Sensor Header.
Magnetic, Namur, Source, Sink.
De-coupling Header.
0.02 Hz high pass filter.
Signal Type Header.
AC, (mV) or digital logic.
Input Connector.
Freq. Input (CH1)
Up/Down Counter
Control (CH2).
+24 V Excitation.
Low Pass Filter Header.
20 kHz, 2 kHz, 200 Hz.
Comparator.
Precision switching interface.
Frequency/
Counter Header.
CH2.
Interface to Tiger Meter.
Your first choice frequency/rpm/counter input module.
Combined with the Tiger 320 Series operating system, the IF10 universal frequency/counter input module is the quick-fix interface to time varying signals. You now have a versatile and powerful monitoring and control system to perform tasks such as totalizing counts, frequency measurements, or status monitoring. Should your transducer be a magnetic pick-up outputting small AC volts or an open-collector transistor switching voltage levels, the IF10 is easily connected with a selection of configuration headers providing a variety of interface options.
Input Module
Order Code Suffix
Signal Input
IF10
Hardware Module Specifications
0-24 V DC, 0-30 V AC. CH1 frequency or UP counter.
CH2 frequency or UP / DOWN counter.
Low-pass Filter Header
None, 200 Hz, 2 kHz, 20 kHz cut off frequency.
De-coupling Header
DC component removed by 0.02 Hz high-pass filter.
Sensor Header
Optional sink / source for digital transistor or switch interface; specific Namur 2-wire proximity detector option; magnetic pick-up (AC) choice.
Signal Type Header
Choice of DC (logic) or AC signal type.
Frequency/Counter Header CH2 function select.
Frequency Response
Set by Tiger meter configuration software.
Can be as fast as 200 kHz on CH1 or CH2.
Excitation Voltage
24 V DC (50 mA) to power external transducers.
CH2 UP/DOWN Control
Figure 1 IF10 Universal Frequency/Counter Input
Module
The Tiger 320 Series controller has four input channels capable of processing almost any input signal type. The IF10 universal frequency/counter input module uses only channels 1 (CH1) and 2 (CH2).
The IF10 input module receives and conditions an AC volts or digital input signal, via pin 1, and supplies a frequency input to CH1 and CH2 in the meter for further processing. CH1 can also be configured as an UP counter via software selection in Code 2 of the meters programming software. CH2 can be configured as an UP or DOWN counter. The UP/DOWN counter control signal for CH2 is connected to pin 4. With the frequency/counter selection header set to the COUNT position, the input module provides an UP counter output to the meter for further processing. To provide a DOWN counter, pin 4 must be connected to ground (pin 3).
Selectable on-board headers provide configuration settings allowing the sensor and signal type to be selected along with high and low-pass filtering. These selectable headers give the Tiger 320 Series the flexibility to perform dual software operations such as rate of change on CH1 and totalizing on CH2.
Figure 2 IF10 Universal Frequency/Counter Input Module Signal Flow Diagram
Tiger 320 Series Meter Settings Frequency and counter settings are configured in Codes 2 and 4 of the Tiger 320 Series meters main programming mode. Channel 1 frequency settings are configured in Code 2. Channel 2 frequency and counter settings are configured in Code 4.
The following example diagrams show the various header settings and input connections required for a range of input sensor types.
Example 1 NPN Open-collector Output with Proximity Switch Figure 3 shows a 3-wire proximity switch taking +24 V excitation from the meter with an NPN open-collector signal output connected to the input module as frequency with no filtering (CH1 and CH2).
The input header is set to SINK connecting the signal output to +24 V via an on-board 10 k pull-up resistor. As the proximity switch is activated, the signal is forced to ground.
Figure 3 3-wire Proximity Switch with NPN Open-collector Output
Example 2 PNP Open-collector Output with Proximity Switch Figure 4 shows a 3-wire proximity switch taking +24 V excitation from the meter with a PNP open-collector signal output connected to the input module as frequency with no low-pass filtering (CH1 and CH2).
The input header is set to SOURCE connecting the input signal to a 10 k pull-down resistor to ground. When the proximity switch is activated, the input signal switches from 0 V to +24 V.
Figure 4 3-wire Proximity Switch with PNP Open-collector Output
Example 3 Hall Effect / Magnetic Pickup mV Input Figure 5 shows a magnetic pickup. With small AC signals a shielded cable should be used to avoid stray pickup.
Figure 5 HAll Effect / Magnetic Pickup mV Input
Example 4 TTL Input Figure 6 shows a TTL input. The TTL input requires the sensor header to be placed in the SINK position. In this example the TTL logic has a separate +5 V supply. The input module is configured as a DOWN counter on CH2 and a frequency input on CH1. This requires pin 4 connected to ground (pin 3) to select the DOWN counter option and the frequency/counter header set to COUNT. The digital option (LOGIC) is selected on the signal type header.
Figure 6 TTL Input
Example 5 Digital Input with DC Voltage Offset Figure 7 shows a digital input with voltage offset. In this situation the DC component of the signal is removed by selecting the AC option on the decoupling header. The digital input has its own supply voltage. CH1 reads frequency. CH2 is set as an UP counter.
Figure 7 Digital Input with DC Component
Example 6 Pushbutton Switch with Frequency & UP Counter Option Figure 8 shows a pushbutton switch with frequency on CH1 and the UP counter option on CH2. The low-pass filter header is set to
200 Hz to debounce mechanical contacts. Sensor type is set to SINK to pull-up the input signal to +24 V until it is switched to ground when the pushbutton is pressed.
Figure 8 Pushbutton Switch with Frequency & UP Counter
Example 7 NAMUR Sensor Figure 9 shows a NAMUR 2-wire proximity detector as an UP counter on CH2. Set the sensor header to NAMUR to ensure the detector has the correct output load (2 k pull-down resistor) and to protect the sensor at +24 V excitation voltage. The current output of these detectors vary in response to the proximity of the target metal.
Figure 9 NAMUR Sensor
One method of calibrating the IF10 input module is to use a frequency generator to apply a low and high input, while setting zero and span settings via the two-point calibration mode. Unfortunately, a frequency generator is not always available to a user in the field and, therefore, manual calibration needs to be carried out by changing the controllers scale factor.
Flow sensors such as paddlewheel and turbine types generate a known number of pulses for each unit of volume of fluid passing the rotor blade. This constant is known as the K factor and is used to determine the flow rate or total flow from the number of pulses occurring per second.
To calibrate the IF10 input module in applications using pulse, flow, and proximity sensors, the manufacturer provides either the K factor specified for the sensor, or a pulses per engineering unit chart (liters, gallons, feet, inches, meters, millimeters, revolution). From this information, The K factor can be easily converted to a scale factor and the scale factor manually entered into the controller.
Depending on the channel used and the type of input signal, follow the sequence of steps in one of the following manual calibration procedure sequence charts:
Channel 1:
As a frequency signal to the controller.
As an UP counter.
Channel 2:
As a frequency signal to the controller.
As an UP or DOWN counter.
Frequency Input
As a frequency input to the meter, a different scale factor can be used in CH1 to suit the required engineering units. To calculate and set a new scale factor, carry out the manual calibration procedure in the following sequence:
UP Counter
As with CH1 set to frequency, a different scale factor can be used in CH1 to suit the required engineering units. The configuration procedure is identical for the first five steps, but in Step 6 the frequency input signal can be selected in software as an UP counter. To calculate and set a new scale factor, carry out the manual calibration procedure in the following sequence:
Step 1
Establish the K Factor
Step 1
Establish the K Factor
Step 2
Calculate the Scale Factor
Step 2
Calculate the Scale Factor
= Scale Factor
per
minute
per
hour
Divide
scale factor
by 60
Divide
scale factor
by 3600
you
require units
per second
YES
= Scale Factor
per
minute
per
hour
Divide
scale factor
by 60
Divide
scale factor
by 3600
you
require units
per second
YES
Step 3
Enter the New Scale Factor
Step 3
Enter the New Scale Factor
Calibration Mode
Calibration Mode
Step 4
Select Display Resolution
Step 4
Select Display Resolution
Code 1
Code 1
Step 5
Select the Data Source for the Primary Display
Step 5
Select the Data Source for the Primary Display
Code 1
Code 1
Step 6 Final Settings
Step 6 Final Settings
Code 2 Select the frequency range
Code 2 Select the UP counter settings
Step 1 Establish the K Factor The manufacturer of the sensor normally provides either the K factor specified for the sensor, or a pulses per engineering unit chart, shown in pulses per liter, gallon, feet, inch, meter, millimeter, or revolution. Either way the K factor is the same:
A K factor of 250 is the same as 250 pulses/unit for a specified sensor application
Step 2 Calculate the Scale Factor From the K factor, the scale factor can be calculated by dividing K into unity.
For example:
A paddlewheel sensor generates 213 pulses per gallon of fluid passing the rotor.
If K = 213 (213 pulses/gallon)
Then
= 0.0047 gallons/pulse = the scale factor
The resultant scale factor is then entered into the controller in the calibration mode.
The controller receives the input signal from the sensor as pulses and treats them as a frequency measurement task. The final controller display is in units of frequency, i.e. hertz, but equivalent to the flow rate scaled to the appropriate engineering units, for example: gallons/second.
A rotary encoder placed on a milling table generates 500 pulses per foot of travel.
Therefore, if K = 500 (500 pulses/foot)
Then
= 0.002 feet/pulse = the scale factor
Again, the resultant scale factor is then entered into the controller in the calibration mode. The controller receives the input signal from the sensor as pulses and treats them as a frequency measurement task. The final controller display is in units of frequency, i.e. hertz, but equivalent to the feed rate scaled to the appropriate engineering units, for example: feet/second.
Note:
If you require units per minute divide the scale factor by 60.
If you require units per hour divide the scale factor by 3600.
Step 3 Enter the New Scale Factor When you have established the new scale factor, enter the controllers calibration mode [CAL] and set to [10X]. The X in the 3rd digit means you must select the relevant channel for the input signal. Enter this mode and set the offset setting [OFF_1] to 0 and the scale setting [SCA_1] to the new scale factor.
Enter Calibration Mode
then
Leave as
Reset to new scale factor. For example:
Step 4 Select Display Resolution At this point you should decide on where you want to position the decimal point on the display, based on the minimum and maximum displayed units you require, then set this in Code 1 [X61].
Enter Code 1
3rd digit selects channel 1
then
3rd digit selects decimal point position
Step 5 Select the Data Source for the Primary Display While leaving Code 1 after setting the position of the decimal point, set the 2nd digit to 5 and the 3rd digit to 0 to select the primary display [Cod_1] [X50].
The source for the primary display is set by selecting 0 in the 3rd digit and then entering the select data source mode. In this mode a number of choices are available as the source of data for the selected (primary) display.
Enter Code 1
then
Note:
3rd digit 0 selects primary display.
Select the channel
source for the primary display.
required as the
The primary display is the default display for all single display Tiger 320 Series controllers (i.e. selecting 0, 1, or 2 in the 3rd digit selects the primary display). In dual and triple display controllers, the top display is the primary display. And in bargraphs the digital display is the primary display and the bargraph is the secondary display.
Step 6 Final Settings: Frequency Input The display frequency range is selected last and completes the manual calibration procedures for CH1 setup as a frequency input. After you have decided on the resolution you require, and positioned the decimal point to provide this, the frequency range then configures the position of the displayed counts when a 1 Hz pulsed input is applied.
Enter Code 2 and select 4 in the 2nd digit. In the 3rd digit select the frequency range that applies.
Enter Code 2
X X 3rd digit selects the frequency range
for the display
Displayed Counts
X40
For 1 Hz
For 50 Hz
X41
For 1 Hz
For 50 Hz
X42
For 1 Hz
X43
For 1 Hz
X44
For 1 Hz
X45
For 1 Hz
X46
For 1 Hz
X47
For 1 Hz
For 50 Hz
For 50 Hz
1. 0
For 50 Hz
For 50 Hz
For 50 Hz
For 50 Hz
5 0. 0
Step 6 Final Settings: UP Counter To complete the manual calibration procedures, CH1 must be configured as an UP counter. Enter Code 2 and select 6 in the 2nd digit. This selects counter as the measurement task. In the 3rd digit select 3 to apply the UP counter.
Enter Code 2
Flow Rate Header in FREQ Position As a frequency input, a different scale factor can be used in CH2 to suit the required engineering units. To calculate and set a new scale factor, carry out the manual calibration procedure in the following sequence:
Step 1
Establish the K Factor
Step 2
Calculate the Scale Factor
= Scale Factor
per
minute
per
hour
Divide
scale factor
by 60
Divide
scale factor
by 3600
you
require units
per second
YES
Step 3
Enter the New Scale Factor
Calibration Mode
Step 4
Select Display Resolution
Code 1
Step 5
Select the Data Source for the Primary Display
Code 1
Step 6 Select the Display Range
Code 4
Totalizer Header in COUNT Position As a counter input, CH2 can be programmed as a totalizer using the prescaler. To calculate the prescaler, carry out the manual calibration procedure in the following sequence:
Step 1
Establish the K Factor
Step 2
Calculate the Scale Factor
= Scale Factor
per
minute
per
hour
Divide
scale factor
by 60
Divide
scale factor
by 3600
you
require units
per second
YES
Step 3
Enter the New Scale Factor
Calibration Mode
Step 4
Make Sure the Prescaler is Set to 1
Code 4
Step 5
Select the UP/DOWN Counter
Code 1
Step 6
Select Display Resolution
Code 1
Step 7
Select the Data Source for the Primary Display
Code 1
Step 8
If required:
Select a New Display Message for the CH2 Display in the View Mode
Texmate Meter Configuration
Utility Program
Step 1 to Step 5 Steps 1 to 5 are the same for CH1 Frequency Input and CH2 Flow Rate. Follow Steps 1 to
5 under the heading Channel 1 Frequency Input when carrying out channel 2 flow rate manual calibration procedures.
Step 6 Select the Display Frequency Range The display frequency range is selected last and completes the manual calibration procedures.
After you have decided on the resolution you require, and positioned the decimal point to provide this, the frequency range then configures the position of the displayed counts when a 1 Hz pulsed input is applied.
Enter Code 4 and select 3 in the 1st digit to select the second digital input channel. In the 2nd digit select the frequency range that applies. Select 0 in the 3rd digit to ensure no linearization tables are applied to CH2.
Enter Code 4
X 2nd digit selects the frequency range
for the display
Displayed Counts
300
For 1 Hz
For 50 Hz
310
For 1 Hz
For 50 Hz
320
For 1 Hz
For 50 Hz
330
For 1 Hz
For 50 Hz
Step 1 to Step 3 Steps 1 to 3 are the same for CH1 Frequency Input and both CH2 Flow Rate and CH2 Totalizer. Follow Steps 1 to 3 under the heading Channel 1 Frequency Input when carrying out channel 2 totalizer manual calibration procedures.
Step 4 Make Sure the Prescaler is Set to 1 When you have established the K factor for the required unit of measurement, enter Code 4 and ensure that the prescale setting is still 1. Select 3 in the 1st digit to select the second digital input channel, 7 in the 2nd digit to enter the prescaler menu, and 0 in the 3rd digit to ensure no linearization tables are applied to CH2.
Enter Code 4
2nd digit selects the Set Prescaler menu
Step 5 Select the UP/DOWN Counter When you have checked the prescaler, select the UP/DOWN counter setting as the mode for CH2. Enter Code 4 and select 3 in the 1st digit to select the second digital input channel, 6 in the 2nd digit to select the UP/DOWN counter, and 0 in the 3rd digit to ensure no linearization tables are applied to CH2.
Enter Code 4
2nd digit selects the Up/Down Counter with Prescaler setting
Step 6 Select Display Resolution At this point you should decide on where you want to position the decimal point on the display, based on the minimum and maximum displayed units you require, then set this in Code 1 [X61].
Enter Code 1
3rd digit selects channel 1
then
3rd digit selects decimal point position
Step 7 Select the Data Source for the Primary Display While leaving Code 1 after setting the position of the decimal point, set the 2nd digit to 5 and the 3rd digit to 0 to select the primary display [Cod_1] [X50].
The source for the primary display is set by selecting 0 in the 3rd digit and then entering the select data source mode. In this mode a number of choices are available as the source of data for the selected (primary) display.
Enter Code 1
then
Note:
3rd digit 0 selects primary display.
Select the channel
source for the primary display.
required as the
The primary display is the default display for all single display Tiger 320 Series controllers (i.e. selecting 0, 1, or 2 in the 3rd digit selects the primary display). In dual and triple display controllers, the top display is the primary display. And in bargraphs the digital display is the primary display and the bargraph is the secondary display.
Step 8 Select a New Display Message for the CH2 Display in the View Mode
The value displayed on CH2 can be viewed in the view mode by pressing the in the operational display. The display toggles between [Ch2] and [VALUE].
button while
If required, the [Ch2] message can be changed to display the unit of measure using the display editing function of the Texmate Meter Configuration Utility Program.
See www.texmate.com for details of the Texmate Meter Configuration Utility Program.
For product details visit www.texmate.com
Local Distributor Address
Tel: 1-760-598-9899 USA 1-800-839-6283 Thats 1-800-TEXMATE Fax: 1-760-598-9828 Email: [email protected] Web: www.texmate.com
Texmate is an American manufacturer of high durability industrial grade panel meters, bar graphs, and transducers. Texmate's meters are frequently equipped with relays and various signal outputs for industrial automation applications and are known for their extremely long service life.