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COMMERCIAL IN CONFIDENCE

Page 4

1.2.1  Initialising the Setpoint

The instrument is provided with a safety lock to prevent it from controlling until the setpoint has been
set. This lock is automatically released the first time that the setpoint is changed from the instrument
front panel. If it is required to initialise a new instrument (or after the parameters have been reset), this
lock may be released remotely by performing the following sequence:

tempbyte = (read byte at ModBus address 0125 hex)
tempbyte = tempbyte OR  0x02 {i.e. set bit 1}
(write tempbyte back to ModBus address 0125 hex)

Note that this sequence is only required to unlock the instrument from its reset state - it is not
necessary to perform this sequence each time the setpoint is changed. The other bits within this byte
are used internally and 

must not be modified.

1.2.2  Ramp Byte

The 

Ramp Byte

 holds bits which show what stage of a ramp/soak sequence is currently active:

 

bit 1 set = in ramp phase, display periodically flashing   SPr

 

bit 2 set = in soak phase, display periodically flashing  Soak

 

bit 3 set = sequence finished, control dormant, display flashes  Stop

 

bit 6 set = Holdback LED on front display lit 

(9500P only)

note that these bits are mutually exclusive (except the holdback bit), and the flashing display is of lower
priority than the displays recorded by the 

Display Byte. 

If no bit is set, the instrument is not in a

ramp/soak sequence.  If the unit has finished a ramp but no soak time is specified (SOAK= - - ) bit 2
will remain set.

The other bits in the 

Ramp Byte 

are used internally by the instrument. 

The 

Ramp Byte 

must not be

written to - unpredictable and possibly dangerous instrument behaviour will result.

1.2.3  Display Byte

The 

Display Byte

 records the message currently being shown on the instrument display, and also

mirrors the state of the SP LED s - note that although these may be read by a remote program, their
values may change rapidly in real time. Due to the time lag in processing communications messages it
may not be possible to exactly mimic the display on a remote screen - particularly for short cycle times.

The hi nibble conveys the following meanings:

 

Bit 7 set = SP2 LED lit

 

Bit 6 set = SP1 LED lit

 

Bit 5 set = add FAIL display to other indications

 

Bit 4 set = SP3 LED lit 

(9500 only)

The low nibble of the Display Byte indicates the current alternating message being displayed, thus

after the top 2 bits are masked off

, the following values indicate the display message:

0x01 = PARK / temp
0x02 = -AL- / temp
0x03 = TUNE / temp
0x23 = TUNE / FAIL
0x04 = TUNE / ATSP / temp
0x05 = HAND / heat power ratio
0x25 = HAND / FAIL
0x26 = INPT / FAIL
0x27 = DATA / FAIL

These messages take display precedence over any others. If one of the 

Display Byte 

messages is

indicated, the remote program must ignore the state of the 

Ramp Byte

.

Summary of Contents for 3300P

Page 1: ...COMMERCIAL IN CONFIDENCE CAL 3300 9300 9400 9500 P MODBUS RTU COMMUNICATIONS GUIDE 7th September 2000 ISSUE 1 10 Doc 33034 Iss 002...

Page 2: ...lers would perform before transmitting the new data out over the bus to the instrument The CAL controllers assume that the values they receive have been checked against limits and are valid no further...

Page 3: ...ing and should not occur however they will be interpreted as if bit 2 was 0 Bit 4 is used to indicate reserved messages see the section Security Messages below Two types of bit value may exist those w...

Page 4: ...s linear Also note that while linear input is selected the display of values on the instrument is effected by the setting in DECP not Disp The instrument provides no error checking on values transmitt...

Page 5: ...wer priority than the displays recorded by the Display Byte If no bit is set the instrument is not in a ramp soak sequence If the unit has finished a ramp but no soak time is specified SOAK bit 2 will...

Page 6: ...ending on disp selection min LoSc max HiSc Ofst 2 0083 RW 3 6 Degrees 10 LIN normal inc dec see separate details for limits Band 2 0085 RW 3 6 Degrees 10 LIN normal inc dec min 0 1 max 25 of Sensor Ma...

Page 7: ...1 0190 RW 3 6 No scaling step by 1 min 0 max 100 PL 2 1 0191 RW 3 6 No scaling step by 1 min 0 max 100 SP2 A 1 0192 RW 3 6 0 none 1 dvhi 2 dvlo 3 band 4 fshi 5 fslo 6 cool 9500P 7 EOP SP2 b 1 0193 RW...

Page 8: ...with degC to decF if required if unit 1 Read hi 2 007A R 3 Read hi 10 LIN Read lo 2 007C R 3 Read lo 10 LIN Data Ct A 2 0432 R 3 CtA 25 Data Ct B 2 0434 R 3 CtB 25 Data Ct 1 2 0436 R 3 Ct1 25 Data Ct...

Page 9: ...sc Rev 3 1 03E5 RW 3 6 0 3d 1 3r Set 3 2 02E8 RW 3 6 Degrees 10 LIN step 0 1 min 0 0 max 2500 When LIN sensor selected max 9999 Hys 3 2 02EA RW 3 6 Hys3 10 LIN step 0 1 min 0 1 max 100 of HiSc Note Th...

Page 10: ...ing the enter program mode message causes the push buttons on the instrument to be locked out This feature prevents potentially dangerous conditions arising from simultaneous adjustment of the instrum...

Page 11: ...n 5 15 4 not used any value may be sent xx 5 not used any value may be sent xx 6 not used any value may be sent xx 7 CRC lo byte 8 CRC hi byte The security byte must be set to 5 prior to this message...

Page 12: ...is not a valid readable bit an error response code 2 invalid address is returned otherwise the following response is sent Byte No Meaning Value hex 1 Slave address xx 2 ModBus Function code read coil...

Page 13: ...Starting Address MSB xx 4 Starting Address LSB xx 5 Data MSB xx 6 Data LSB xx 7 CRC lo byte 8 CRC hi byte The normal response is the same as the message An error response code 2 illegal address will b...

Page 14: ...ceives full message correctly but cannot act on it An error response as detailed under each message heading is returned as follows Byte No Meaning Value 1 Slave address xx 2 Original ModBus Function c...

Page 15: ...erformed 7 Repeat from step 2 for the next byte of the message until all bytes have been processed 8 The final contents of the CRC register is the CRC value to use 9 When the CRC is placed in the mess...

Page 16: ...to read the setpoint the various sections of this code would normally be held in separate functions and would be optimised for better speed but this example shows the thought process involved note als...

Page 17: ...he reply if the Function code is 03 and the CRC is correct The CALController stores the Setpoint internally in 10th degree units so the value can be computed as setpoint reply 3 8 reply 4 10 or in a l...

Page 18: ...rrectly the whole sequence must be re started from message 1 1st Message byte 0 Slave address xx byte 1 Function code write register 06 hex always byte 2 Register Address high byte 03 hex always byte...

Page 19: ...ce for the values to take effect 1st Message byte 0 Slave address xx byte 1 Function code write register 06 hex always byte 2 Register Address high byte 03 hex always byte 3 Register Address low byte...

Page 20: ...D 2 Detailed later dependant on other functions CYC 2 ON OF 0 1 9 9 10 81 Seconds LEVEL 2 Function Values Limits SP1 P 0 100 Read only HAND OFF 1 100 PL1 100 0 PL2 100 0 SP2 A NONE DV HI DV LO BAND FS...

Page 21: ...LOSC SP LK So set point 1 is adjustable between the current high and low scale settings as long as the setpoint lock is off OFST INPT LIN CYC T ON OF 0 0 to 25 of sensor full scale DECP 0 1 to 81 0 0...

Page 22: ...DISP 1 0 to 250 0 1 0 to 199 9 If you change SP3 A at any time then the value of SET 3 defaults to zero There are a number of functions which when changed can have an effect on the values of other fun...

Page 23: ...ting C to F Here is a list of the functions that are effected by a C to F conversion and if a relative or absolute conversion is needed FUNCTION CONVERSION NOTES Set point 1 Absolute HISC Absolute LOS...

Page 24: ...99 9 400 0 LIN1 0 400 0 0 400 0 LIN2 25 400 25 0 400 0 LIN3 0 3000 0 0 999 9 LIN4 250 3000 199 9 999 9 LIN5 0 3000 0 0 999 9 LIN 9500 0 9999 N A N A TABLE 2 MIN MAX SENSOR FULL SCALE DEGREE F SENSOR M...

Page 25: ...0 0 400 0 LIN1 0 400 0 0 400 0 LIN2 0 400 0 0 400 0 LIN3 0 3000 0 0 999 9 LIN4 0 3000 0 0 999 9 LIN5 0 3000 0 0 999 9 LIN 9500 0 9999 N A N A TABLE 4 HI SC LO SC DEFAULT SETTINGS DEGREE F SENSOR DEFA...

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