JP2017133992A - Temperature transmitter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable calculated measurement temperature data to be utilized in a temperature transmitter having a thermocouple connected thereto even when a temperature sensor for measuring a reference contact temperature goes to an abnormal state.SOLUTION: Provided is a temperature transmitter equipped with a terminal block for connecting a thermocouple, comprising: a temperature sensor provided near the terminal block; an auxiliary temperature sensor provided separately from the temperature sensor; a temperature sensor state determination unit for determining the state of the temperature sensor on the basis of the sensor signal of the temperature sensor; a reference contact temperature setting unit for setting the temperature indicated by the temperature sensor as a reference contact temperature when it is determined that the temperature sensor is not in an abnormal state, and setting the temperature of the terminal block estimated on the basis of the temperature indicated by the auxiliary temperature sensor as a reference contact temperature when it is determined that the temperature sensor is in an abnormal state; and a temperature computation unit for computing a temperature by contact temperature compensation on the basis of the set reference contact temperature and the sensor signal of the thermocouple.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a temperature transmitter, and more particularly to a technique for increasing the reliability of a temperature transmitter.

  The temperature transmitter is a field device that inputs a sensor signal from a connected thermocouple, resistance temperature detector, etc., converts the signal into a signal of a predetermined format such as a 4 to 20 mA direct current, and outputs the signal. Here, the case where a thermocouple is connected is targeted.

  FIG. 5A is a diagram illustrating an example of a terminal block of the temperature transmitter 400. In the example shown in this figure, the terminal block is provided with input signal terminals numbered 1 to 5, and the thermocouple is connected to the second terminal and the third terminal.

  FIG. 5B is a cross-sectional view along the line AA in the vicinity of the third terminal. As shown in the figure, a temperature sensor 410 for measuring the reference contact temperature is disposed near the third terminal. The temperature sensor 410 is composed of a resistance temperature detector, for example.

  FIG. 6 is a diagram for explaining the measurement procedure of the temperature transmitter 400. The thermoelectromotive force E23 is measured using the input credit terminal connected to the thermocouple, and the reference junction temperature t2 is measured by the temperature sensor 410. Then, the thermoelectromotive force E12 corresponding to the reference junction temperature t2 is calculated with reference to the electromotive force table.

  Since the thermoelectromotive force E13 is obtained from the thermoelectromotive force E12 and the thermoelectromotive force E23 according to the law of intermediate temperature, the measurement temperature t3 can be calculated from the thermoelectromotive force E13 and the reference temperature t1 (0 ° C.). The measurement method using the reference contact temperature t2 in this way is called reference contact compensation (zero contact compensation).

JP 2013-160505 A

  The temperature transmitter 400 can calculate the measured temperature t3 with high accuracy by the reference junction compensation using the reference junction temperature t2 measured by the temperature sensor 410. This is because the operation of the temperature sensor 410 is normal. It is based on this.

  For this reason, if the acquired reference contact temperature t2 shows an abnormal value due to failure of the temperature sensor 410 or the like, the temperature transmitter 400 cannot output correct measured temperature data, and the output of the temperature transmitter 400 Operation of temperature control system using data becomes impossible. Since the interruption of the temperature control system adversely affects the production plan or the like, it is desirable that the operation of the temperature control system can be continued even if the temperature sensor 410 becomes abnormal.

  Accordingly, an object of the present invention is to make it possible to use measured temperature data to be calculated even in a temperature transmitter that connects a thermocouple, even if a temperature sensor that measures a reference junction temperature is in an abnormal state.

In order to solve the above problems, a temperature transmitter according to the present invention is a temperature transmitter including a terminal block for connecting a thermocouple, and the temperature sensor provided in the vicinity of the terminal block is separate from the temperature sensor. An auxiliary temperature sensor provided in the temperature sensor, a temperature sensor state determination unit that determines a state of the temperature sensor based on a sensor signal of the temperature sensor, and the temperature sensor when it is determined that the temperature sensor is not in an abnormal state Is set as a reference contact temperature, and when it is determined that the temperature sensor is in an abnormal state, the temperature of the terminal block estimated based on the temperature indicated by the auxiliary temperature sensor is set as a reference contact temperature. A reference junction temperature setting unit, and a temperature calculation unit that calculates the temperature by contact temperature compensation based on the set reference junction temperature and the sensor signal of the thermocouple. To.
The reference contact temperature setting unit may estimate the temperature indicated by the auxiliary temperature sensor as the temperature of the terminal block.
Alternatively, the reference junction temperature setting unit may determine the amount of change in temperature indicated by the auxiliary temperature sensor and the relationship between the change in temperature of the auxiliary temperature sensor and the change in temperature of the temperature sensor with respect to a change in ambient temperature obtained in advance. Based on this, the temperature of the terminal block may be estimated.
In this case, the reference junction temperature setting unit may estimate the temperature indicated by the auxiliary temperature sensor as the temperature of the terminal block when the change amount of the temperature indicated by the auxiliary temperature sensor for a predetermined period is equal to or less than a reference value. it can.
The temperature sensor state determination unit may further include a warning output unit that outputs a warning when it is determined that the temperature sensor is in an abnormal state.

  According to the present invention, in a temperature transmitter to which a thermocouple is connected, even if a temperature sensor that measures a reference junction temperature is in an abnormal state, the calculated measured temperature data can be used.

It is a figure which shows the structure of the temperature transmitter of this embodiment. It is a block diagram explaining the functional structure of a temperature transmitter. It is a flowchart explaining the temperature measurement operation | movement of the temperature transmitter of this embodiment. It is a figure explaining the estimation method of terminal block temperature. It is a figure which shows an example of the terminal block of a temperature transmitter. It is a figure explaining the measurement procedure of a temperature transmitter.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 1A is an exploded perspective view showing the configuration of the temperature transmitter 100 of the present embodiment. As shown in the figure, the temperature transmitter 100 includes a main body 110, a substrate 120, a display device 130, a substrate portion cover 140, and a terminal portion cover 150.

  A terminal block having an input signal terminal 112 and an output signal terminal 113 is arranged on the back side of the main body 110 as shown in FIG. The main body has a wiring connection port (input signal side) 111a and a wiring connection port (output signal side) 111b. As in the prior art, a temperature sensor 114 for measuring the reference contact temperature is disposed near the third terminal of the terminal block.

  Further, the temperature transmitter 100 includes an auxiliary temperature sensor 121 on the substrate 120. The auxiliary temperature sensor 121 can use a resistance temperature detector, a thermal diode, or the like, and measures the temperature around the substrate 120. However, the auxiliary temperature sensor 121 may be disposed at a place other than the substrate 120.

  FIG. 2 is a block diagram illustrating a functional configuration of the temperature transmitter 100. As shown in the figure, in addition to the auxiliary temperature sensor 121, the substrate 120 of the temperature transmitter 100 includes a signal input unit 122, a memory 123, a temperature sensor state determination unit 124, a reference junction temperature setting unit 125, a temperature calculation unit 126, A signal output unit 127 and a warning output unit 128 are provided.

  The signal input unit 122 inputs a sensor signal from the thermocouple, a sensor signal from the temperature sensor 114 arranged on the terminal block, and a sensor signal from the auxiliary temperature sensor 121 arranged on the substrate 120, and digitally inputs them at predetermined intervals. The data is converted and stored in the memory 123. The sensor signal uses a ring buffer or the like to hold history information for a certain period.

  The temperature sensor state determination unit 124 determines whether the temperature sensor 114 is in an abnormal state based on a sensor signal from the temperature sensor 114 stored in the memory 123. For example, if the sensor signal cannot be acquired from the temperature sensor 114, if the sensor signal from the temperature sensor 114 is outside a predetermined temperature range, or if the sensor signal is unstable from the temperature sensor 114, the temperature sensor 114 is abnormal. It can be determined that it is in a state.

  The reference junction temperature setting unit 125 sets the reference junction temperature in the reference junction compensation method. Specifically, when the temperature sensor state determination unit 124 determines that the temperature sensor 114 is not in an abnormal state, the temperature indicated by the temperature sensor 114 disposed in the vicinity of the terminal block is set as the reference contact temperature as before. To do.

  On the other hand, if it is determined that the temperature sensor 114 is in an abnormal state, the sensor signal of the temperature sensor 114 is not used, and the temperature of the terminal block is based on the temperature indicated by the auxiliary temperature sensor 121 disposed on the substrate 120. And the estimated temperature is set as the reference junction temperature. An example of the terminal block temperature estimation method will be described later.

  The temperature calculation unit 126 calculates the measured temperature by the reference junction compensation method based on the temperature indicated by the sensor signal from the thermocouple and the set reference junction temperature. The calculated measured temperature is converted into an analog physical quantity of a predetermined format such as 4-20 mA by the signal output unit 127 and output to the outside.

  When the temperature sensor state determination unit 124 determines that the temperature sensor 114 is in an abnormal state, the warning output unit 128 outputs a temperature sensor failure notification to the outside of the host device or the like.

  Next, the temperature measurement operation of the temperature transmitter 100 of this embodiment will be described with reference to the flowchart of FIG. First, the temperature sensor state determination unit 124 refers to a sensor signal from the temperature sensor 114 stored in the memory 123 (S101), and determines whether or not the temperature sensor 114 is in an abnormal state (S102).

  As described above, when the sensor signal cannot be obtained from the temperature sensor 114, when the sensor signal from the temperature sensor 114 indicates outside the predetermined temperature range, when the sensor signal from the temperature sensor 114 is unstable, etc. It can be determined that 114 is in an abnormal state.

  As a result, when it is determined that “the temperature sensor 114 is not in an abnormal state” (S102: No), the reference contact temperature setting unit 125 sets the temperature based on the sensor signal of the temperature sensor 114 as the reference contact temperature (S103). ), The temperature calculation unit 126 performs temperature calculation by reference junction compensation based on the sensor signal from the thermocouple and the set reference junction temperature (S104). The signal output unit 127 converts the calculation result into an analog physical quantity in a predetermined format such as 4-20 mA, and outputs the result to the outside of the host device or the like (S105).

  On the other hand, when the temperature sensor state determination unit 124 determines that “the temperature sensor 114 is in an abnormal state” (S102: Yes), the warning output unit 128 outputs a warning to the host device or the like, and the temperature sensor 114 has failed. This is notified (S106).

  The temperature transmitter 100 performs the following processing so that the output of the measured temperature is not interrupted even when the temperature sensor 114 is in an abnormal state. That is, the reference contact temperature setting unit 125 estimates the temperature of the terminal block based on the sensor signal of the auxiliary temperature sensor 121 (S107), and sets the estimated temperature as the reference contact temperature (S108).

  Then, the temperature calculation unit 126 performs temperature calculation by reference junction compensation based on the sensor signal from the thermocouple and the set reference junction temperature (S104). The signal output unit 127 converts the calculation result into an analog physical quantity in a predetermined format such as 4-20 mA, and outputs the result to the outside of the host device or the like (S105).

  Next, the terminal block temperature estimation process (S107) performed by the reference junction temperature setting unit 125 will be described.

  If the ambient temperature of the temperature transmitter 100 is stable, the temperatures indicated by the normal temperature sensor 114 and the normal auxiliary temperature sensor 121 are assumed to be equal. For this reason, if the temperature sensor 114 is in an abnormal state, the temperature indicated by the auxiliary temperature sensor 121 can be estimated as the terminal block temperature.

  However, in this embodiment, the temperature sensor 114 is disposed inside the terminal block, and the auxiliary temperature sensor 121 is disposed on the substrate 120, and the way the ambient temperature is transmitted is not the same. For this reason, when ambient temperature changes, it is assumed that the temperature which both show differs until it becomes a stable state.

  For example, as shown in FIG. 4, when the ambient temperature changes from Tc1 to Tc2, the temperature change mode of the temperature sensor 114 and the temperature change mode of the auxiliary temperature sensor are different.

  Therefore, in order to increase the estimation accuracy of the terminal block temperature even when the ambient temperature is changed when the temperature sensor 114 is in an abnormal state, the temperature of the temperature sensor 114 and the auxiliary in advance are experimentally detected with respect to the ambient temperature change. The relationship with the temperature of the temperature sensor 121 may be obtained, and the temperature of the terminal block may be estimated based on the temperature change of the auxiliary temperature sensor 121.

Specifically, when the temperature of the auxiliary temperature sensor 121 does not change for a predetermined period, the temperature of the auxiliary temperature sensor 121 is estimated as the temperature of the terminal block. On the other hand, when the temperature of the auxiliary temperature sensor 121 changes by ΔTs in a predetermined period,
Terminal block estimated temperature = temperature of auxiliary temperature sensor 121−kt × ΔTs
It can be. Here, kt is a temperature change coefficient obtained experimentally. The temperature coefficient may be changed between when the temperature of the auxiliary temperature sensor 121 increases and when the temperature decreases.

  Furthermore, it is assumed that the temperature change of the temperature sensor 114 and the temperature change of the auxiliary temperature sensor 121 are in a first-order lag relationship with the change of the ambient temperature. For this reason, the time constant of the temperature change of the temperature sensor 114 with respect to the ambient temperature change, the time constant of the temperature change of the auxiliary temperature sensor 121, the dead time τ of the temperature change of the temperature sensor 114 with respect to the temperature change of the auxiliary temperature sensor 121 by experiments. Etc. may be obtained as parameters, and the accuracy of temperature estimation may be further increased. The parameter may be created for each change amount ΔTs of the auxiliary temperature sensor 121 in a predetermined time.

  In this case, the ambient temperature change is calculated backward from the temperature indicated by the auxiliary temperature sensor 121, the temperature change amount ΔTs, and the time constant, and the temperature sensor 114 is calculated from the obtained ambient temperature change, the time constant of the temperature sensor 114, and the dead time. Thus, the temperature of the terminal block can be estimated. However, the terminal block temperature estimation method is not limited to the above example, and various methods can be used.

  As described above, according to the temperature transmitter 100 of the present embodiment, even if the temperature sensor 114 arranged on the terminal block is in an abnormal state, the terminal block temperature is obtained using the sensor signal of the auxiliary temperature sensor 121. By estimating, available measurement temperatures can be output. For this reason, interruption of system control using the output of the temperature transmitter 100 can be prevented, and the reliability of the temperature transmitter 100 can be improved. In addition, since the temperature sensor 114 is notified to the outside of the host device or the like that it is in an abnormal state, it is possible to quickly deal with repairs and replacements.

DESCRIPTION OF SYMBOLS 100 ... Temperature transmitter, 110 ... Main body, 111 ... Wire connection port, 112 ... Input signal terminal, 113 ... Output signal terminal, 114 ... Temperature sensor, 120 ... Substrate, 121 ... Auxiliary temperature sensor, 122 ... Signal input part , 123, memory, 124, temperature sensor state determination unit, 125, reference junction temperature setting unit, 126, temperature calculation unit, 127, signal output unit, 128, warning output unit, 130, display device, 140, substrate unit cover, 150 ... Terminal cover

Claims (5)

A temperature transmitter having a terminal block for connecting a thermocouple,
A temperature sensor provided in the vicinity of the terminal block;
An auxiliary temperature sensor provided separately from the temperature sensor;
A temperature sensor state determination unit for determining a state of the temperature sensor based on a sensor signal of the temperature sensor;
When it is determined that the temperature sensor is not in an abnormal state, the temperature indicated by the temperature sensor is set as a reference contact temperature, and when the temperature sensor is determined to be in an abnormal state, the temperature indicated by the auxiliary temperature sensor A reference contact temperature setting unit that sets the temperature of the terminal block estimated based on the reference contact temperature,
Based on the set reference contact temperature and the sensor signal of the thermocouple, a temperature calculation unit that calculates the temperature by contact temperature compensation;
A temperature transmitter comprising:   The temperature transmitter according to claim 1, wherein the reference contact temperature setting unit estimates a temperature indicated by the auxiliary temperature sensor as a temperature of the terminal block.   The reference junction temperature setting unit is based on a temperature change amount indicated by the auxiliary temperature sensor and a relationship between a temperature change of the auxiliary temperature sensor and a temperature change of the temperature sensor with respect to a change in ambient temperature obtained in advance. The temperature transmitter according to claim 1, wherein the temperature of the terminal block is estimated.   The reference junction temperature setting unit estimates the temperature indicated by the auxiliary temperature sensor as the temperature of the terminal block when the change amount of the temperature indicated by the auxiliary temperature sensor for a predetermined period is equal to or less than a reference value. The temperature transmitter according to claim 3.   5. The apparatus according to claim 1, further comprising a warning output unit that outputs a warning when the temperature sensor state determination unit determines that the temperature sensor is in an abnormal state. Temperature transmitter.