defrosting is enabled when at least one of the two readings is

below the temperature set in parameter “d.tS”

–defrosting by temperature starts when at least one of the two

readings remains below the temperature set in parameter “d.tF” for

time “d.St”

–the end of defrosting, in the sense of deactivation of the defroster

command outputs "dF" and "2d" in modes "d.dt" = EL, in, does not

occur separately for the two evaporators when their respective

temperatures sensed by the probes rise above the values set in

parameter “d.tE” (evaporator 1 with probe EP) and “d.t2”

(evaporator 2 with probe 2E).

If these temperatures are not reached within the times set in

parameters “d.dE” and “d.d2” their respective defrosting actions are

interrupted.

However, the end of defrosting as a controller phase occurs when

both readings exceed the intended values (or, if the temperatures

are not reached, when their maximum durations are reached).

If the selected defrosting mode is of the type employing electric

heating and thermostatting (“d.dt” = Et), the two defrosting outputs

“dF” e “2d” behave as temperature regulators with heating function

with the respective set points = “d.tE” (evaporator 1) and “dt2”

(evaporator 2), both with hysteresis fixed at 1°C and with reference

to the respective temperatures read at both evaporators.

If one of the two evaporator probes is not enabled or has an error,

its defrosting behaves as with selection EL (so the defrosting output

during defrosting must remain activated throughout).

Notes: The "Dynamic Defrost" function and the thermostatting

function of the fans operate always and only as a function of the

probe configured as EP (evaporator 1). If the control with the twin

evaporator is not used, it is recommended to set “d.d2 = oF in order

to avoid undesirable influences on total defrost duration.

The active defrost is shown on the instrument display with the

lighting up of the DEFROST led

At the end of defrosting, it is possible to delay the new start up of

the compressor (output “ot”) at the time set in parameter “d.td” to

allow the evaporator to drain.

During this delay, the led Defrost flashes to indicate the draining

state.

4.8.4 - DEFROSTS IN EVENT OF EVAPORATOR PROBE

ERROR

In event of evaporator probe error the defrosts occur at intervals

"d.Ei" and duration "d.EE”.

In case an error occurs when the time remaining to the start or the

end of defrost it’s lower than that normally set the parameters

related to error conditions probe, the start or the end take place with

the shortest time.

The functions are provided because when the evaporator probe is

used the defrost endurance time is usually set longer than

necessary (the time “d.dE” is a security time-out) and in case is

used the "Dynamic Intervals Defrost System” the interval is usually

E v a p . 1

E v a p . 2

"d F "

"E P "

"2P "

"2 d "

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

set more longer than what is normally programmed into instruments

that do not have the function.

Notes: If the control with the twin evaporator is used, in case of

error probe 2P the time “d.d2” not switch and remain operative at

programmed value)

4.8.5 - DEFROST DISPLAY LOCK

Through par. “d.dL” and “A.dA” it’s possible to define the display

behaviour during defrost.

The “d.dL” parameter pemits the display visualization lock on the

last Pr1 emperature reading (“d.dL” = on) during all the defrost cycle

until, at the end of defrost, the temperature has not reached the lock

value or the value [”SP” + “r.d”] or is elapsed the time setted on par.

"A.dA".

Or it permits only the visualization of label “dEF” (“d.dL” = Lb)

during the defrost cycle and, after the defrost, of label “PdF” until,

at the end of defrost, the Pr1 temperature has not reached the lock

value or the value [”SP” + “r.d”] or is elapsed the time setted on par.

"A.dA".

The display will otherwise (“d.dL”= oF) continue to visualize the Pr1

temperature measured by the probe during the defrost cycle.

4.9 - EVAPORATOR FANS CONTROL

All the parameters concerning fans control are contained in the

group “]Fn”.

The control of the fans on the output configured as “Fn” depending

on determined control statuses of the instrument and the

temperature measured by the evaporator probe (EP).

In the case that the evaporator probe is not used or in error , the

output Fn is activated only depending on the parameters “F.tn”,

“F.tF” and “F.FE”.

The parameters “F.tn” e “F.tF” decides the funs functioning when

the output configured as “ot” (compressor) is off.

When output “ot” is off , it is possible to set the instrument so that

that the output “Fn”continues to work in cycles according to the

times programmed in the parameter “F.tn” (fan activation time)

and “F.tF” (fan deactivation time).

When output “ot” is switched off the instrument activates the output

“Fn for the time “F.tn”, then deactivates it for the time “F.tF” and so

on whilst the otuput “ot” remains off.

Programming “F.tn” = oF the output “Fn” in “ot” off condition will

remain switched off.

Programming instead “F.tn” to any value and “F.tF” = oF the output

“Fn” in “ot” off condition will remain switched on.

The parameter “F.FE” instead decides whether the fans must

always be switched on independently of the defrosting status

(“F.FE”=on) or switched off during defrosting (“F.FE”=oF).

In this later case, it is possible to delay the start up of the fans even

after the end of the defrosting of the time set in the parameter

“F.Fd”.

When this delay is active the led FAN flashing to signal the delay in

progress.

When the evaporator probe is used the fans, as well as being

conditioned by the parameters “F.tn”, “F.tF and “F.FE”, are also

conditioned by a temperature control.

It is possible to set the disablement of the fans when the

temperature measured by the evaporator probe is higher than the

one set in the parameter “F.FL” (temperature too hot) or when it is

lower than the one set in the parameter “F.LF” (temperature too

cold).

Notes: It is necessary to pay attention to the correct use of this fans

temperature control functions because in the typical application of

refrigeration the stop of the fans evaporator stops thermal

exchange.

The relative differential that can be set in parameter “F.dF” is also

associated with these parameters.

Remember that the fans functioning can be conditioned by the

“Door open” function by the digital input.

4.10 - ALARM FUNCTIONS

The alarm conditions of the instrument are:

- Probe errors : “E1”, “-E1”, “E2, “-E2”, “E3”, “-E3”, “E4, “-E4”

- temperature alarms: “H1”, “L1”, “H2”, “L2”

- External alarm: “AL”, “PrA”, “HP”, LP”

- Open door alarm: “oP”

The alarm functions of the instrument work on the ALARM led, on

internal buzzer (if present and programmed by par. “o.bu”) and on

output desired, if configured by the parameters “o.o1”, “o.o2”, “o.o3”

,“o.o4”,, depending on what is set on the said parameters.

Any active alarm is shown on the instrument display with the lighting

up of the ALARM led, the silenced or memorized alarm status is

shown by the ALARM led flashing .

The buzzer (if “o.bu” = 1 or 3) is activated in alarm and can be

disabled (alarm silencing) manually by pressing any key of the

instrument.

The possible selections of output parameters for the alarm

signalling function are:

= At - when one wants the output to be activated in alarm and can

be disabled (alarm silencing) manually by pressing any key of the

instrument (typical application for sound signal).

= AL - when one wants the output to be activated in alarm status

but cannot be disabled manually and are therefore only disabled

when the alarm status ceases (typical application for a light signal).

= An - when one wants the output to be activated in alarm status

and that they remain activated even when the alarm has ceased

(Alarm memory). Disablement (recognition of memorised alarm) can

only be carried out manually by pressing any key when the alarm

has ended (typical application for light signal).

= -t - when one wants the function described as At but with an

inverse function (output activated in normal condition and disabled

in alarm status).

= -L - when one wants the function described as AL but with

inverse logic (output activated in normal conditions and disabled in

alarm status).

= -n - when one wants the function described as An but with inverse

working logic (output activated in normal conditions and disabled in

alarm status).

4.10.1 - TEMPERATURE ALARMS

The instrument has two fully configurable temperature alarms, each

with a maximum and minimum threshold.

The temperature alarm functions act in response to the readings of

the probes set in parameters “A.y1” e“A.y2”, alarm thresholds set

in parameters “A.H1”, “A.H2” (maxima alarms), “A.L1”, “A.L2”

(minima alarms) and the differentials for these, “A.d1”, “A.d2”

Via the parameters “A.y1” and “A.y2” it is also possible to define

whether the alarm thresholds “A.H1”, “A.H2 “, “A.L1”, “A.L2” are

absolute or relative to the set point.

Depending on the desired operation, parameters “A.y1” and “A.y2”

can be given the following values:

= 1: Absolute values based on Pr1 with display of label (H –L)

= 2: Relative values based on Pr1 with display of label (H –L)

= 3: Absolute values based on probe Au with display of label (H –L)

= 4: Relative values based on probe Au with display of label (H –L)

= 5: Absolute values based on probe cd with display of label (H –L)

= 6: Absolute values based on Pr1 without display of label

= 7: Relative values based on Pr1 without display of label

= 8: Absolute values based on probe Au without display of label

= 9: Relative values based on probe Au without display of label

= 10: Absolute values based on probe cd without display of label

Certain parameters also allow the user to delay the enabling and

intervention of these alarms. These parameters are:

“A.P1” and “A.P2”- these are the time periods during which

temperature alarms are disabled beginning with instrument start-up

if the instrument is in an alarm condition on start-up.

F.dF

tim e

Fn off

F.LF

Tem p.

F.FL

off off

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

If there are no alarm conditions on start-up, the time period “A.Px” is

ignored.

“A.dA” - this is the time period during which temperature alarms 1

are disabled following the end of a defrost.

Note: During defrosts, and for time period “A.dA” after defrosts,

alarm 1 is disabled, whereas during defrosts alarm 2 is always

enabled.

“A.t1”, “A.t2” - these are the actuation delay times for temperature

alarms 1 and 2.

Temperature alarms 1 and 2 are enabled at the end of the alarm-

disabled time periods and activated after time periods “A.t1” and

“A.t2” when the temperature measured by the probe configured for

the alarm rises above or drops below the respective maximum and

minimum alarm thresholds.

Via the parameters “A.A1” and “A.A2” it is also possible to define

at will the action of the alarms on the regulating output and on the

alarm outputs (including buzzer).

This means for example that it is possible to change the regulating

output directly, deactivating it if there are temperature alarms on the

probes configured as “Au” (e.g. “antifreeze” function) or as “cd” (e.g.

condenser “dirty” function).

If both alarms are configured with reference to the same probe, the

instrument also allows the user to control pre-alarm notifications

(e.g. notifications that do not activate the alarm output and/or the

buzzer) and alarm notifications (which do activate the alarm output

and/or the buzzer).

The alarm thresholds will be the same as those set in parameters

“A.Hx” and “A.Lx” if the alarms absolute (“A.yx” = 1, 3, 5, 7, 9, 10).

Or will be the values [”SP”+”A.Hx”] and [”SP”+”A.Lx”] if the alarms

are relative (“A.yx” = 2, 4, 6, 8).

The maxima and minima temperature alarms can be disabled by

setting the relevant parameters "A.Hx" and "A.Lx" = oF.

Triggering of the temperature alarms causes the AL alarm signal

LED to light up, activates outputs configured with an alarm function,

and activates the internal buzzer if configured.

4.10.2 - EXTERNAL ALARMS (DIGITAL INPUTS)

The instrument can notify alarms external to the instrument by

activating one or more digital inputs configured with functions

programmed as “i.xF” = 4, 5, 12, 13, 14.

Simultaneously with the configured alarm notification (buzzer and/or

output), the instrument notifies the alarm by iluminating the ALARM

led and displaying on the display the label defined for the alarm

(AL, PrA , HP, LP) alternating with the variable defined in

parameter “i.dS”.

The “i.xF”= 4 mode produces no action on the control outputs

whereas the other modes deactivate the “ot” output or deactivate all

control outputs when the digital input intervenes.

Alarm

“ot” output (compr.)

other control outputs

(“Fn”, “dF”, “Au”, “HE”).

AL (4)

unchanged

AL (5)

OFF

PrA

OFF

unchanged

OFF

unchanged

OFF

unchanged

4.10.3 - OPEN DOOR ALARM

The instrument can signal an open door alarm by activating the

digital input with the function programmed as “i.xF” = 1, 2 or 3.

When the digital input is activated the instrument show oP and after

the delay programmed in parameter “A.oA”, the instrument signals

the alarm via the activation of the configured alarm output

(buzzer/ouput).

At the intervention of the open door alarm the inhibited output will

reactivated (fans or fans + compressor).

4.11 - HACCP FUNCTION (ALARM RECORDING)

The HACCP (Hazard Analysis and Critical Control Points) function

causes the instrument to record the last 10 alarms that have

occurred together with information that is useful for determining the

criticality of the alarm.

The function is available only for instruments that have the calendar

clock.

The parameters associated with displaying HACCP alarms are

contained in the “ ]HA” group, while those associated with the

configuration are contained in the “ ]AL” group.

The following HACCP alarms can be stored in memory:

HACCP alarm code

Alarm

Maximum temperature alarm H1

Minimum temperature alarm L1

Maximum temperature alarm H2

Minimum temperature alarm L2

Power failure (black-out) alarm

Alarm from digital input

HACCP alarms are stored provided the associated enabling

parameters are configured and the preset time configured in the

same parameter has lapsed.

It is also possible to disable alarm recording by using a suitably

configured digital input (i.xF=13) or by using the STAND-BY or

DOWN/AUX keys, suitably configured (“t.UF” or “t.Fb” = 7).

These alarms are displayed by the same display procedure as for

the programming parameters by accessing parameters “H.01” ...

“H.10” contained in the ]HA group.

Note: see section on HACCP alarm display in chapter 2

The instrument automatically sorts these parameters from most

recent (H.01) to oldest (H.10) whenever an alarm is recorded or

deleted.

If more than 10 alarms occur, the instrument deletes the information

about the oldest alarm by overwriting it with the most recent alarm.

When this occurs the instrument increments by one the value of the

“H.dL” parameter by which it is possible to display the number of

alarms the instrument has been forced to delete when these

exceeded the permitted memory.

After selecting the parameter for the alarm which the user wishes to

display, if the label flashes this indicates that the alarm has never

been displayed (therefore not recognised).

To recognise it, simply access the parameter via the SET key and

display it.

The next time it is displayed, the parameter label will be shown solid

(not flashing).

If the alarm is still ongoing at the time of its display, the data are

displayed but the alarm is not recognised and cannot be cancelled.

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

In the event of unrecognised (and therefore still ongoing) HACCP

alarms, the instrument displays the message “HAC” alternating

with the normal display.

Within the parameter the data will be displayed sequentially as the

SET key is repeatedly pressed.

The alarm can be deleted by holding down the Down key for more

than 5 seconds while one of the data of the alarm is displayed.

Its deletion is confirmed by the display indicating “---” for approx. 1

sec.

Similarly the value of the “H.dL” parameter can be reset by holding

down the Down key for more than 5 seconds while the value is

displayed.

However, if desired, all alarms can be deleted immediately by:

–holding down the STAND-BY key for 5 sec if parameter “t.UF” =

–holding down the DOWN key for 5 sec if parameter “t.Fb” = 6

–by a digital input if the relevant parameter “i.xF” = 11

–by the parameter reset function (at the password prompt r.P enter

-48).

4.11.1 - HACCP TEMPERATURE ALARMS

Via the parameters “A.r1” (for alarms H1 and L1) and “Ar.2” (for

alarms H2 and L2) it is possible to enable recording of temperature

alarms as HACCP alarms.

The same parameters can also be used to define the minimum

alarm duration that will cause the alarm to be recorded as an

HACCP alarm.

If the alarm duration is shorter than the programmed duration, the

alarm is not recorded.

If the parameters are set as = oF , recording is disabled.

For each recorded temperature alarm, the following data are stored:

- Alarm type (A. = H1 or L1 or H2 or L2)

- Alarm start time HACCP ( y. =year, M. =month, d. =day, h.

=hours, n. =minutes)

- HACCP alarm duration ( E. = hours, e. = minutes)

- Critical temp. reached (max. peak if Hi alarm or min. peak if Lo

alarm)

Example of HACCP maximum temperature alarm H1

1 = configured alarm start (in this case with A.t1 = oF)

2 = HACCP alarm recording start

3 = alarm end

Note: If there is a power failure during a temperature alarm, the

instrument records the duration of the alarm up until the moment the

power failure began.

In order to capture correct information on the temperature

conditions which the user wishes to monitor, it is recommended to

set a black-out alarm and if necessary disable the on-startup alarm

delays (parameters A.P1 and A.P2) so that if the alarm is still

ongoing when the power returns it is recorded as a new alarm on

the return of power.

4.11.2 - HACCP POWER FAILURE (BLACK-OUT) ALARMS

Is recorded only if the power failure exceeds the value set in

parameter “A.bo”.

If “A.bo” = oF the black-out alarm is never recorded.

For each recorded black-out alarm, the following data are stored:

- Alarm type (A. = bo)

- Start time ( y. =year, M. =month, d. =day, h. =hours, n. =minutes)

- Black-out duration ( E. = hours, e. = minutes)

–Temp. relative to the probe configured for temperature alarm 1

(see parameter “A.y1”) measured at end of black-out (if available; if

unavailable the display shows “---”).

Example of HACCP black-out alarm

1 = power failure

2 = min. power failure duration that will enable HACCP black-out

alarm recording

3 = return of power (alarm end)

4.11.3 - HACCP ALARMS FROM DIGITAL INPUTS

This is recorded only if the generic alarm (AL) from a digital input

configured in modes 4 or 5 continues for longer than the time set in

parameter “A.di”.

If “A.di” = oF, an alarm from a digital input is never recorded.

For each recorded alarm from a digital input, the following data are

stored:

- Alarm type (A. = AL)

- Start time ( y. =year, M. =month, d. =day, h. =hours, n. =minutes)

- Alarm duration ( E. = hours, e. = minutes)

–Temp. relative to the probe configured for temperature alarm 1

(see parameter “A.y1”) measured at end of black-out (if available; if

unavailable the display shows “---”).

Note: If the power fails during an alarm from a digital input, the

instrument records the duration of the alarm up until the moment the

power failure began.

4.12 - FUNCTIONING OF KEYS “STAND-BY”AND

“DOWN/AUX”

All the parameters concerning keyboard functions are contained in

the group “]tS”.

Two of the instrument keys, in addition to their normal functions,

can be configured to operate other commands.

The STAND-BY key function can be defined by the parameter

“t.UF” while the DOWN/AUX key function can be defined by the

parameter “t.Fb”

Both the parameters have the same possibilities and can be

configured for the following functions:

=oF - The key carries out no function.

= 1 - Pressing the key for at least 1 second, it is possible to

enable/disable the auxiliary output if configured (“o.Fo”=2).

If are programmed activation / deactivation events of the auxiliary

output by Real Time Clock the action of the keys force output status

until the next event.

= 2 - Pressing the key for at least 1 second, it is possible to select

the mode Economic/Normal in rotation. Once selection has been

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

made, the display will flash the active set point code for about 1 sec.

(SP, Eco).

If are programmed switch mode events by Real Time Clock the

action of the keys force status until the next event.

= 3 - Pressing the key for at least 1 second, it is possible to switch

the instrument from the ON status to Stand-by status and vice

versa. If switch-on/stand-by events are programmed using the

clock, action by this mode has priority over the event.

= 4 - Pressing the key for at least 1 sec activates/deactivates a

“Turbo” cycle.

= 5 - Forcing a programmed Switch-on/Switch-off (Stand-by) event

- Pressing the key for at least 1 sec switches the instrument from

the ON state to the Stand-by state and vice versa, until the next

event. Therefore, if switch-on/stand-by events are programmed

using the clock, action by this mode forces the state until the next

event.

= 6 - HACCP Alarm Reset -Pressing the key for at least 1 sec

resets stored HACCP alarms. The reset is confirmed by the display

indicating “---” for approx. 1 sec.

= 7 - HACCP Alarm Recording Disabled -Pressing the key for at

least 1 sec disables/enables recording of stored HACCP alarms.

After the selection is made the display will flash “Hon” (HACCP

alarms enabled) or “HoF” ( HACCP alarms disabled) for approx. 1

sec.

4.13 - EVENTS THAT CAN BE PROGRAMMED TO OCCUR AT

DEFINED TIMES

All events are programmable using the 14 parameters “c.01” ...

“c.14” contained in the “ ]cE” group.

After selecting the desired parameter, press the SET key repeatedly

to cycle through the following:

“h.” and the hours (e.g. “h.13”)

“n.” and the minutes (e.g. “n.45”)

“d.” and the day of the week (e.g. “d.1”)

“t.” and the type of event to be performed at the programmed time

(e.g. t.1).

Note: see section on programming event-related parameters in

chapter 2

The days are numbered as follows:

d. 1 = Monday

d. 2 = Tuesday

d. 3 = Wednesday

d. 4 = Thursday

d. 5 = Friday

d. 6 = Saturday

d. 7 = Sunday

d. 8 = every day

d. 9 = Monday, Tuesday, Wednesday, Thursday, Friday

d. 10 = Monday, Tuesday, Wednesday, Thursday, Friday, Saturday

d.11 = Saturday and Sunday

d.oF = no day (event disabled)

The 14 event-programming parameters allow a maximum of 14 x 7

= 98 weekly events to be scheduled (using d.8).

The following events can be programmed:

t.1 = switch instrument ON

t.2 = put instrument in Stand-by

t.3 = switch auxiliary output ON

t.4 = switch auxiliary output OFF

t.5 = Start defrost (to enable scheduled defrosting, also program

“d.dC” = cL)

t.6 = Switch to Eco mode (SPE)

t.7 = Switch to normal mode (SP)

A manual intervention, e.g. to change the mode (eco or normal) or

activate/deactivate the auxiliary output, is effective only until the

next scheduled event.

For example, if the instrument is in economical mode and is forced

manually to normal mode it will stay in normal mode until the next

event that switches it to economical mode.

Programming example

The user wishes to set the following:

–4 defrosts every working day at 7.00, 12.00, 17.00 and 22.00

–2 defrosts every Sunday at 7.00 and 19.00

(also program “d.dC” = cL)

–1 switch every working day from normal to economical mode at

20.00 and 1 switch from economical to normal mode at 6.00.

–no switches on Sundays

–1 switch of the auxiliary output to ON every working day at 8.00

and 1 switch every day to OFF at 21.00.

–no switches on Sundays.

Event

Par.

hour

min.

days

event

work day

defrost. 1

c.01

h.07

n.00

d.10

t.5

work day

defrost. 2

c.02

h.12

n.00

d.10

t.5

work day

defrost. 3

c.03

h.17

n.00

d.10

t.5

work day

defrost. 4

c.04

h.22

n.00

d.10

t.5

sunday

defrost 1

c.05

h.07

n.00

d.7

t.5

sunday

defrost 2

c.06

h.19

n.00

d.7

t.5

ECO

mode

c.07

h.20

n.00

d.10

t.6

nomal

mode

c.08

h.06

n.00

d.10

t.7

Aux on

c.09

h.08

n.00

d.10

t.3

Aux off

c.10

h.21

n.00

d.10

t.4

c.11... c.14

h.00

n.00

d.oF

t.oF

4.14 - RS 485 SERIAL INTERFACE

The instrument can be equipped with a RS 485 serial

communication interface, by means of which it is possible to

connect the regulator with a net to which other instruments

(regulators of PLC) are connected, all depending typically on a

personal computer used as plant supervisor.

Using a personal computer it is possible to acquire all the function

information and to program all the instrument’s configuration

parameters. The software protocol adopted is a MODBUS-RTU

type, widely used in several PLC and supervision programs

available on the market (F 500 / F 500-RS series protocol manual is

available on request).

The instrument is equipped with two terminals called D+ and D-

which have to be connected with all the namesake terminals of the

net. For the wiring operation it is advisable to adopt a screened

cable wired as in the drawing.

X 3 4 n .2X 3 4 n .1

G N D

D+ D-

X 3 4 n .N

G N D D+ G N DD-

sh ie ld

D+

In te rface

R S 4 85

G N D

D-

H O S T

(P C /P LC )

120 o h m

14 15 16 14 15 16

F 500-RS

MCX

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

The interface circuit allows the connection of up to 32 instruments

on the same line.

To maintain the line in rest conditions a 120 Ohm resistance (Rt)

must be connected to the end of the line.

If the instrument is equipped with a serial interface, the parameter to

be programmed are the following present in the parameters group

“]tS” :

"t.AS" : Address of the station. Set a different number for each

station, from 1 to 255.

Note: The baud-rate are fixed at 9600 baud.

4.15 - ACCESSORIES

The instrument is equipped with a connector that allows the

connection of some accessories described as follow.

4.15.1 - PARAMETERS CONFIGURATION BY “KEY USB”

The device has a connector that allows you to transfer the operating

parameters from the "KEY USB" device equipped with a 5-pin

connector. The "KEY USB" device is used for serial programming of

devices must have the same configuration parameters, or to save a

copy of the programming device and to transfer it quickly. The

device has a USB input, allowing connection to a PC, with which,

through the software configuration "Universal Conf" or "Osaka Set

Up" is possible to configure operating parameters.

For more information, see the "KEY USB" device manual.

4.15.2 - “X2” REMOTE DISPLAY

The device is possible to connect a remote display device via a

cable X2 can be up to 10 m start. The X2 device is powered directly

from equipment, displays temperature measured by the probe Pr1

by a 2-digit display and a half.

Refer to the user manual regarding X2 device for more information.

5 - PROGRAMMABLE PARAMETERS TABLE

Par.

Description

Range

Def.

Note

]SP

S. - parameters relative to Set Point

S.LS

Minimum Set Point

-99.9 ÷ S.HS

-50.0

S.HS

Maximum Set Point

S.LS ÷ 999

99.9

Set Point

S.LS ÷ S.HS

0.0

SPE

Eco Set Point

SP ÷ S.HS

2.0

SPH

“Turbo” Set Point (or

ind. Heating Set Point

mod. HC )

S.LS ÷ SP

-2.0

]In

i. -parameters relative to inputs

i.SE

Probes Type

Pt = PTC

nt = NTC

P1 = Pt1000

Pt / nt / P1

i.uP

Unit of measurement

and resolution (decimal

point)

C0 = °C with 1° res.

F0 = °F with 1° res.

C1 =°C with 0,1° res.

F1 = °F with 0,1° res.

C0 / F0 / C1 /

i.Ft

Measurement filter

oF ÷ 20.0

sec

2.0

i.C1

Pr1 Probe Calibration

-30.0 ÷ 30.0

°C/°F

0.0

i.C2

Pr2 Probe Calibration

-30.0 ÷ 30.0

°C/°F

0.0

i.C3

Pr3 Probe Calibration

-30.0 ÷ 30.0

°C/°F

0.0

i.C4

Pr4 Probe Calibration

-30.0 ÷ 30.0

°C/°F

0.0

i.CU

Measure offset on the

display

-30.0 ÷ 30.0

°C/°F

0.0

i.P2

Pr2 input function:

oF = No function

EP = Evaporator (1)

Au = Aux

cd = condenser

2E = Evaporator 2

oF / EP / Au /

cd / 2E

i.P3

Pr3 input function:

oF = No function

EP = Evaporator (1)

Au = Aux

cd = condenser

2E = Evaporator 2

dG = digital input

oF / EP / Au /

cd / 2E / dG

i.P4

Pr3 input function:

see i.P3

oF / EP / Au /

cd / 2E / dG

i.1F

Function and function

logic of digital input

di1:

0 = No function

1= Door open

2= Door open with fan

stop

3= Door open with fan

and compressor stop

4= External “AL” alarm

5= External “AL” alarm

with deactivation of

control outputs

6=Selection of active

Set Point (SP-SPE)

7= Switch on/ off

(Stand - by)

8= “Turbo" cycle

activation

9= Remote command

of AUX output

10= Disable recording

of HACCP alarms

-17 / -16/ -15 / -

14 / -13 / -12 / -

11 / -10 / -9 / -8

/ -7 / -6 / -5 / -4

/ -3 / -2 / -1 / 0 /

1 / 2 / 3 / 4 / 5 /

6 / 7 / 8 / 9 / 10

/ 11 / 12 / 13 /

14 / 15 /16 /17

S U P P L Y

U S B

S U P P L Y A D A P TE R

1 2 V D C A C S U P P L Y

U S B

S U P P L Y

T V R Y

ca ble 10 m M A X .

KEY USB

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

11= Reset of HACCP

alarms

12= External "PrA"

alarm

13= External “HP”

alarm

14= External “LP”

alarm

15= Forcing events

Switch on/off (Stand-

by)

16= Start Defrost

17= Stop Defrost

i.1t

Delay in acquiring

digital input di1

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

i.2F

Function and function

logic of digital input

di2: see i.1F

-17 ... 0 ... 17

i.2t

Delay in acquiring

digital input di2

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

i.3F

Function and function

logic of digital input

Pr3: see i.1F

-17 ... 0 ... 17

i.4F

Function and function

logic of digital input

Pr4: see i.1F

-17 ... 0 ... 17

i.Et

Delay to Eco mode

with door closed

oF = No function

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

i.tt

Time-out ECO mode.

oF = No function

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

i.dS

Variable visualized

normally on display:

P1 = meas. probe Pr1

P2 = meas. probe Pr2

P3 = meas. probe Pr3

P4 = meas. probe Pr4

Ec = Pr1 in normal

mode, Eco in Eco

mode

SP= Active Set Point

rE = No function

oF = Display off

P1 / P2 / P3 /

P4 / Ec / SP /

rE / oF

]dF

d. - parameters relative to defrosting control

d.dt

Defrosting Type:

EL= Electrical

heating/stop. compr.

in= hot gas/reverse

cycle

no= without compr.

output condictioning

Et= Electrical heating

with evaporator

temperature control

EL / in / no / Et

d.dC

Defrosting starting

mode:

rt = real time intervals

ct = “ot” output on time

intervals

cS = defrost every “ot”

switching off (+ rt

intervals)

cL = by real time clock

rt / ct / cS / cL

d.di

Defrosting interval

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

6.00

d.Sd

Delay first defrost after

power-on

(oF = Defrost at power-

on)

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

6.00

d.dd

Dynamic Defrost

Percentage reduction

0 ÷ 100 %

d.dE

Lenght (max.) of

defrost cycle (evap. 1)

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

20.0

d.dL

Defrost display Lock

oF= display free

on= Lock on

temperature Pr1 before

defrost

Lb= Lock on label

“dEF” (during

defrosting) and “PdF”

(during post-defrosting)

oF - on - Lb

d.tE

Defrost stop

temperature (evap. 1)

- 99.9 ÷ 999

°C/°F

8.0

d.Ei

Defrosting interval for

evaporator probe error

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

6.00

d.EE

Lengh of defrost cycle

for evaporator probe

error

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

10.0

d.tS

Defrost enable

temperature

- 99.9 ÷ 999

°C/°F

2.0

d.tF

Defrost start

temperature

- 99.9 ÷ 999

°C/°F

-99.9

d.St

Defrost start delay for

evaporator

temperature

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

1.00

d.cd

Delay start Defrost by

continuous compressor

running time

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

d.td

Compressor delay

after defrost (drainage

time)

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

d.d2

Lenght (max.) of

defrost cycle

evaporator 2

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

d.t2

Defrost stop

temperature

evaporator 2

- 99.9 ÷ 999

°C/°F

8.0

]rE

r. - parameters relative to temperature control

r.d

Differential

(Hysteresis)

0.0 ÷ 30.0

°C/°F

2.0

r.Ed

Differential

(Hysteresis) in Eco

mode

0.0 ÷ 30.0

°C/°F

4.0

r.Hd

Differential

(Hysteresis) in Eco

mode in “turbo” mode

or Heating HC mode.

0.0 ÷ 30.0

°C/°F

1.0

r.t1

Output activation time

for probe error

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

r.t2

Output deactivation

time for probe error

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

r.HC

Output operating mode:

H= Heating

C= Cooling

nr = Neutral Zone

HC =Neutral Zone with

ind. Set point

C3 = Cooling with 3 aut.

switch modes

H / C / nr / HC /

r.tC

Lengh of “turbo” cycle

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

]Fn

F. parameters relative to evaporator fans control

F.tn

Fan time activation

with ot output

(compressor) off

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

5.00

F.tF

Fan time deactivation

with ot output

(compressor) off

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

F.FL

High temperature fan

deactivation

- 99.9 ÷ 999

°C/°F

10.0

F.LF

Low temperature fan

deactivation

- 99.9 ÷ 999

°C/°F

-99.9

F.dF

Differential fan control

0.0 ÷ 30.0

°C/°F

1.0

F.FE

Fan status during

defrost

oF - on

F.Fd

Fan delay after defrost

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

]Pr

P. parameters relative to compressor protection

and power on delay

P.P1

Output “ot” delay at

switch on

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

P.P2

Output “ot” delay after

switch off

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

P.P3

Output “ot” delay

between switching-on

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

P.od

Delay outputs at power

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

]AL

A. - parameters relative to alarms

A.y1

Temperature alarms 1

Type:

1 =Pr1 absolute with

label (H - L)

2 =Pr1 Relative with

label (H - L)

3 = “Au” absolute with

label (H - L)

4 =“Au” Relative with

label (H - L)

5 = “cd” absolute with

label (H - L)

6 = Pr1 absolute

without label

7 = Pr1 relative without

label

8 = “Au” absolute

without label

9 = “Au” relative

without label

10 = “cd” absolute

without label

1 / 2 / 3 / 4 / 5 /

6 / 7 / 8 / 9 / 10

A.H1

High temperature

Alarm 1 threshold

oF / -99.9 ÷

999 °C/°F

A.L1

Low temperature

Alarm 1 threshold

oF / -99.9 ÷

999 °C/°F

A.d1

Alarms A.H1 and A.L1

Hysteresis)

0.0 ÷ 30.0

°C/°F

1.0

A.t1

Alarms A.H1 and A.L1

delay

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

A.P1

Temperature Alarms 1

delay at power on

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

2.00

A.A1

Alarms H1 e L1 actions

0 = no actions

1 = activate alarm

outputs

2 = disable control

outputs (ot e HE) but

not activate alarm

outputs

3 = disable control

outputs (ot e HE) and

activate alarm outputs

0 / 1 / 2 / 3

A.y2

Temperature alarms 2

Type: see “A.y1”

1 / 2 / 3 / 4 / 5 /

6 / 7 / 8 / 9 / 10

A.H2

High temperature

Alarm 2 threshold

oF / -99.9 ÷

999 °C/°F

A.L2

Low temperature

Alarm 2 threshold

oF / -99.9 ÷

999 °C/°F

A.d2

Alarms A.H2 and A.L2

Hysteresis)

0.0 ÷ 30.0

°C/°F

1.0

A.t2

Alarms A.H2 and A.L2

delay

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

A.P2

Temperature Alarms 2

delay at power on

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

2.00

A.A2

Alarms H2 e L2 actions

0 = no actions

1 = activate alarm

outputs

2 = disable control

outputs (ot e HE) but

not activate alarm

outputs

3 = disable control

outputs (ot e HE) and

activate alarm outputs

0 / 1 / 2 / 3

A.dA

Temperature Alarms 1

delay after defrost, and

unlock display delay

after defrost

oF/ 0.01 ÷ 9.59

(hrs.min. ) ÷

99.5

(hrs.min.x10)

1.00

A.oA

Alarm delay with door

open

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

3.00

A.r1

(#)

A.H1 and A.L1 delay to

be recorded as an

HACCP alarm

(se =oF gli allarmi non

sono mai registrati

come HACCP)

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

A.r2

(#)

A.H2 and A.L2 delay to

be recorded as an

HACCP alarm

( =oF HACCP rec.

disable)

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

A.bo

(#)

Black out alarm delay

to be recorded as an

HACCP alarm

( =oF HACCP rec.

disable)

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

A.di

(#)

Digital input alarm AL

delay to be recorded

as an HACCP alarm

( =oF HACCP rec.

disable)

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

]Ou

o. - parameters relative to configuration of

outputs and buzzer

o.o1

OUT1 function:

oF= No function

ot= Temperature

control (compressor)

dF=Defrosting(1)

Fn= fan

Au= Auxiliary

At/-t= Silenceable

alarm

AL/-L= Not silenceable

Alarm

An/-n= Memorised

alarm

on = on when

instrument switch on

HE= Heating (Neutral

zone control)

2d = Defrosting 2

L1 = light with

economy mode (on

with “SP” and off with

“SPE”)

L2 = internal light (off

with door closed and

on with door opened)

oF/ot/dF/

Fn/Au/At/

AL/An/ -t/ -L/ -

n/on/HE/2d/

L1/L2

o.o2

OUT2 function:

see “o.o1”

oF/ot/dF/

Fn/Au/At/

AL/An/ -t/ -L/ -

n/on/HE/2d/

L1/L2

o.o3

OUT3 function:

see “o.o1”

oF/ot/dF/

Fn/Au/At/

AL/An/ -t/ -L/ -

n/on/HE/2d/

L1/L2

o.o4

OUT4 function:

see “o.o1”

oF/ot/dF/

Fn/Au/At/

AL/An/ -t/ -L/ -

n/on/HE/2d/

L1/L2

o.bu

Buzzer function mode

oF = disable

1 = active alarms only

2 = key pressed only

3 = active alarms and

key pressed

oF / 1 / 2 / 3

o.Fo

Function mode

auxiliary output:

oF= No Function

1= control output “ot”

delayed

2= manual activation

by key or digital input.

oF / 1 / 2

o.tu

Time relative to

auxiliary output

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

99.5

(min.sec.x10)

]tS

t. -parameters relative to configuration of the

keyboard and serial communication

t.UF

Function mode Key

STAND-BY:

oF= No function

oF / 1 / 2 / 3 / 4

/ 5 / 6 / 7

1= Auxiliary output

command

2= Norm. / Eco mode

Selection

3= Switch on/off

(Stand-by)

4= “Turbo” cycle

command

5 = Manual Switch

on/off (Stand-by) when

set by clock

6= HACCP Alarms

Reset

7= HACCP Alarms rec.

disable/enable

t.Fb

Function mode key

Down/Aux: see “t.UF”

oF / 1 / 2 / 3 / 4

/ 5 / 6 / 7

t.Lo

Keyboard lock function

delay

oF/ 0.01 ÷ 9.59

(min.sec ) ÷

30.0

(min.sec.x10)

t.Ed

Set Visibility with fast

procedure by Key SET:

oF = None

1 = SP

2 = SPE

3 = SP e SPE

4 = Active SP

5 = SP and SPH

6 = SP, SPE and SPH

oF / 1 / 2 / 3 / 5

/ 6

t.PP

Access Password to

parameter functions

oF ÷ 999

t.HA

(#)

HACCP Alarms

Parameters level

1 = protected

parameters

2 = unprotected

parameters

1 / 2

t.AS

MODBUS Station

address (for serial

communication)

0 ÷ 255

]cL

c. - parameters relative to clock setting

c.CL

(#)

Current time and

current day of the

week:

h = hour

n = min.

d = day of the week

(d.1 = Monday ... d.7 =

Sunday)

d.oF = clock disable

h. = 0 ÷ 23

n. = 0 ÷ 59

d. = oF-1 ÷ 7

c.dt

(#)

Current date:

y = year

M = month

d = date

y. = 10 ÷ 99

n. = 1 ÷ 12

d. = 1 ÷ 31

]cE

c. parameters relative to events occour at defined

times

c.01

(#)

Event 1

h = hour

n = min.

d = day of the week

(d.1 = Monday ... d.7 =

Sunday

d. 8 = every day

d. 9 = from Monday to

Friday

d.10 = from Monday to

Saturday

d.11 = Sat. and Sun.

d.oF = no day (event

disabled)

t = event type

t.1 = Switch on

t.2 = Stand-by

h. = 0 ÷ 23

n. = 0 ÷ 50

d. = oF-1 ÷ 11

t. = oF-1 ÷ 10

h.0

n.0

d.oF

t.oF

OSAKA –USER MANUAL –F 500 / F 500-RS –V.1 –Page 1

t.3 = Switch on Aux

output

t.4 = Switch off Aux

output

t.5 = Start defrost

t.6 = Switch to Eco

mode (SPE)

t.7 = Switch to normal

mode (SP)

c.02

(#)

Event 2

c.03

(#)

Event 3

100

c.04

(#)

Event 4

101

c.05

(#)

Event 5

102

c.06

(#)

Event 6

103

c.07

(#)

Event 7

104

c.08

(#)

Event 8

105

c.09

(#)

Event 9

106

c.10

(#)

Event 10

107

c.11

(#)

Event 11

108

c.12

(#)

Event 12

109

c.13

(#)

Event 13

110

c.14

(#)

Event 14

]HA

H. - parameters relative HACCP stored alarms

(read only parameters)

111

H.01

(#)

Stored Alarm n. 1:

A. = Alarm type

y.= start year

M.= start month

d.= start date

h. = start hour

n. = start min.

E. = duration(hrs)

e. = duration (min.)

_= peak max./min.

(critical temp.) °C/°F

A. = H1/ L1/

H2/ L2/ bo/ AL

y. = 10 ÷ 99

M. = 1 ÷ 12

d. = 1 ÷ 31

h. = 0 ÷ 23

n. = 0 ÷ 59

E. = 0 ÷ 99

e. = 0 ÷ 59

_ = - 99.9 ÷

999

112

H.02

(#)

Stored Alarm n. 2

113

H.03

(#)

Stored Alarm n. 3

114

H.04

(#)

Stored Alarm n. 4

115

H.05

(#)

Stored Alarm n. 5

116

H.06

(#)

Stored Alarm n. 6

117

H.07

(#)

Stored Alarm n. 7

118

H.08

(#)

Stored Alarm n. 8

119

H.09

(#)

Stored Alarm n. 9

120

H.10

(#)

Stored Alarm n. 10

121

H.dL

(#)

Number of HACCP

alarms deleted

because exceeded

0 ÷ 100

(#) : Only in models with Real Time Clock

6 - PROBLEMS, MAINTENANCE AND GUARANTEE

6.1 - SIGNALLING

Error

Reason

Action

E1 -E1

E2 -E2

E3 -E3

E4 -E4

The probe may be

interrupted (E) or in

short circuit (-E), or may

measure a value outside

the range allowed

Check the correct

connection of the probe

with the instrument and

check the probe works

correctly

EPr

Internal EEPROM

memory error

Press Key SET

Err

Fatal memory error

Replace the instrument

or ship to factory for

repair

Other Signalling:

Message

Reason

Delay at power-on in progress

Keyboard lock

Maximum temperature alarm 1 in progress

Minimum temperature alarm 1 in progress

Maximum temperature alarm 2 in progress

Minimum temperature alarm 2 in progress

Digital input alarm in progress

PrA

Digital input alarm PrA in progress

Digital input alarm HP in progress

Digital input alarm LP in progress

Door opened

dEF

Defrosting in progress with “d.dL”=Lb

PdF

Post-defrosting in progress with “d.dL”=Lb

Eco

Eco mode active

trb

“turbo” mode active

HAC

As-yet unrecognised HACCP alarms occurring

---

Reset/delete peak values and HACCP alarms

Hon

HACCP Alarms rec. enable

HoF

HACCP Alarms rec. disable

6.2 - CLEANING

We recommend cleaning of the instrument only with a slightly wet

cloth using water and not abrasive cleaners or solvents.

6.3 - GUARANTEE AND REPAIRS

This device has a guarantee in form of repair or replacement by

manufacturing defects in materials of 12 months from the date of

purchase.

OSAKA SOLUTIONS automatically void this guarantee and is not

liable for any damages deriving from:

- Use, installation, or use and handling undue, others than

those described above and, in particular, differs from the

safety requirements established by the regulations.

- Use in applications, machines or electrical panels that do not

provide adequate protection against liquids, dust, grease and

electric shocks to the installation conditions made.

- The inexperienced handling, and / or alteration of the product.

- The installation / use in applications, machines or electrical

panels do not comply with the valid norm.

In case of defective product under warranty or out of that period, it

should contact the post sales service to perform the necessary

steps. Request document repair "RMA" (by mail or fax) and

complete it, is necessary send the RMA and the device to SAT

OSAKA by method prepaid.

7 - TECHNICAL DATA

7.1 - ELECTRICAL DATA

Power supply: 100...240 VAC +/- 10%

Frequency AC: 50/60 Hz

Power consumption: 6 VA approx.

Input/s: 4 inputs for temperature probes: PTC (KTY 81-121, 990

@ 25 °C) or NTC (103AT-2, 10K@ 25 °C) or Pt1000 (1000 @

0° C); 2 digital inputs for free voltage contacts

Output/s: up to 4 relay outputs (Out1 and Out2 are always present)

This manual suits for next models

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