CN216349199U

CN216349199U - Intelligent temperature transmitter and sensor signal measuring device

Info

Publication number: CN216349199U
Application number: CN202122347159.9U
Authority: CN
Inventors: 宋振
Original assignee: Shandong Arnman Intelligent Technology Co ltd
Current assignee: Shandong Arnman Intelligent Technology Co ltd
Priority date: 2021-09-27
Filing date: 2021-09-27
Publication date: 2022-04-19
Anticipated expiration: 2031-09-27

Abstract

The utility model relates to an intelligent temperature transmitter, comprising: the constant current source generating circuit outputs constant current excitation to the sensor through the signal and excitation switching circuit so as to supply power to the sensor; the signal and excitation switching circuit determines an operation mode according to a mode switching instruction sent by the singlechip; acquiring a differential voltage analog signal according to a sensing signal output by a sensor; the analog-to-digital conversion circuit is used for performing analog-to-digital conversion on the differential voltage analog signal to obtain a differential voltage digital signal; the single chip microcomputer is used for acquiring first temperature and resistance voltage data according to the differential voltage digital signal; and the transmitting output circuit is used for converting the first temperature and resistance voltage data into standard signals. The utility model supports various thermocouple sensors, differential voltage signals, 2-wire system, 3-wire system and 4-wire system thermal resistance sensors or resistors, and simultaneously supports the functions of self-diagnosis of sensor faults, degraded operation after faults and fault indication.

Description

Intelligent temperature transmitter and sensor signal measuring device

Technical Field

The present invention relates to the field of industrial instrumentation and, more particularly, to an intelligent temperature transmitter and sensor signal measurement device.

Background

Transmitters are instruments that convert the output signal of a sensor into a transmittable standardized output signal, mainly for industrial process measurement and control. Among them, the temperature transmitter is one of the most commonly used transmitters, and has wide application occasions and market demands.

The existing temperature transmitter has the following problems: it is difficult to make all sensors input compatible, especially not to support 4-wire system measurement compatible with thermal resistance. And secondly, the failure diagnosis of the sensor is not provided or the failure diagnosis function is weak, so that the failure-reducing operation of the failure generation transmitter is not supported. And thirdly, the function of fault indication is not provided, and when the transmitter breaks down, the fault is complex to be checked. Fourthly, the power consumption of the whole machine is high, the power consumption is large, and the NE43 standard is difficult to support. Diode simulation compensation is mostly adopted for thermocouple cold junction compensation, and compensation precision is low and stability is poor. Sixthly, the on-line current measurement is not supported, and the on-site inspection is inconvenient. And measurement accuracy of the transmitter is low, the influence of environment temperature on the accuracy is large, and the anti-interference performance is poor.

Disclosure of Invention

The utility model provides an intelligent temperature transmitter and a sensor signal measuring device, which aim to solve the problem of how to efficiently and accurately measure a sensor.

In order to solve the above problem, according to an aspect of the present invention, there is provided a design of an intelligent temperature transmitter, the temperature transmitter including: a sensor signal measuring device and a transmission output circuit, the sensor signal measuring device including: the device comprises a constant current source generating circuit, a signal and excitation switching circuit, an analog-to-digital conversion circuit, a single chip microcomputer and a power circuit; wherein the content of the first and second substances,

the constant current source generating circuit is connected with the signal and excitation switching circuit and is used for outputting constant current excitation to the sensor through the signal and excitation switching circuit so as to supply power to the sensor;

the signal and excitation switching circuit is respectively connected with the sensor, the analog-to-digital conversion circuit and the single chip microcomputer and is used for determining an operation mode according to a mode switching instruction sent by the single chip microcomputer; the voltage difference detection circuit is used for acquiring a differential voltage analog signal according to the sensing signal output by the sensor;

the analog-to-digital conversion circuit is connected with the singlechip and is used for performing analog-to-digital conversion on the differential voltage analog signal to obtain a differential voltage digital signal;

the singlechip is connected with the transmitting output circuit and used for sending the mode switching instruction to the signal and exciting the switching current; the differential voltage digital signal is used for acquiring first temperature, resistance and/or voltage data;

the transmitting output circuit is used for converting the first temperature, resistance and/or voltage data into a standard signal of a preset type;

and the power supply circuit is used for supplying power to the sensor signal measuring device and the transmitting output circuit.

Preferably, the temperature transmitter further comprises:

and the environment temperature measuring circuit is connected with the singlechip and is used for measuring the environment temperature.

Preferably, wherein the signal and stimulus switching circuit comprises: the circuit comprises a double-path four-channel analog multiplexer, a first terminal, a second terminal, a third terminal and a fourth terminal which are used for being connected with a sensor, a first control pin and a second control pin which are used for switching channels, an exciting current filling end, an exciting current sucking end, a differential positive output end and a differential negative output end, wherein the differential positive output end outputs differential voltage analog signals.

Preferably, the signal and excitation switching circuit further comprises: a pull-up resistor and a pull-down resistor; the pull-up resistor is respectively connected with the differential positive output end and the power end of the signal and excitation switching circuit, and the pull-down resistor is respectively connected with the differential negative output end and the ground end of the signal and excitation switching circuit.

Preferably, the sensor signal measuring device further comprises:

and the communication interface is connected with the singlechip and is used for realizing the interaction between the singlechip and external equipment.

Preferably, the sensor signal measuring device further comprises:

and the reference circuit is connected with the constant current source generating circuit, the analog-to-digital conversion circuit and the transmitting output circuit and is used for providing a reference voltage signal.

Preferably, the sensor signal measuring device further comprises:

and the protection circuit is connected with the external power supply, the transmitting output circuit, the power supply and the reference circuit, and is used for protecting the power supply loop of the intelligent temperature transmitter and providing the function of online current measurement.

Preferably, the sensor signal measuring device further comprises:

and the fault indicating equipment is connected with the single chip microcomputer and used for giving a fault alarm according to the control instruction sent by the single chip microcomputer.

According to another aspect of the present invention, there is provided an intelligent temperature transmitter, comprising: the device comprises a constant current source generating circuit, a signal and excitation switching circuit, an analog-to-digital conversion circuit, a single chip microcomputer, a transmission output circuit, an ambient temperature measuring circuit, a power supply circuit, a reference circuit and fault indicating equipment;

the constant current source generating circuit is connected with the signal and excitation switching circuit; the signal and excitation switching circuit is respectively connected with the sensor, the analog-to-digital conversion circuit, the single chip microcomputer and the power circuit; the analog-to-digital conversion circuit is connected with the single chip microcomputer; the single chip microcomputer is connected with the transmitting output circuit, the fault indicating equipment and the ambient temperature measuring circuit; the power supply circuit and the reference circuit are respectively connected with the constant current source generating circuit, the signal and excitation switching circuit, the analog-to-digital conversion circuit, the single chip microcomputer, the transmitting output circuit and the ambient temperature measuring circuit;

wherein the signal and stimulus switching circuit comprises: the circuit comprises a double-path four-channel analog multiplexer, a first terminal, a second terminal, a third terminal and a fourth terminal which are used for being connected with a sensor, a first control pin and a second control pin which are used for switching channels, an exciting current filling end, an exciting current sucking end, a differential positive output end, a differential negative output end, a pull-up resistor and a pull-down resistor, wherein the differential positive output end outputs a differential voltage analog signal;

the pull-up resistor is respectively connected with the differential positive output end and the power supply end of the signal and excitation switching circuit, and the pull-down resistor is respectively connected with the differential negative output end and the ground end of the signal and excitation switching circuit.

According to another aspect of the present invention, there is provided a sensor signal measuring apparatus characterized by comprising: the device comprises a constant current source generating circuit, a signal and excitation switching circuit, an analog-to-digital conversion circuit, a single chip microcomputer and a power circuit; wherein the content of the first and second substances,

the signal and excitation switching circuit is respectively connected with the sensor, the analog-to-digital conversion circuit, the single chip microcomputer and the power circuit and is used for determining an operation mode according to a mode switching instruction sent by the single chip microcomputer; the voltage difference detection circuit is used for acquiring a differential voltage analog signal according to the sensing signal output by the sensor;

the singlechip is used for sending the mode switching instruction to the signal and exciting the switching current; the differential voltage digital signal is used for acquiring first temperature, resistance and/or voltage data;

and the power supply circuit is used for supplying power to the sensor signal measuring device.

The utility model provides an intelligent temperature transmitter, which comprises: the intelligent temperature transmitter can accurately measure the sensing signals of different types of sensors and convert the sensing signals into 4-20mA current signals for output; for the measurement of the thermal resistor or the resistor, the compatibility of three wiring modes of a 2-wire system, a 3-wire system and a 4-wire system is supported, particularly the support of the 4-wire system of the thermal resistor improves the precision of temperature measurement, widens the use scene of the transmitter, simultaneously supports the fault indication function, and is convenient to operate and use. The utility model also provides a sensor signal measuring device, which can realize the purpose of accurately measuring the induction signals of different types of sensors, supports the compatibility of three wiring modes of a 2-wire system, a 3-wire system and a 4-wire system, particularly supports the 4-wire system of the thermal resistor, improves the precision of temperature measurement and widens the use scene of the transmitter.

Drawings

A more complete understanding of exemplary embodiments of the present invention may be had by reference to the following drawings in which:

FIG. 1 is a schematic diagram of a smart temperature transmitter 100 according to an embodiment of the present invention;

FIG. 2 is an exemplary diagram of an intelligent temperature transmitter according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a constant current source generating circuit according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a signal and stimulus switching circuit according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of an analog-to-digital conversion circuit according to an embodiment of the utility model;

FIG. 6 is a schematic diagram of a single-chip microcomputer according to an embodiment of the present invention;

FIG. 7 is a schematic diagram of a transmit output circuit according to an embodiment of the present invention;

FIG. 8 is a circuit schematic of a communication interface according to an embodiment of the present invention;

FIG. 9 is a schematic diagram of a protection circuit according to an embodiment of the utility model;

fig. 10 is a schematic structural diagram of a sensor signal measuring device 1000 according to an embodiment of the present invention.

Detailed Description

The exemplary embodiments of the present invention will now be described with reference to the accompanying drawings, however, the present invention may be embodied in many different forms and is not limited to the embodiments described herein, which are provided for complete and complete disclosure of the present invention and to fully convey the scope of the present invention to those skilled in the art. The terminology used in the exemplary embodiments illustrated in the accompanying drawings is not intended to be limiting of the utility model. In the drawings, the same units/elements are denoted by the same reference numerals.

Unless otherwise defined, terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Further, it will be understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense.

FIG. 1 is a schematic diagram of a smart temperature transmitter 100 according to an embodiment of the present invention. As shown in fig. 1, an intelligent temperature transmitter 100 provided by the embodiment of the present invention includes: a sensor signal measuring device 101 and a transmission output circuit 102, the sensor signal measuring device 101 including: a constant current source generating circuit 1011, a signal and excitation switching circuit 1012, an analog-to-digital conversion circuit 1013, a single chip 1014 and a power supply circuit 1015.

Preferably, the constant current source generating circuit 1011 is connected to the signal and excitation switching circuit, and is configured to output a constant current excitation to the sensor through the signal and excitation switching circuit, so as to supply power to the sensor.

Referring to fig. 2, in an embodiment of the present invention, a temperature transmitter includes: the device comprises a singlechip, a constant current source generating circuit for measuring thermal resistance, a signal and excitation switching circuit for realizing multi-sensor compatibility, an analog-to-digital conversion circuit for performing analog-to-digital conversion on sensor signals and a transmitting output circuit for realizing transmitting output. Wherein, the sensor includes: pt100 thermal resistor, Pt500 thermal resistor, Cu100 thermal resistor, Cu50 thermal resistor, pure resistance signal, platinum rhodium 10-platinum thermocouple (S type), platinum rhodium 13-platinum thermocouple (R type), nickel chromium-nickel silicon thermocouple (K type), nickel chromium silicon-nickel silicon thermocouple (N type), nickel chromium-constantan thermocouple (E type), iron-constantan thermocouple (J type), copper-constantan thermocouple (T type), platinum rhodium 30-platinum rhodium 6(B type), differential voltage signal, and may provide non-standard adjustments and calibrations for specific types of thermal resistors or thermocouples.

In an embodiment of the utility model, a constant current source generating circuit is used to provide drive for sensor measurement, and a constant current source generates current to output constant current excitation to a sensor to supply power to the sensor. In order to ensure the accuracy of thermal resistance measurement, the current stability of the constant current source is of great importance.

In the embodiment of the utility model, the constant current source generating circuit shown in fig. 3 is adopted, and the constant current source generating circuit is realized by adopting an LMV321 low-power-consumption amplifier which has very low power consumption, only needs the current less than 110uA under the normal working condition, and is particularly suitable for a 2-wire transmitter with limited power consumption. The reference input of the constant current source generating circuit is obtained by dividing a reference voltage of 3.0V output by the reference circuit through R7 and R9, the signal obtained by dividing the voltage through two resistors is a voltage signal of 0.6V, and the signal is connected to the positive input end of the LMV321 after being filtered by a capacitor C2 and is used as a given signal of the constant current source generating circuit. The output of the LMV321 is used as the output end of the constant current source to drive the thermal resistance to be measured, and since the amplifier is supplied with power by 3.3V and belongs to rail-to-rail output, the maximum voltage output swing amplitude of the constant current source can reach 3.3V. The current returned by the thermal resistor passes through a reference resistor R6 to form a feedback voltage, and the feedback voltage is filtered by a capacitor C21 and then returns to be connected to the negative input end of the LMV321 to form closed-loop feedback control of the constant current source. In the circuit, the voltage dividing resistors R7 and R9 belong to key devices for generating given voltage, and the feedback resistor R6 belongs to a sampling reference resistor for deep negative feedback. The time stability and the temperature stability of the three resistors determine the stability of the constant current source. Therefore, the three resistors used in the scheme are all metal film resistors or film resistors with the temperature drift of less than or equal to +/-25 PPM/DEG C.

Preferably, the signal and excitation switching circuit 1012 is respectively connected to the sensor, the analog-to-digital conversion circuit and the single chip, and is configured to determine an operation mode according to a mode switching instruction sent by the single chip; and the voltage difference analog signal acquisition module is used for acquiring a differential voltage analog signal according to the sensing signal output by the sensor.

Preferably, the signal and stimulus switching circuit 1012, among others, comprises: the circuit comprises a double-path four-channel analog multiplexer, a first terminal, a second terminal, a third terminal and a fourth terminal which are used for being connected with a sensor, a first control pin and a second control pin which are used for switching channels, an exciting current filling end, an exciting current sucking end, a differential positive output end, a differential negative output end, a pull-up resistor and a pull-down resistor, wherein the differential positive output end outputs a differential voltage analog signal;

The signal and excitation switching circuit 1012 can receive a high-low level switching differential signal and excitation output by the single chip microcomputer through an IO port to different terminals, so as to switch the operation mode of the signal and excitation switching circuit.

In the embodiment of the utility model, 2-wire system, 3-wire system and 4-wire system measurement of the thermal resistor is realized while the thermocouple measurement is compatible through the excitation and signal switching circuit. The circuit can freely switch the operation modes according to the types of the sensors under the control of a single chip microcomputer program.

As shown in fig. 4, the core of the circuit is a two-way four-channel analog multiplexer RS2252 (similar model is CD4052), and the chip realizes the measurement of different sensors by switching the connections of the excitation source and the measurement terminal. Wherein P1, P2, P3 and P4 are the first, second, third and fourth terminals of the external connection sensor; CS _ a and CS _ B are the first and second control pins of RS 2252; the high and low levels can be output through the IO port of the singlechip to switch signals and excite the signals to different terminals. The AN and the AP are two differential voltage signal output ends of the switched sensor, the AN is a differential negative output end, the AP is a differential positive output end, and output signals are sent to a digital-to-analog conversion circuit to carry out data acquisition and processing. The signals at P1, P2, P3 and P4 can be switched to the differential negative output AN by controlling the channel control terminal of the analog multiplexer RS2252, and the differential positive output AP is always fixed to the P2 terminal. I + and I-are excitation current sources which are supplied to the sensor without switching, I + is an excitation current filling end, I-is a current suction end of the sensor excitation, and the excitation current is generated by a constant current source generating circuit. The constant current excitation current-sinking end I + can be switched to the P1, P2, P3 and P4 by controlling the channel control end of the analog multiplexer RS2252, and the constant current excitation current-sinking end is always fixed on the P3 terminal. And the channel control end of the analog multiplexer RS2252 realizes that the constant-current excitation current end I + and the differential negative output end AN are switched to corresponding terminals according to the control instruction of the singlechip, so that the operation mode of the excitation and signal switching circuit is changed, and the measurement of different types of sensors is realized. The corresponding relationship among the CS _ a signal, the CS _ B signal, the current sinking end I + connection terminal and the differential negative output end AN connection terminal in different operation modes is shown in table 1.

TABLE 1 corresponding relationship table under different operation modes

In the embodiment of the present invention, a pull-up resistor is provided on a signal path of a sensor of a switching circuit for signal and excitation, that is, a differential positive signal line of a digital-analog conversion input signal path, and a pull-down resistor is provided on a differential negative signal line (a pull-up resistor R19 is provided on AP, and a pull-down resistor R3 is provided on AN). In order to avoid the interference of the resistors on the normally measured effective signal, the resistance values of the two resistors are set to be as large as possible. The pull-up resistor and the pull-down resistor of the design both adopt 10 mega ohm resistance values, and larger resistors can be selected. By adding pull-up and pull-down resistors, the default state of the digital-to-analog converter can be set to full-scale or over-scale input under the condition that the signal path is in short circuit, thereby generating a larger conversion result. The signal and excitation switching circuit can provide a physical realization basis for realizing fault detection and degraded operation after slight fault, and is an indispensable part of fault diagnosis function. In the fault diagnosis process, the type of the fault needs to be analyzed by continuously switching the wiring mode of the thermal resistor; the transmitter also relies on switching signals and energized channels to achieve degraded operation when a fault is detected.

Preferably, the analog-to-digital conversion circuit 1013 is connected to the single chip microcomputer, and is configured to perform analog-to-digital conversion on the differential voltage analog signal to obtain a differential voltage digital signal.

In an embodiment of the present invention, the differential voltage analog signal is analog-to-digital converted by the analog-to-digital conversion circuit to obtain the differential voltage digital signal. As shown in fig. 5, the digital-to-analog conversion circuit according to the embodiment of the present invention is implemented by using a high-precision low-power consumption analog-to-digital conversion chip of CS1237 (similarly, CMS1237) produced by a semiconductor in core. The chip not only supports 24-bit code-loss-free digital-to-analog conversion, but also is internally provided with a differential amplifier with selectable PGA amplification factors of 1, 2, 64 and 128, so that the signal high-precision measurement is realized, and the independent establishment of an external signal amplification circuit is avoided. The specific implementation process is as follows: weak signals transmitted by an external sensor directly enter differential voltage signal input ends AINP and AINN of a CS1237 through a low-pass filter network formed by R4 and R5, C8, C9 and C10 to convert analog signals into digital signals, and the converted digital signals are transmitted to a single chip microcomputer to be operated through DOUT and SCLK of the CS 1237.

Preferably, the single chip microcomputer 1014 is connected with the transmission output circuit and is used for sending the mode switching command to the signal and exciting the switching current; and the circuit is used for acquiring first temperature and resistance voltage data according to the differential voltage digital signal.

Preferably, when the type of the sensor is thermocouple or differential voltage, the positive pole of the thermocouple or differential voltage is connected with the second terminal, the negative pole of the thermocouple is connected with the third terminal, and the signal and excitation switching circuit is controlled to be in the first operation mode through the control command so as to measure the signal; when the type of the sensor is a 4-wire heating resistor or a 4-wire resistor, one pair of homopolar cables of the 4-wire heating resistor or the 4-wire resistor is connected to the first terminal and the second terminal, the other pair of homopolar cables is connected to the third terminal and the fourth terminal, and the signal and excitation switching circuit is controlled to be in a second operation mode through the control command so as to measure signals; when the type of the sensor is a 2-wire heating resistor or a 2-wire resistor, two cables of the 2-wire heating resistor or the 2-wire resistor are respectively connected to the first terminal and the second terminal, and the signal and excitation switching circuit is controlled to be in a third operation mode through the control command so as to measure signals; when the type of the sensor is a 3-wire heating resistor or a 3-wire resistor, two cables with the same polarity of the 3-wire heating resistor or the 3-wire resistor are respectively connected to the second terminal and the third terminal, the other cable with the same polarity intercepts the fourth terminal, and the signal and excitation switching circuit is controlled by the control command to repeatedly switch between a fourth operation mode and a third operation mode so as to measure signals.

In the embodiment of the utility model, the single chip microcomputer can send a corresponding mode switching instruction to the signal and excitation switching circuit according to the type of the sensor so as to realize switching of different operation modes. Specifically, when the type of the sensor is a thermocouple or differential voltage, the positive pole of the thermocouple or differential voltage is connected with P2, the negative pole of the thermocouple is connected with P3, and the signal and excitation switching circuit is controlled to be in a first operation mode through the control command so as to measure signals; when the type of the sensor is a 4-wire thermal resistor or a 4-wire resistor, one pair of same-polarity cables of the 4-wire thermal resistor or the 4-wire resistor is connected to P1 and P2, the other pair of same-polarity cables is connected to P3 and P4, and the signal and excitation switching circuit is controlled to be in a second operation mode through the control command to measure signals; when the type of the sensor is a 2-wire heating resistor or a 2-wire resistor, two cables of the 2-wire heating resistor or the 2-wire resistor are respectively connected to P1 and P2, and the signal and excitation switching circuit is controlled to be in a third operation mode through the control command so as to measure signals; when the type of the sensor is a 3-wire thermal resistor or a 3-wire resistor, two cables with the same polarity of the 3-wire thermal resistor or the 3-wire resistor are respectively connected to the P2 and the P3, the other cable with the same polarity is connected to the P4, and the signal and excitation switching circuit is controlled by the control command to repeatedly switch between the fourth operation mode and the third operation mode so as to measure signals.

The process of realizing different wiring modes measurement of different sensors based on the mode switching is as follows:

(1) thermocouple or differential voltage measurement: fixed in mode 1.

The thermocouple or differential voltage wiring mode is as follows: the positive electrode of the thermocouple is connected with a P2 terminal, and the negative electrode of the thermocouple is connected with a P3 terminal.

The specific signal and excitation paths are as follows: p2 is a signal measurement and is directly connected to the AP signal without switching. P3 is the negative terminal of signal measurement, and is connected to AN signal through X0 to X terminal of RS 2252. The excitation current flows in from the Y port of RS2252 through switching, flows out from the Y0 port, and returns through resistor R22. The excitation current provides a stable negative terminal measurement reference for the thermocouple at terminal P3. All types of thermocouples are measured by the circuit, and conversion between measurement signals and temperature is realized through thermocouple coefficients stored in the single chip microcomputer. If the differential analog voltage is measured, the voltage signal is directly output without converting the voltage into the temperature.

(2) 4-wire thermal resistance or resistance measurement: fixed in mode 2.

The wiring mode of the 4-wire thermal resistor or the resistor is as follows: a pair of like-polarity wires of the thermal resistor are connected to the P1 and P2 terminals, and the other pair of like-polarity wires are connected to the P3 and P4 terminals.

The specific signal and excitation paths are as follows: p2 is the positive terminal for signal measurement and is connected directly to the AP signal without switching. P4 is the negative terminal of signal measurement, going through X1 of RS2252 to connect to AN signal. The excitation current I + is connected to the P1 terminal by switching from Y to Y1, and is returned directly back to I-through the thermal resistor from the P3 terminal without switching. The 4-wire system measurement provides the highest measurement accuracy, and the circuit realizes complete separation of the measurement loop and the excitation loop. So that the measurement of the thermal resistance is not affected by the resistance of the wire. After the resistance value of the thermal resistor is obtained, the measurement of the 4-wire thermal resistor can be finished by executing calculation through the single chip microcomputer. If the resistance is measured purely, the voltage-to-temperature conversion is not needed, and the resistance signal is directly output.

(3) 2-wire thermal resistance or resistance measurement: fixed in mode 3.

The wiring mode of the 2-wire thermal resistor or the resistor is as follows: the two wires of the thermal resistor are connected to the P1 and P2 terminals.

The specific signal and excitation paths are as follows: p2 is the positive terminal for signal measurement and is connected directly to the AP signal without switching. P3 is the negative terminal of signal measurement, and is connected to AN signal through X2 to X terminal of RS 2252. The excitation current I + is connected to the P2 terminal by switching from Y to Y2, and is returned directly back to I-through the thermal resistor from the P3 terminal without switching. The 2-wire test of thermal resistance is affected by the resistance of the wire, and it is not suitable to measure thermal resistance with too long wire. But only two connections can guarantee the reliability of the measurement. After the resistance value of the thermal resistor is obtained, the 2-wire heating resistor can be measured by executing calculation through the single chip microcomputer. If the resistance is measured purely, the voltage-to-temperature conversion is not needed, and the resistance signal is directly output.

(4) 3-wire measurement of thermal resistance or resistance: switching back and forth between mode 4 and mode 3.

The wiring mode of the 3-wire thermal resistor or the resistor is as follows: two wires of the same polarity of the thermal resistor are connected to the P2 and P3 terminals, respectively. And a separate polarity is connected to P4.

The 3-wire system measurement is divided into two steps, and for the convenience of description, we assume that the resistance of the measured thermal resistor is RT and the resistance of the wire resistor is RL. Step 1: control RS2252 switches to mode 4 and measures the resistance of the hot resistance plus 1 wire, i.e., RT + RL. The specific signal and excitation paths are as follows: p2 is the positive terminal for signal measurement and is connected directly to the AP signal without switching. P4 is the negative terminal of signal measurement, going through X3 of RS2252 to connect to AN signal. The excitation current I + is connected to the P2 terminal by switching from Y to Y3, and is returned directly back to I-through the thermal resistor from the P3 terminal without switching. Thus, both the excitation current and the signal measurement function are available through the P2 terminal, so that the impedance of the connected wires is accounted for. But only the measurement signal, no excitation current, and no wire impedance effect are present at the P4 terminal. So the data obtained by the measurements of AN and AP at this time is the thermal resistance plus one wire impedance.

Step 2: control RS2252 switches to mode 3 and measures the resistance of the hot resistance plus 2 wires, i.e. RT +2 × RL. The specific signal and excitation paths at this time are the same as for the 2-wire system thermal resistance measurement.

When 3-wire thermal resistance is calculated, the data (RT +2 × RL) of 2 wires is subtracted from twice the data (RT + RL) measured in the step 1, so that all wire impedances can be offset, and the influence of the wire impedances on the thermal resistance is avoided. The specific calculation formula is as follows, assuming that the measured resistance is RM: then RM ═ 2 ═ RT + RL) - (RT +2 ═ RL); the measured resistance RM is thus the resistance of the thermal resistor and the error in the wire resistance is cancelled. When the transmitter works, the step 1 and the step 2 are executed circularly, after the resistance value of the thermal resistor offsetting the cable resistor is obtained, the measurement of the 3-wire heating resistor can be finished by executing calculation through the single chip microcomputer. If the resistance is measured purely, the voltage-to-temperature conversion is not needed, and the resistance signal is directly output.

When the sensor is a thermal resistor, the single chip microcomputer can convert the acquired differential voltage digital signal into a resistor according to a conversion relation between a standard differential voltage digital signal and the resistor, and then convert the resistor into temperature according to a relation between the resistor and the temperature so as to acquire and output a first temperature.

When the sensor is used for measuring the resistance, the single chip microcomputer can also convert the acquired differential voltage digital signal into resistance data and directly output the resistance data according to the conversion relation between the standard differential voltage digital signal and the resistance.

When the sensor is a thermocouple, the single chip microcomputer can convert the acquired differential voltage digital signal into a first thermoelectric potential according to the conversion relation between the standard differential voltage digital signal and the thermoelectric potential. And meanwhile, obtaining a second temperature by measuring the ambient temperature, and converting the second temperature into a second thermoelectric potential according to the standard conversion relation between the temperature and the thermoelectric potential. And adding the first thermoelectric potential and the second thermoelectric potential to obtain a third thermoelectric potential after cold end compensation of the thermocouple. And converting the converted thermoelectric force into temperature according to the relationship between the third thermoelectric force and the temperature so as to obtain the corrected first temperature and output the corrected first temperature. Meanwhile, the cold end compensation function of the thermocouple can be closed according to the use scene, and the conversion from the conversion thermal potential to the temperature can be directly carried out according to the relation between the first thermal potential and the temperature so as to obtain the first temperature which is not corrected and output the first temperature.

When the sensor is used for measuring differential voltage, the single chip microcomputer can convert the acquired differential voltage digital signal into real differential analog voltage data according to the conversion relation between the standard differential voltage digital signal and the real differential analog voltage and directly output the real differential analog voltage data.

Whether in the initial deployment stage or the operation and maintenance stage of the transmitter, the fault diagnosis function of the transmitter can help the construction or operation and maintenance personnel to quickly locate the fault problem. Aiming at the requirements, the temperature transmitter is provided with the green fault indicator lamp, and a user can give a prompt according to the indicator lamp to determine the fault of the sensor. If the user wants to see more detailed information, the user can also use the matched configuration software to directly read the fault information of the sensor through the communication interface of the transmitter. In addition, when a sensor connected with the transmitter has slight fault, if the transmitter can adjust the operation state of the transmitter, the reliability and the stability of the system are undoubtedly further increased. Aiming at the requirements, the utility model also realizes a efficiency reduction operation mechanism when the transmitter fails. The system can still ensure the output signal of the sensor even if slight faults occur.

The utility model divides the fault of the sensor into two grades, namely a serious fault and a slight fault, and the fault indicating equipment is operated to inform a user of the fault and inform the user of the serious fault or the slight fault no matter in the fault state, and the fault indicating equipment can be a fault indicating lamp. The following are definitions of these two types of faults. A catastrophic failure is one in which the sensor has failed to affect its basic operation, i.e., the temperature measurement function is totally lost. At the moment, the transmitter outputs not a measuring signal but an alarm current, and can output a current less than or equal to 3.6mA or more than or equal to 22mA according to the setting of a user. Under the serious failure mode, the single chip microcomputer controls the failure indicating lamp to flash rapidly. The slight fault means that the fault of the sensor does not cause the complete loss of the measuring function of the sensor, and the sensor is switched to a poor measuring mode to complete the measurement. At the moment, the output of the transmitter is a measurement signal, but the output precision of the transmitter is poorer than that of the transmitter in a normal working state. In a slight fault mode, the single chip microcomputer controls the fault indicator lamp to be on or off normally. If the sensor works normally, the transmitter can run in a state set by a user, the transmitter outputs a measurement signal of accuracy expected by the user at the moment, and the fault indicator lamp controlled by the single chip microcomputer is normally on to indicate that the working state is normal.

To implement fault diagnosis and light fault-degrading operation of the transmitter to the sensor, a co-operation of the transmitter hardware and software is required. And a pull-up resistor and a pull-down resistor are designed on a signal and excitation switching circuit on hardware. In software, an upper limit and a lower limit for determining a fault are set according to different types of thermal resistors and operating temperature intervals of thermocouples.

In embodiments of the present invention, when the transmitter finds a problem operating in the configured mode, it automatically switches to the other mode for further inspection. And if the mode configured by the user works normally, the user works normally according to the configured mode. If a fault occurs, on one hand, the single chip sends a control instruction to fault indicating equipment according to a fault type and a preset control rule, so that the fault indicating lamp gives an alarm according to the control instruction and indicates the fault level; and sends out detailed fault information through the communication interface. On the other hand, the single chip machine determines a degradation operation mode and controls the signal and excitation switching circuit to operate according to the degradation operation mode; meanwhile, when in a fault state, whether it is a major fault or a minor fault. It is cyclically attempted to resume the normal operating mode. And once the normal mode is successfully operated, operating in the normal mode, and determining the fault type and reason of the temperature transmitter again according to the preset judgment rule. And if the normal mode operation fails, returning to the original fault state. Specifically, when the running time of the temperature transmitter in the fault state reaches a preset time threshold, the running mode before the fault is adjusted according to the type of the sensor, and the fault type and the fault reason of the temperature transmitter are determined according to the preset judgment rule again.

The single chip circuit is the core of digital signal processing, and is implemented by STM8L151G4U6 as shown in fig. 6. The single chip microcomputer is low in power consumption and small in packaging, and is very suitable for being used in a temperature transmitter with limited power consumption and size. In addition, the single chip microcomputer is also provided with a 12-bit DAC peripheral, which is very useful for subsequent current output transmission, and can greatly simplify the design of a V/I output circuit and improve the accuracy and response time of current output. The power supply of the singlechip is not a 3.3V power supply output by the LDO, but a reference voltage of 3.0V output by a reference is used. The reason is that the circuit design can ensure the accuracy and stability of current output to the maximum extent considering that the reference used by the DAC is the supply voltage of the singlechip. The power supply of the single chip microcomputer is filtered by the C18 and then is connected to a VCC pin of the single chip microcomputer through a C19 decoupling capacitor. In addition, in order to ensure the reliable reset of the single chip microcomputer, a reset circuit of the single chip microcomputer is built by using R11 and C16.

The singlechip plays a control role on one hand, is used for switching paths of excitation and signals, controlling the state of the indicator light and outputting an analog voltage signal to control the output of 4-20mA current; and on the other hand, the data acquisition work is carried out, and the data acquisition device is used for acquiring the output data of the analog-digital converter and acquiring the data of the environmental temperature measurement. And secondly, processing the acquired signals, realizing nonlinear calibration of the transmitter signals, calculation and correction of temperature values, monitoring of system states and realizing communication switching working states according to configuration. In addition, the monitoring analysis and the judgment of the sensor faults are realized by the logic of the single chip microcomputer.

In the embodiment of the utility model, the fault indicator lamp adopts a fog-shaped emerald LED, is powered by 3.3.V and is connected to the singlechip through the current-limiting resistor R2. If the transmitter is in a normal working state, the indicator lamp is kept normally on to inform that the transmitter is in a normal working state. If the transmitter is in a serious fault state, the single chip microcomputer controls the LED lamp to flash quickly to inform a user that the transmitter is in the fault state. If the transmitter is in a slight fault state, the LED lamp is controlled by the single chip microcomputer to be turned on and off constantly, a user is informed that the transmitter is in a reduced-efficiency operation state, and although the transmitter can normally output signals, the accuracy of the output signals is poor.

Preferably, the transmitting output circuit 102 is configured to convert the first temperature and resistance voltage data into a standard signal of a preset type.

In the implementation mode of the utility model, the transmitting output circuit can collect the signal of the external sensor according to the standard of the 2-wire system 4-20mA current output transmitter, carry out temperature calculation, finally map the temperature information to the 4-20mA current output, output the standard signal and realize the remote transmission of the transmitter signal. As shown in fig. 7, in order to realize the V/I conversion circuit for outputting the current of the transmitter, the digital-to-analog converter of the single chip microcomputer is externally provided with a modulated voltage signal which is sent out through the DAC lead. As shown in the figure, the DAC signal can map the temperature signal to a standard signal of 4-20mA through a V/I transmitting circuit built by the LMV 321. The voltage of the DAC will be divided by R10 and R14 as the positive side input to the LMV 321. The output of the LMV321 drives the BCX56 NPN transistor through a R12 resistor to control the output of the loop circuit. The output loop current is introduced to the negative terminal output of the LMV321 through R15 sampling to form a deeply negatively fed back current output. The voltage dividing resistors R10 and R14 are in a given loop, and the feedback resistor R15 is in a sampling link. The characteristics of these three resistors are decisive for the accuracy and stability of the current output. Therefore, the utility model selects the low temperature drift resistance with the temperature drift less than or equal to +/-25 PPM/DEG C.

Preferably, the power circuit 1015 is used for supplying power to the sensor signal measuring device and the transmission output circuit.

In the embodiment of the utility model, the power supply circuit is realized by adopting a linear voltage regulator HT7533, and the static power consumption of the chip is as low as 2.5 uA. The regulator has a maximum input voltage of 30V, which can accommodate the power requirements of transmitter DC 24V. The input side and the output side of the voltage stabilizer are respectively provided with a capacitor for filtering noise.

Preferably, the temperature transmitter further comprises:

In an embodiment of the present invention, the ambient temperature is measured by the ambient temperature measuring circuit to obtain a second temperature, so that the single chip microcomputer is configured to correct the first temperature according to the second temperature to obtain a corrected first temperature.

When the sensor is a thermocouple, the single chip microcomputer can convert a differential voltage digital signal into a first thermoelectric potential according to a conversion relation between a preset differential voltage digital signal and the thermoelectric potential; converting the second temperature into a second thermoelectric potential according to a conversion relation between a preset temperature and the thermoelectric potential; determining a third thermoelectric potential after cold end compensation of the thermocouple according to the sum of the first thermoelectric potential and the second thermoelectric potential; converting the third thermoelectric force into temperature according to a conversion relation between preset thermoelectric force and temperature so as to obtain and output the corrected first temperature; or when the sensor is a thermocouple, converting the differential voltage digital signal into a first thermoelectric potential according to a conversion relation between a preset differential voltage digital signal and the thermoelectric potential, and converting the first thermoelectric potential into temperature according to a relation between the first thermoelectric potential and the temperature so as to obtain and output a corrected first temperature.

In the embodiment of the utility model, the thermocouple is subjected to cold end compensation in a digital calculation mode. The circuit adopts NST1001 digital temperature chip to measure the ambient temperature. The chip NST100 of the nano-core microelectronic product is a high-precision double-pin digital pulse output temperature sensor chip. The temperature measuring range of the chip is-50 ℃ to 150 ℃, the resolution can reach 0.0625 ℃ at most, the precision of the full temperature zone is better than 0.75 ℃, the conversion time is short, and the precision is high. The cold end compensation of the thermocouple is realized as follows: the ambient temperature value inside the transmitter is obtained by NST 1001. And calculating the compensation electromotive force of the thermocouple according to the value of the environmental temperature. And thirdly, adding the compensated temperature electromotive force and the electromotive force obtained by the thermocouple measurement to obtain the compensated temperature electromotive force. Fourthly, calculating the real temperature value on the thermocouple according to the compensated electromotive force and the calculation coefficient of the thermocouple in the single chip microcomputer.

Preferably, the sensor signal measuring device further comprises:

As shown in fig. 2, the temperature transmitter further includes: a communication interface, a power supply and reference circuit (integration of the power supply circuit and the reference circuit), and a protection circuit (not shown in the figure). And the communication interface is connected with the singlechip and is used for realizing the interaction between the singlechip and external equipment. The power supply circuit is respectively connected with the constant current source generating circuit, the signal and excitation switching circuit, the analog-to-digital conversion circuit, the single chip microcomputer, the transmitting output circuit and the ambient temperature measuring circuit and is used for providing stable power supply; the reference circuit is respectively connected with the constant current source generating circuit, the signal and excitation switching circuit, the analog-to-digital conversion circuit, the single chip microcomputer, the transmitting output circuit and the ambient temperature measuring circuit and used for providing a reference voltage signal. And the protection circuit is connected with the external power supply, the transmitting output circuit, the power supply circuit and the reference circuit, and is used for protecting a power supply loop of the intelligent temperature transmitter and providing the function of online current measurement.

As shown in fig. 8, in an embodiment of the present invention, the communication interface is implemented using a standard Mini-USB socket. The UART cables TX and RX wire of the single chip microcomputer are directly connected to the D + and D-data wires of the USB socket, and the calibration and parameter modification of the transmission can be directly realized through the serial port of TTL outside. The program downloading and DEBUG cable of the single chip microcomputer is directly connected to a Shield pin of the USB socket, and program downloading and debugging can be achieved through an external downloader. In addition, the reset pin of the singlechip is led out to the ID pin of the USB, and the reset and restart of the singlechip can be conveniently realized outside.

In the embodiment of the utility model, a linear voltage regulator is selected as a power supply scheme of the whole transmitter. The reference circuit provides reference source for the constant current source generating circuit, the analog-to-digital conversion circuit and the current transmitting circuit. In order to ensure the measurement accuracy, a special serial reference source is adopted to generate a reference source required by the whole system. The scheme adopts a reference chip REF3330 to realize constant current reference. The reference chip can work at-40-125 ℃, and the maximum temperature drift of the full temperature zone range is less than 30 PPM/DEG C. The superior temperature stability and long term stability of the voltage reference source represents less temperature drift and time drift of the temperature transmitter. All references of the transmitter comprise a constant current source generating circuit, a digital-to-analog conversion circuit and a current output transmitting circuit (power supply of a single chip microcomputer), and are provided by the reference circuit. The method can reduce the cost, ensure that all circuit drifts in the same direction when the reference source drifts, further reduce the overall drift of the transmitter and ensure the measurement precision and the environmental stability.

As shown in fig. 9, P5 is a positive terminal for external power supply and P6 is a negative terminal for the protection circuit. The external power supply firstly passes through a safety high-voltage capacitor C5 to protect instantaneous burr voltage. And then passes through a TVS tube D4 to protect against transient pulses or electrostatic interference. Then through fuse F1, preventing the back-end load failure from causing circuit damage. Then the EMI is filtered out from the interior of the circuit through the inductors L1 and L2. After being protected by an anti-reverse diode D1, the filter C1 enters the interior of the transmitter. The utility model also designs a special test interface specially for the online current measurement without disassembly of the transmitter, the interface is realized by using a Zener voltage regulator tube D2, and measurement terminals T + and T-are led out from the two ends of the diode to the outside. When the loop current is measured, only the ammeter needs to be contacted with the measuring terminals T + and T-, at the moment, the diode is short-circuited, and all current flows through the measuring ammeter, so that the on-line current measurement is realized. In addition, the circuit is also provided with ESD electrostatic surge protection diodes on all terminals which can be touched and contacted, and the detailed content can be used for looking at signal and excitation switching circuits and communication interfaces.

The temperature transmitter of the utility model has the following advantages: (1) the input compatibility of the multiple sensors is realized, the 4-wire system measurement of the thermal resistor is particularly supported, and the measurement precision and the use scene of the sensors are improved. (2) This changer possesses the fault diagnosis function of healthy sensor, combines the fault indicator lamp of changer, and improvement efficiency that can be great helps construction or fortune dimension personnel to fix a position the trouble problem fast. (3) The slight fault efficiency-reducing operation mechanism of the transmitter ensures that the transmitter automatically switches the working mode when slight fault occurs, and ensures effective signal output of the transmitter. This improves the reliability of the transmitter. (4) The minimum power consumption current of the whole machine reaches 3.5mA, and the NE43 standard is supported. In addition to the manner of the indicator light, an alarm can also be output at the output current. The configuration system can conveniently control the faults. (5) The cold end compensation precision of the pure digital thermocouple is high, the stability is good, and the reaction speed is high. (6) And the online current measurement is supported, so that the field inspection is convenient and inconvenient. (7) The transducer has high measurement precision, small influence of environment temperature on precision and good anti-interference performance. Experimental tests show that: in the aspect of resisting electromagnetic interference: the output signal temperature of the group pulse of the signal or power supply 2000V is +2 ℃, and the group pulse is recovered to be normal after being cancelled (PT100 thermal resistance, the measuring range is set to be 0-100 ℃). In terms of resistance to environmental changes: raising the temperature to between 20 and 80 ℃ and rising the temperature to 0.05 ℃/10 ℃; the temperature of 20 to-40 ℃ is reduced and the temperature is drifted to-0.1 ℃/10 ℃ (PT100 thermal resistance, and the range is set to be 0 to 100 ℃).

An embodiment of the present invention further provides an intelligent temperature transmitter, including: the device comprises a constant current source generating circuit, a signal and excitation switching circuit, an analog-to-digital conversion circuit, a single chip microcomputer, a transmission output circuit, an ambient temperature measuring circuit, a power supply circuit, a reference circuit and fault indicating equipment;

Fig. 10 is a schematic structural diagram of a sensor signal measuring apparatus 1000 according to an embodiment of the present invention. As shown in fig. 10, a sensor signal measuring apparatus 1000 according to an embodiment of the present invention includes: a constant current source generating circuit 1001, a signal and excitation switching circuit 1002, an analog-to-digital conversion circuit 1003, a single chip microcomputer 1004 and a power supply circuit 1005.

Preferably, the constant current source generating circuit 1001 is connected to the signal and excitation switching circuit, and is configured to output a constant current excitation to the sensor through the signal and excitation switching circuit, so as to supply power to the sensor.

Preferably, the signal and excitation switching circuit 1002 is respectively connected to the sensor, the analog-to-digital conversion circuit and the single chip microcomputer, and is configured to determine an operation mode according to a mode switching instruction sent by the single chip microcomputer; and the voltage difference analog signal acquisition module is used for acquiring a differential voltage analog signal according to the sensing signal output by the sensor.

Preferably, the analog-to-digital conversion circuit 1003 is connected to the single chip, and configured to perform analog-to-digital conversion on the differential voltage analog signal to obtain a differential voltage digital signal.

Preferably, the single chip microcomputer 1004 is configured to send the mode switching command to the signal and the excitation switching current; and the circuit is used for acquiring first temperature and resistance voltage data according to the differential voltage digital signal.

Preferably, the power circuit 1015 is used for supplying power to the sensor signal measuring device.

The sensor signal measuring device 1000 according to the embodiment of the present invention corresponds to the sensor signal measuring device 101 in the intelligent temperature transmitter 100 according to another embodiment of the present invention, and thus, the description thereof is omitted.

The utility model has been described with reference to a few embodiments. However, other embodiments of the utility model than the one disclosed above are equally possible within the scope of the utility model, as would be apparent to a person skilled in the art from the appended patent claims.

Generally, all terms used in the claims are to be interpreted according to their ordinary meaning in the technical field, unless explicitly defined otherwise herein. All references to "a/an/the [ device, component, etc ]" are to be interpreted openly as referring to at least one instance of said device, component, etc., unless explicitly stated otherwise. The steps of any method disclosed herein do not have to be performed in the exact order disclosed, unless explicitly stated.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

In the description of the present invention, the terms of direction or positional relationship indicated by the terms "upper", "lower", "left", "right", "inside", "outside", and the like are based on the directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning a fixed connection, a removable connection, or an integral connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting the same, and although the present invention is described in detail with reference to the above embodiments, those of ordinary skill in the art should understand that: modifications and equivalents may be made to the embodiments of the utility model without departing from the spirit and scope of the utility model, which is to be covered by the claims.

Claims

1. An intelligent temperature transmitter, characterized in that, temperature transmitter includes: a sensor signal measuring device and a transmission output circuit, the sensor signal measuring device including: the device comprises a constant current source generating circuit, a signal and excitation switching circuit, an analog-to-digital conversion circuit, a single chip microcomputer and a power circuit; wherein the content of the first and second substances,

the signal and excitation switching circuit is respectively connected with the sensor, the analog-to-digital conversion circuit, the single chip microcomputer and the power circuit and is used for determining an operation mode according to a mode switching instruction sent by the single chip microcomputer; the differential voltage signal is obtained according to the sensing signal output by the sensor;

2. The temperature transmitter of claim 1, further comprising:

3. The temperature transmitter of claim 1, wherein the signal and excitation switching circuitry comprises: the circuit comprises a double-path four-channel analog multiplexer, a first terminal, a second terminal, a third terminal and a fourth terminal which are used for being connected with a sensor, a first control pin and a second control pin which are used for switching channels, an exciting current filling end, an exciting current sucking end, a differential positive output end and a differential negative output end, wherein the differential positive output end outputs differential voltage analog signals.

4. The temperature transmitter of claim 3, wherein the signal and excitation switching circuitry further comprises: a pull-up resistor and a pull-down resistor; the pull-up resistor is respectively connected with the differential positive output end and the power end of the signal and excitation switching circuit, and the pull-down resistor is respectively connected with the differential negative output end and the ground end of the signal and excitation switching circuit.

5. The temperature transmitter of claim 1, wherein the sensor signal measuring device further comprises:

6. The temperature transmitter of claim 1, wherein the sensor signal measuring device further comprises:

7. The temperature transmitter of claim 1, wherein the sensor signal measuring device further comprises:

8. The temperature transmitter of claim 1, wherein the sensor signal measuring device further comprises:

9. The utility model provides an intelligence temperature transmitter which characterized in that, intelligence temperature transmitter includes: the device comprises a constant current source generating circuit, a signal and excitation switching circuit, an analog-to-digital conversion circuit, a single chip microcomputer, a transmission output circuit, an ambient temperature measuring circuit, a power supply circuit, a reference circuit and fault indicating equipment;

wherein the signal and stimulus switching circuit comprises: the sensor comprises a double-path four-channel analog multiplexer, a first terminal, a second terminal, a third terminal and a fourth terminal which are used for being connected with the sensor, a first control pin and a second control pin which are used for switching channels, an exciting current filling end, an exciting current sucking end, a differential positive output end, a differential negative output end, a pull-up resistor and a pull-down resistor, wherein the differential positive output end outputs differential voltage analog signals;

10. A sensor signal measuring device, characterized in that the sensor signal measuring device comprises: the device comprises a constant current source generating circuit, a signal and excitation switching circuit, an analog-to-digital conversion circuit, a single chip microcomputer and a power circuit; wherein the content of the first and second substances,