CN211929386U - Digital gas density relay with self-diagnosis function and monitoring device - Google Patents

Abstract

The application discloses a digital gas density relay with a self-diagnosis function and a monitoring device, comprising a gas density detection sensor, an intelligent control unit, a annunciator, a communication module, a normally open electric control valve and a normally closed electric control valve; one end of the normally open electric control valve is provided with an interface communicated with the electrical equipment, the other end of the normally open electric control valve is communicated with one end of the normally closed electric control valve, the other end of the normally closed electric control valve is communicated with the air, and the gas density detection sensor is arranged on a gas path between the normally open electric control valve and the normally closed electric control valve; the intelligent control unit is respectively connected with the gas density detection sensor, the annunciator, the communication module, the normally open electric control valve and the normally closed electric control valve, completes online monitoring of the gas density value of the electrical equipment, controls the annunciator, and controls the switching state switching of the normally open electric control valve and the normally closed electric control valve. The gas density of the gas-insulated or arc-extinguishing electrical equipment is monitored, and meanwhile, online self-checking or self-diagnosis is completed, maintenance is not needed, operation and maintenance cost is reduced, and safe operation of a power grid is guaranteed.

Description

Digital gas density relay with self-diagnosis function and monitoring device

Technical Field

The utility model relates to an electric power tech field, concretely relates to use on high pressure, middling pressure electrical equipment, have self diagnostic function's digital gas density relay and monitoring devices.

Background

With the development of the unattended transformer substation towards networking and digitization and the continuous enhancement of the requirements on remote control and remote measurement, the method has important practical significance on the online monitoring of the gas density and micro-water content state of the SF6 electrical equipment. With the continuous and vigorous development of the intelligent power grid in China, intelligent high-voltage electrical equipment is used as an important component and a key node of an intelligent substation, and plays a significant role in improving the safety of the intelligent power grid. At present, most of high-voltage electrical equipment is SF6 gas insulation equipment, and if the gas density is reduced (caused by leakage and the like), the electrical performance of the equipment is seriously influenced, and serious hidden danger is caused to safe operation. At present, the online monitoring of the gas density value in the SF6 high-voltage electrical equipment is very common, and therefore, the application of the gas density monitoring system (gas density relay) is developed vigorously. Whereas current gas density monitoring systems (gas density relays) are basically: 1) the remote transmission type SF6 gas density relay is used for realizing the acquisition and uploading of density, pressure and temperature and realizing the online monitoring of the gas density. 2) The gas density transmitter is used for realizing the acquisition and uploading of density, pressure and temperature and realizing the online monitoring of the gas density. The remote SF6 gas density relay or gas density transmitter is a core and key component, and how to ensure normal operation is very critical.

Therefore, it is very necessary to develop a digital gas density relay or a gas density monitoring device with a self-diagnosis function, which is applied to a gas density monitoring system based on the ubiquitous power internet of things, and obtains the current working state of the digital gas density relay through zero calibration and diagnosis of a gas density detection sensor, so that the self-diagnosis or self-check of the digital gas density relay can be realized, the maintenance-free effect is realized, the working efficiency is improved, and the safe operation of a power grid is ensured.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high pressure or medium voltage electrical equipment is used, digital gas density relay (gas density monitoring devices) with self-diagnostic function, when being used for monitoring the electrical equipment gas density of gas insulation or arc extinguishing, still through digital gas density detection sensor's zero-bit check diagnosis, acquire digital gas density relay's current operating condition, accomplish the online self-checking or the self-diagnosis to digital gas density relay, improve work efficiency, need not passive maintenance, reduce the operation maintenance cost, guarantee electric wire netting safe operation.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the present application discloses in a first aspect a digital gas density relay with a self-diagnostic function, comprising: the intelligent control system comprises a gas density detection sensor, an intelligent control unit, a signaler, a communication module, a normally open electric control valve and a normally closed electric control valve;

one end of the normally open electric control valve is provided with an interface communicated with electrical equipment, the other end of the normally open electric control valve is communicated with one end of the normally closed electric control valve, the other end of the normally closed electric control valve is communicated with air, and a gas density detection sensor is arranged on a gas path between the normally open electric control valve and the normally closed electric control valve and is used for collecting a pressure value, a temperature value and/or a gas density value of the gas path between the normally open electric control valve and the normally closed electric control valve;

the intelligent control unit is respectively connected with the gas density detection sensor, the annunciator, the communication module, the normally open electric control valve and the normally closed electric control valve; the intelligent control unit is configured to acquire the gas density value acquired by the gas density detection sensor, or acquire the pressure value and the temperature value acquired by the gas density detection sensor and convert the pressure value and the temperature value into the gas density value according to the gas pressure-temperature characteristic; the intelligent control unit uploads one or more of a gas density value, a pressure value and a temperature value through the communication module and is used for completing the online monitoring of the gas density of the monitored electrical equipment by the digital gas density relay; the intelligent control unit is also configured to control the annunciator, enable the annunciator to output an alarm and/or a locking contact signal, and control the switching state of the normally-open electric control valve and the normally-closed electric control valve.

The second aspect of the present application discloses a gas density monitoring device having a self-diagnostic function, including: the intelligent control system comprises a gas density detection sensor, an intelligent control unit, a signaler, a communication module, a normally open electric control valve and a normally closed electric control valve;

one end of the normally open electric control valve is provided with an interface communicated with electrical equipment, the other end of the normally open electric control valve is communicated with one end of the normally closed electric control valve, the other end of the normally closed electric control valve is communicated with air, and a gas density detection sensor is arranged on a gas path between the normally open electric control valve and the normally closed electric control valve and is used for collecting a pressure value, a temperature value and/or a gas density value of the gas path between the normally open electric control valve and the normally closed electric control valve;

the intelligent control unit is respectively connected with the gas density detection sensor, the annunciator, the communication module, the normally open electric control valve and the normally closed electric control valve; the intelligent control unit is configured to acquire the gas density value acquired by the gas density detection sensor, or acquire the pressure value and the temperature value acquired by the gas density detection sensor and convert the pressure value and the temperature value into the gas density value according to the gas pressure-temperature characteristic; the intelligent control unit uploads one or more of a gas density value, a pressure value and a temperature value through the communication module and is used for completing the online monitoring of the gas density of the monitored electrical equipment by the digital gas density relay; the intelligent control unit is also configured to control the annunciator, enable the annunciator to output an alarm and/or a locking contact signal, and control the switching state of the normally-open electric control valve and the normally-closed electric control valve.

The digital gas density relay with the self-diagnosis function generally refers to that the components of the digital gas density relay are designed into an integral structure; the gas density monitoring device with the self-diagnosis function generally refers to that the components of the gas density monitoring device are designed into a split structure and are flexibly formed.

Preferably, the normally open electrically controlled valve is configured to close the gas path between the electrical equipment and the gas density detection sensor, the normally closed electrically controlled valve; the normally closed electric control valve is configured to open an air path of the gas density detection sensor, so that the gas density detection sensor is communicated with air, and the zero position check diagnosis of the gas density detection sensor is realized.

Preferably, the intelligent control unit control annunciator does not output an alarm and/or latch contact signal during zero verification diagnosis.

Preferably, when the gas density is lower than and/or higher than the preset threshold, the intelligent control unit controls the annunciator to output an alarm and/or a locking contact signal for completing the monitoring of the gas density in the electrical equipment.

Preferably, the digital gas density relay with the self-diagnosis function further comprises a digital gas density relay housing, wherein one or more of the gas density detection sensor, the intelligent control unit, the annunciator, the communication module, the normally open electric control valve and the normally closed electric control valve are positioned in the digital gas density relay housing. And preferably, the gas density detection sensor, the normally open electric control valve and the normally closed electric control valve are positioned in the digital gas density relay shell.

Preferably, the gas density detection sensor includes a pressure sensor and a temperature sensor; or the gas density detection sensor is a gas density transmitter consisting of a pressure sensor and a temperature sensor; or, the gas density detection sensor is a density detection sensor adopting a quartz tuning fork technology.

Preferably, the digital gas density relay with the self-diagnosis function or the gas density monitoring device with the self-diagnosis function further comprises a display unit, and the intelligent control unit displays one or more monitoring signals and/or information including a gas density value, a pressure value, a temperature value and a current working state through the display unit.

Preferably, the current operating state of the digital gas density relay with self-diagnostic function or the gas density monitoring device with self-diagnostic function includes: normal working state and abnormal working state.

More preferably, when the current operating state is an abnormal operating state, the digital gas density relay with the self-diagnosis function or the gas density monitoring device with the self-diagnosis function issues an abnormal prompt.

Preferably, the digital gas density relay with the self-diagnosis function or the gas density monitoring device with the self-diagnosis function further comprises a multi-way joint, and the normally open electric control valve, the gas density detection sensor and the normally closed electric control valve are respectively arranged on the multi-way joint; and on the gas path, the other end of the normally open electric control valve is respectively communicated with the gas density detection sensor and one end of the normally closed electric control valve through a multi-way joint.

In a preferred embodiment, a first interface of the multi-way joint is communicated with the other end of the normally open electric control valve, a second interface of the multi-way joint is communicated with one end of the normally closed electric control valve, and the gas density detection sensor is installed on a gas path between the normally open electric control valve and the normally closed electric control valve through a third interface of the multi-way joint.

In a preferred embodiment, the gas density detection sensor is mounted on a third interface of the multi-way joint; or a third interface of the multi-way joint is connected with a gas collecting pipeline, and the gas density detection sensor is arranged on the gas collecting pipeline.

More preferably, the digital gas density relay with the self-diagnosis function or the gas density monitoring device with the self-diagnosis function further comprises a comparison sensor, the comparison sensor is also arranged on the multi-way connector, and the comparison sensor is communicated with the gas density detection sensor on a gas path through the multi-way connector.

In a preferred embodiment, a first interface of the multi-way joint is communicated with the other end of the normally open electric control valve, a second interface of the multi-way joint is communicated with one end of the normally closed electric control valve, the gas density detection sensor is installed on a gas path between the normally open electric control valve and the normally closed electric control valve through a third interface of the multi-way joint, and the comparison sensor is installed on a gas path between the normally open electric control valve and the normally closed electric control valve through a fourth interface of the multi-way joint.

In a preferred embodiment, the comparison sensor is mounted on a fourth interface of the multi-way joint; or a fourth interface of the multi-way joint is connected with a second gas collecting pipeline, and the comparison sensor is installed on the second gas collecting pipeline.

Further, the alignment sensor comprises a second pressure sensor; or, the comparison sensor comprises a second pressure sensor and a second temperature sensor; or the comparison sensor is a second gas density transmitter consisting of a second pressure sensor and a second temperature sensor; or the comparison sensor is a second density detection sensor adopting a quartz tuning fork technology.

The density detection sensor of the quartz tuning fork technology or the second density detection sensor of the quartz tuning fork technology is characterized in that the constant resonance frequency of a quartz oscillator in vacuum and the resonance frequency difference of a quartz oscillator in a homologous state in a gas to be detected are in direct proportion to the density of the gas to be detected, and an analog signal or a digital signal of the gas density value is obtained after processing.

The temperature sensor or the second temperature sensor may be a thermocouple, a thermistor, or a semiconductor type; can be a contact type or a non-contact type; can be a thermal resistor or a thermocouple; either digital or analog.

The pressure sensor or the second pressure sensor may be a diffused silicon pressure sensor, an MEMS pressure sensor, a chip pressure sensor, a coil-induced pressure sensor (e.g., a pressure sensor with an induction coil in the barton tube), or a resistive pressure sensor (e.g., a pressure sensor with a slide wire resistor in the barton tube); the pressure sensor can be an analog pressure sensor or a digital pressure sensor.

Further, the intelligent control unit compares and diagnoses a first pressure value P1 acquired by the gas density detection sensor and a second pressure value P2 acquired by the comparison sensor under the same gas pressure; and/or the intelligent control unit compares and diagnoses a first temperature value T1 acquired by the gas density detection sensor and a second temperature value T2 acquired by the comparison sensor at the same gas temperature; or, the intelligent control unit is used for detecting a first density value acquired by the gas density detection sensor under the same gas densityP1₂₀And a second density value P2 collected by the comparison sensor₂₀And comparing and diagnosing to obtain the current working state of the digital gas density relay.

Further, the intelligent control unit uploads the received data to a background through a communication module, and the background performs comparison diagnosis on a first pressure value P1 acquired by a gas density detection sensor and a second pressure value P2 acquired by a comparison sensor under the same gas pressure; and/or the background carries out comparison diagnosis on a first temperature value T1 acquired by the gas density detection sensor and a second temperature value T2 acquired by the comparison sensor under the same gas temperature; or the background is used for acquiring a first density value P1 of the same gas density by a gas density detection sensor₂₀And a second density value P2 collected by the comparison sensor₂₀And comparing and diagnosing to obtain the current working state of the digital gas density relay.

In a preferred embodiment, the gas density detection sensor comprises a pressure sensor and a temperature sensor, and the comparison sensor comprises a second pressure sensor and a second temperature sensor; the pressure value collected by the pressure sensor of the gas density detection sensor is a first pressure value P1, and the temperature value collected by the temperature sensor is a first temperature value T1; comparing the pressure value acquired by a second pressure sensor of the sensor with a second pressure value P2, and the temperature value acquired by the second temperature sensor is a second temperature value T2; the intelligent control unit and/or the background compares the first pressure value P1 with the second pressure value P2 to obtain a pressure difference | P1-P2|, and/or compares the first temperature value T1 with the second temperature value T2 to obtain a temperature difference | T1-T2 |; if the pressure difference | P1-P2| and/or the temperature difference | T1-T2| are/is within the preset threshold value, the current working state of the digital gas density relay or the gas density monitoring device is a normal working state, otherwise, the current working state is an abnormal working state.

In a preferred embodiment, the gas density detection sensor comprises a gas density detection sensor, and the comparison sensor comprises a second gas density detection sensor; the density value of the gas collected by the gas density detection sensor is a first density value P1₂₀Comparison and transmissionThe density value of the gas collected by the sensor is a second density value P2₂₀(ii) a The intelligent control unit and/or the background enable the first density value P1₂₀And a second density value P2₂₀Comparing to obtain density difference | P1₂₀-P2₂₀L, |; if the density difference | P1₂₀-P2₂₀If the absolute value is within the preset threshold value, the current working state of the digital gas density relay or the gas density monitoring device is a normal working state, otherwise, the current working state is an abnormal working state.

Further, at the time of zero-position check diagnosis, that is, at zero pressure, the pressure signal collected by the gas density detection sensor is the first pressure signal P1₀Comparing the pressure signal collected by the sensor to obtain a second pressure signal P2₀The intelligent control unit and/or the background transmits the first pressure signal P1₀A second pressure signal P2₀Respectively comparing with zero pressure; if pressure difference | P1₀The intelligent control unit corrects the pressure signal acquired by the gas density detection sensor to enable the corrected first pressure signal P1 to be equal to or larger than a preset threshold value₀Repairing the smaller than the corresponding preset threshold value; and/or, if the pressure difference | P2₀The intelligent control unit corrects the pressure signal acquired by the sensor in comparison with a preset threshold value of-0 | ≧ and enables the corrected second pressure signal P2₀And modifying the corresponding preset threshold value.

Furthermore, the gas density detection sensor comprises a temperature sensor, and the intelligent control unit and/or the background compares the environmental temperature value with the temperature value acquired by the temperature sensor of the gas density detection sensor to complete the calibration of the temperature sensor of the gas density detection sensor; and/or the presence of a gas in the gas,

compare the sensor and include second temperature sensor, intelligence accuse unit and/or backstage compare ambient temperature value, and the temperature value of comparing the second temperature sensor collection of sensor compares, accomplishes the check-up of contrast to the second temperature sensor of sensor.

In a preferred embodiment, the acquired temperature value is a first temperature value T1, the environment temperature value is a second temperature value TH, and the intelligent control unit and/or the background compares the first temperature value T1 with the second temperature value TH to obtain a temperature difference | T1-TH |; if the temperature difference | T1-TH | is within a preset threshold value, the current working state of the digital gas density relay or the gas density monitoring device is a normal working state, otherwise, the current working state is an abnormal working state; wherein the first temperature value T1 is from the gas density detection sensor or from the comparison sensor.

The environment temperature value is obtained by comprehensively judging the temperature values of other detection points of a system comprising a digital gas density relay or a gas density monitoring device; or from weather forecasts; or the temperature values of other detection points of the same transformer substation are obtained through comprehensive judgment.

Preferably, the gas density detection sensor comprises at least one pressure sensor and at least one temperature sensor; randomly arranging and combining the pressure values acquired by the pressure sensors and the temperature values acquired by the temperature sensors, converting the combinations into a plurality of pressure values corresponding to 20 ℃ according to gas pressure-temperature characteristics, namely gas density values, and comparing the gas density values to finish self diagnosis of the pressure sensors and the temperature sensors; alternatively, the first and second electrodes may be,

the pressure values collected by the pressure sensors and the temperature values collected by the temperature sensors are subjected to all permutation and combination, and the combination is converted into a plurality of corresponding pressure values at 20 ℃ according to gas pressure-temperature characteristics, namely gas density values, and the gas density values are compared to finish self diagnosis of the pressure sensors and the temperature sensors; alternatively, the first and second electrodes may be,

and comparing the gas density values, the pressure values and the temperature values obtained by the pressure sensors and the temperature sensors to finish the self-diagnosis of the pressure sensors and the temperature sensors.

The self-diagnosis of the pressure sensors and the temperature sensors can be completed by the intelligent control unit or the background.

Preferably, the intelligent control unit calculates the gas density value by using an average method (mean method), wherein the average method is as follows: setting acquisition frequency in a set time interval, and carrying out average value calculation processing on N gas density values of different acquired time points to obtain the gas density values; alternatively, the first and second electrodes may be,

setting temperature interval step length in a set time interval, and carrying out average value calculation processing on density values corresponding to N different temperature values acquired in all temperature ranges to obtain gas density values; or setting a pressure interval step length in a set time interval, and carrying out average value calculation processing on density values corresponding to N different pressure values acquired in the whole pressure variation range to obtain a gas density value;

wherein N is a positive integer greater than or equal to 1.

Preferably, the annunciator includes, but is not limited to, one of an electromagnetic relay, a solid state relay, a MOS FET relay, a power relay, an electronic switch, and a thyristor.

Preferably, the digital gas density relay with the self-diagnosis function or the gas density monitoring device with the self-diagnosis function further comprises a filter connected to the other end of the normally closed electrically controlled valve.

Preferably, the communication mode of the communication module includes a wired communication mode and a wireless communication mode.

More preferably, the wired communication mode comprises one or more of an RS232 BUS, an RS485 BUS, an RS422 BUS, a CAN-BUS BUS, 4-20mA, Hart, IIC, SPI, Wire, a coaxial cable, a PLC power carrier and a cable Wire.

More preferably, the wireless communication mode includes one or more of a 5G/NB-IOT communication module (e.g., 5G, NB-IOT), a 2G/3G/4G/5G, WIFI, bluetooth, Lora, Lorawan, Zigbee, infrared, ultrasonic, sound wave, satellite, light wave, quantum communication, sonar, which are built in the sensor.

Preferably, the digital gas density relay with the self-diagnosis function or the gas density monitoring device with the self-diagnosis function further comprises a protection circuit, the protection circuit is arranged on the intelligent control unit or connected with the intelligent control unit, and the protection circuit comprises, but is not limited to, one or more of a surge protection circuit, a filter circuit, a short-circuit protection circuit, a polarity protection circuit and an overvoltage protection circuit.

Preferably, the digital gas density relay with self-diagnosis function or the gas density monitoring device with self-diagnosis function further comprises a short-circuit and/or open-circuit diagnosis circuit configured to diagnose the circuit with short-circuit and/or open-circuit fault of the digital gas density relay.

Preferably, the digital gas density relay with the self-diagnosis function or the gas density monitoring device with the self-diagnosis function further comprises a heater and/or a heat sink connected with the intelligent control unit, wherein the intelligent control unit turns on the heater when the temperature is lower than a set value or turns on the heat sink when the temperature is higher than the set value.

Preferably, the intelligent control unit includes, but is not limited to, a microprocessor, a power supply, and a data storage.

Preferably, the control of the intelligent control unit is controlled through a field control and/or a background control.

Preferably, the preset threshold value can be modified in the field and/or in the background.

Preferably, the intelligent control unit is provided with an electrical interface, and the electrical interface completes test data storage, and/or test data export, and/or test data printing, and/or data communication with an upper computer, and/or analog quantity and digital quantity information input.

Preferably, a clock is further arranged on the intelligent control unit, and the clock is configured to be used for regularly setting the self-calibration time of the digital gas density relay, or recording the test time, or recording the event time.

Preferably, the digital gas density relay with the self-diagnosis function or the gas density monitoring device with the self-diagnosis function further comprises a display interface for human-computer interaction, wherein the display interface is connected with the intelligent control unit, displays the current verification data in real time and/or supports data input.

Preferably, the digital gas density relay with the self-diagnosis function or the gas density monitoring apparatus with the self-diagnosis function further includes: respectively with gas density detection sensor with the little water sensor that the unit is connected is controlled to the intelligence, and/or respectively with gas density detection sensor with the decomposition thing sensor that the unit is connected is controlled to the intelligence.

Preferably, the digital gas density relay with the self-diagnosis function further includes: the contact resistance detection unit is connected with a contact signal of the digital gas density relay or directly connected with a signaler in the digital gas density relay; when the contact of the digital gas density relay acts and/or receives an instruction for detecting the contact resistance of the contact, the contact resistance detection unit can detect the contact resistance value of the contact of the digital gas density relay.

Preferably, at least two digital gas density relays with self-diagnosis function or gas density monitoring devices with self-diagnosis function are connected with a remote background detection system through a communication module; the digital gas density relay or the gas density monitoring device is arranged on the electrical equipment corresponding to the gas chamber, and the communication mode of the communication module comprises a wired communication mode and a wireless communication mode.

More preferably, at least two of the digital gas density relays with the self-diagnosis function or the gas density monitoring devices with the self-diagnosis function are connected with the remote background detection system sequentially through the concentrator and the protocol converter; the digital gas density relay or the gas density monitoring device is arranged on the electrical equipment of the corresponding gas chamber.

Further, the hub adopts an RS485 hub; the protocol converter adopts an IEC61850 or IEC104 protocol converter.

More preferably, the intelligent control unit completes online diagnosis of the digital gas density relay or the gas density monitoring device according to the setting of the remote background detection system or a remote control instruction; or, completing the online diagnosis of the digital gas density relay or the gas density monitoring device according to the set diagnosis time of the digital gas density relay.

Compared with the prior art, the technical scheme of the utility model following beneficial effect has:

the digital gas density relay or monitoring device with the self-diagnosis function is provided, the current working state of the digital gas density relay is obtained through zero check diagnosis of the gas density detection sensor while the gas density of gas-insulated or arc-extinguishing electrical equipment is monitored and monitored, the online self-diagnosis or self-diagnosis of the digital gas density relay is completed, the working efficiency is improved, the maintenance is not needed, the operation and maintenance cost is reduced, and the safe operation of a power grid is guaranteed.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the application and, together with the description, serve to explain the application and are not intended to limit the application. In the drawings:

fig. 1 is a schematic circuit diagram of a digital gas density relay with a self-diagnostic function for a high and medium voltage electrical apparatus according to a first embodiment;

fig. 2 is a schematic view of a gas path structure of a digital gas density relay or a gas density monitoring device with a self-diagnosis function for a high and medium voltage electrical apparatus according to the first embodiment;

fig. 3 is a schematic circuit diagram of a digital gas density relay or a gas density monitoring device with a self-diagnosis function for a high and medium voltage electrical apparatus according to a second embodiment;

fig. 4 is a schematic view of a gas path structure of a digital gas density relay or a gas density monitoring device with a self-diagnosis function for a high and medium voltage electrical apparatus according to a second embodiment;

fig. 5 is a schematic circuit diagram of a digital gas density relay with a self-diagnostic function for a high and medium voltage electrical apparatus according to a third embodiment.

Detailed Description

In order to make the objects, technical solutions and effects of the present invention clearer and clearer, the present invention will be described in further detail with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

The first embodiment is as follows:

fig. 1 is the circuit principle schematic diagram of the digital gas density relay with self-diagnosis function for the first high and medium voltage electrical equipment of the utility model, and fig. 2 is the gas circuit structure schematic diagram of the digital gas density relay or the gas density monitoring device with self-diagnosis function for the first high and medium voltage electrical equipment of the embodiment.

As shown in fig. 1 and 2, a digital gas density relay or gas density monitoring device having a self-diagnostic function includes: the intelligent gas density relay comprises a digital gas density relay shell 14, a gas density detection sensor 1, an intelligent control unit 2, a communication module 3, a display unit 4, an annunciator 5, a temperature control unit 7, a protection circuit (a surge protection circuit 801, a filter circuit 802 and a short-circuit protection circuit 803), a short-circuit and/or open-circuit diagnosis circuit 9, a normally-open electric control valve 10, a multi-way connector 11, a normally-closed electric control valve 12 and a filter 13. The gas density detection sensor 1 comprises a pressure sensor 101 and a temperature sensor 102, wherein the pressure sensor 101 is used for collecting pressure values, and the temperature sensor 102 is arranged on the digital gas density relay shell 14. The intelligent control unit 2 is respectively connected with the pressure sensor 101 and the temperature sensor 102 of the gas density detection sensor 1, the communication module 3, the display unit 4, the annunciator 5, the heater 701, the fan 702, the short circuit and/or open circuit diagnosis circuit 9, the normally open electronic control valve 10 and the normally closed electronic control valve 12. Shielding may also be provided on the outside or inside of the digital gas density relay housing 14 to improve electromagnetic interference resistance.

One end of the normally open electric control valve 10 is provided with an interface communicated with electrical equipment and used for being communicated with the electrical equipment on a gas path, and the other end of the normally open electric control valve is communicated with the multi-way joint 11; one end of the normally closed electric control valve 12 is communicated with the multi-way joint 11, and the other end of the normally closed electric control valve 12 is communicated with air (or directly communicated with air) through a filter 13; the pressure sensor 101 of the gas density detection sensor 1 is in communication with the multi-way joint 11 on the gas path. The normally open electronic control valve 10 is configured to close an air path between the electrical equipment and the gas density detection sensor 1 and the normally closed electronic control valve 12, and the normally closed electronic control valve 12 is configured to open the air path of the gas density detection sensor 1, so that the gas density detection sensor 1 is communicated with the air, and zero position check diagnosis of the pressure sensor 101 of the gas density detection sensor 1 is realized. When the zero-position check is diagnosed, the intelligent control unit 2 controls the annunciator 5, and the annunciator 5 cannot output an alarm and/or a locking contact signal.

The intelligent control unit 2 includes a microprocessor 201, a memory 202, and a power supply 203.

The communication mode of the communication module 3 may be wired or wireless, for example, a wired mode of an RS485 bus or a wireless mode of a 5G/NB-IOT communication module (e.g., 5G, NB-IOT) may be used to upload data or information. Of course, the wired communication mode CAN be any one or more of industrial buses such as RS232, RS422, CAN-BUS and the like, optical fiber Ethernet, 4-20mA, Hart, IIC, SPI, Wire, coaxial cables and PLC power carriers; the wireless communication mode can also be any one or more of 2G/3G/4G/5G, WIFI, Bluetooth, Lora, Lorawan, Zigbee, infrared, ultrasonic wave, sound wave, satellite, light wave, quantum communication and sonar.

The display unit 4 uses liquid crystal or nixie tube elements to display data or information locally.

The annunciator 5 adopts an electromagnetic relay or a solid-state relay, and is controlled to be switched on or off by the intelligent control unit 2. Of course, the annunciator 5 may be any one of a MOS FET relay, a power relay, an electronic control relay, an electronic switch, and a thyristor.

Among them, the temperature control unit 7 includes a heater 701 and a fan 702. When ambient temperature is low excessively and the temperature is less than the setting value, unit 2 control heater 701 is controlled to the intelligence and opens, and when ambient temperature was too high, the temperature was higher than the setting value, unit 2 control fan 702 was controlled to the intelligence and opens, makes the inside temperature of digital gas density relay casing 14 keep in a reasonable range, prevents to appear crossing excessively or too high.

Wherein, surge protection circuit 801 adopts discharge tube, and when the voltage value of surge was too high in the twinkling of an eye, discharge tube played, released too high surge voltage, played the effect that the unit 2 was controlled to the protection intelligence. The filter circuit 802 employs inductive and/or capacitive filtering, also to protect the smart control unit 2. The short-circuit protection circuit 803 adopts a thermistor or a self-recovery fuse, and when a short circuit occurs, the self-recovery fuse of the short-circuit protection circuit 803 is disconnected, so that the intelligent control unit 2 is protected. Of course, the protection circuit may further include any one or more of a polarity protection circuit and an overvoltage protection circuit.

The short circuit and/or open circuit diagnosis circuit 9 is used for diagnosing a main circuit of the digital gas density relay with short circuit and/or open circuit faults. In this embodiment, the short circuit and/or open circuit diagnosis circuit 9 adopts a current transformer or a hall current sensor, and when the current of the short circuit and/or open circuit diagnosis circuit (i.e. the hall current sensor) 9 is too large (short circuit occurs) or there is no current (open circuit occurs), the intelligent control unit 2 can judge that a short circuit and/or open circuit fault occurs.

In addition, at least two digital gas density relays or gas density monitoring devices can be connected with a remote background detection system through a communication module; the digital gas density relay or the gas density monitoring device is arranged on the electrical equipment of the corresponding gas chamber. The intelligent control unit 2 is controlled through field control and/or background control. For example, at least two of the digital gas density relays or the gas density monitoring devices are connected to the remote background detection system sequentially through a hub and a protocol converter, wherein the hub may adopt an RS485 hub, and the protocol converter may adopt an IEC61850 or IEC104 protocol converter.

The working principle and the working process of the embodiment are as follows:

the intelligent control unit 2 obtains the pressure value P1 and the temperature value T1 collected by the pressure sensor 101 and the temperature sensor 102 of the gas density detection sensor 1 according to the gas pressure thereofConversion of temperature characteristics into gas density values P1₂₀(ii) a Or the intelligent control unit 2 acquires the gas density value P1 acquired by the pressure sensor 101 and the temperature sensor 102 of the gas density detection sensor 1₂₀. The intelligent control unit 2 uploads the parameters including, but not limited to, the gas density value P1 through the communication module 3₂₀And one or more of a pressure value P1 and a temperature value T1, the online monitoring of the gas density of the monitored electrical equipment by the digital gas density relay is completed. When the gas density value is lower than and/or higher than the preset contact threshold value, the intelligent control unit 2 controls the annunciator 5 to enable the annunciator 5 to output an alarm and/or lock a contact signal, so that the monitoring of the gas density value in the electrical equipment is completed. The contact of the annunciator 5 is switched on to send out a corresponding contact signal (alarm or locking), so that the aim of monitoring and controlling the density of sulfur hexafluoride gas in equipment such as an electrical switch and the like is fulfilled, and the electrical equipment can work safely. If the gas density value is increased, the intelligent control unit 2 controls the annunciator 5, the contact of the annunciator 5 is disconnected, and the contact signal (alarm or lock) is released. For example, assume the parameters of a digital gas density relay are: the rated pressure value is 0.6MPa, the alarm contact pressure value is 0.55MPa, and the locking contact pressure value is 0.50 MPa. When the equipment runs and air leakage occurs, and the gas density value of the equipment is reduced to 0.55MPa of the preset threshold value of the alarm contact, the intelligent control unit 2 controls the annunciator 5 to enable the annunciator 5 to output an alarm contact signal; and when the gas density value is reduced to the preset threshold value of the locking contact point of 0.50MPa, the intelligent control unit 2 controls the annunciator 5 to enable the annunciator 5 to output a locking contact point signal, so that the monitoring of the gas density value in the electrical equipment is completed, and the electrical equipment can run safely and reliably. The contact preset threshold may be modified in the field and/or in the background. In the monitoring state, the normally open electrically controlled valve 10 is in an open state, and the normally closed electrically controlled valve 12 is in a closed state.

Wherein, intelligence accuse unit 2 adopts the mean value method (mean value method) to calculate gas density value, the purpose makes the monitoring data more accurate. Specifically, the averaging method is as follows: setting acquisition frequency in a set time interval, and carrying out average value calculation processing on N gas density values of different acquired time points to obtain the gas density values; or setting a temperature interval step length in a set time interval, and carrying out average value calculation processing on density values corresponding to N different temperature values acquired in the whole temperature range to obtain a gas density value; or setting a pressure interval step length in a set time interval, and carrying out average value calculation processing on density values corresponding to N different pressure values acquired in the whole pressure variation range to obtain a gas density value; wherein N is a positive integer greater than or equal to 1.

When zero-bit check diagnosis, through the control of intelligence accuse unit 2, normally open automatically controlled valve 10 and be in the off-state, intelligence accuse unit 2 is controlled again and is opened normally closed automatically controlled valve 12, makes gas pressure slowly fall to when the zero-bit, intelligence accuse unit 2 receives pressure signal P1 that gas density detected sensor 1's pressure sensor 101 gathered₀If the pressure difference | P1₀And-0 | ≧ a preset threshold value, the intelligent control unit 2 sends a signal and/or information that the zero offset of the pressure sensor 101 of the gas density detection sensor 1 is abnormal. After the zero calibration and diagnosis work is completed, the intelligent control unit 2 closes the normally closed electric control valve 12 and then opens the normally open electric control valve 10, so that the digital gas density relay is restored to the monitored working state. In addition, the pressure signal P1 collected by the pressure sensor 101 of the gas density detection sensor 1₀If the pressure difference | P1₀The intelligent control unit 2 can also correct the pressure signal collected by the pressure sensor 101 of the gas density detection sensor 1 to make the corrected P1 equal to or greater than-0 | ≧ the preset threshold value_{Repair 0}Corresponding preset thresholds are met. Specifically, in the case where there is no zero pressure, the pressure signal collected by the pressure sensor 101 of the gas density detection sensor 1 may be subjected to the zeroing process to be returned to the normal state.

In addition, after the digital gas density relay completes the zero checking and diagnosing work of the pressure sensor 101 of the gas density detection sensor 1, if abnormal, an alarm can be automatically sent out, and the alarm can be uploaded to a remote end (a monitoring room, a background monitoring platform and the like) through the communication module 3 or can be sent to a designated receiver, for example, a mobile phone, and a notification can be displayed on site. In a word, the reliable performance of the digital gas density relay can be fully ensured in multiple modes and various combinations.

Example two:

fig. 3 is a schematic circuit diagram of a digital gas density relay or a gas density monitoring device with a self-diagnosis function for a high and medium voltage electrical apparatus according to a second embodiment; fig. 4 is a schematic view of a gas path structure of a digital gas density relay or a gas density monitoring device having a self-diagnostic function for a high and medium voltage electrical apparatus according to a second embodiment.

As shown in fig. 3 and fig. 4, different from the first embodiment, the present embodiment further includes a comparison sensor 6, and the comparison sensor 6 includes a second pressure sensor 601. On the gas path, the pressure sensor 101 of the gas density detection sensor 1 and the second pressure sensor 601 of the comparison sensor 6 are respectively communicated with the multi-way joint 11. The normally open electric control valve 10 is configured to close the gas density detection sensor 1, compare the gas circuit of the sensor 6 and the normally closed electric control valve 12 with the electrical equipment, and the normally closed electric control valve 12 is configured to open the gas circuit of the gas density detection sensor 1 and the gas circuit of the comparison sensor 6, so that the gas density detection sensor 1 and the comparison sensor 6 are communicated with the air, and zero position check diagnosis of the pressure sensor 101 of the gas density detection sensor 1 and/or the second pressure sensor 601 of the comparison sensor 6 is realized. Also, the smart control unit 2 can control the annunciator 5 when the zero check diagnosis is performed, and the annunciator 5 does not output an alarm and/or a locking contact signal.

The working principle and the working process of the embodiment are as follows:

the working principle of the gas density value monitoring and the gas density value monitoring in this embodiment is the same as that in the first embodiment, and will not be described herein again.

When zero-bit check diagnosis, through the control of intelligence accuse unit 2, normally open automatically controlled valve 10 and be in the off-state, intelligence accuse unit 2 is controlled again and is opened normally closed automatically controlled valve 12, makes gas pressure slowly fall to when the zero-bit, intelligence accuse unit 2 receives pressure signal P1 that gas density detected sensor 1's pressure sensor 101 gathered₀And the second receiving the comparison sensor 6The second pressure signal P2 collected by the two pressure sensors 601₀. If pressure difference | P1₀When the value of-0 | ≧ a preset threshold value, the intelligent control unit 2 sends a signal and/or information of the zero offset abnormality of the pressure sensor 101 of the gas density detection sensor 1; if pressure difference | P2₀-0| ≧ preset threshold, the intelligent control unit 2 signals and/or messages an anomaly compared to the zero offset of the second pressure sensor 601 of the sensor 6.

After the zero calibration and diagnosis work is completed, the intelligent control unit 2 closes the normally closed electric control valve 12 and then opens the normally open electric control valve 10, so that the digital gas density relay is restored to the monitored working state. In addition, if the pressure difference | P1₀The intelligent control unit 2 can also correct the pressure signal collected by the pressure sensor 101 of the gas density detection sensor 1 to make the corrected P1 equal to or greater than-0 | ≧ the preset threshold value_{Repair 0}Corresponding preset threshold values are met; if pressure difference | P2₀The intelligent control unit 2 can also correct the pressure signal acquired by the second pressure sensor 601 of the sensor 6 by comparing-0 | ≧ the preset threshold value, so that the corrected P2_{Repair 0}Corresponding preset thresholds are met. Specifically, in the case where there is no zero pressure, the pressure signal collected by the pressure sensor 101 of the gas density detection sensor 1 and/or the second pressure sensor 601 of the comparison sensor 6 may be subjected to the zeroing process to return to the normal state.

In addition, in real time or according to a preset time, the intelligent control unit 2 and/or the background compares the first pressure value P1 collected by the pressure sensor 101 of the gas density detection sensor 1 and the second pressure value P2 collected by the second pressure sensor 601 of the comparison sensor 6 under the same gas pressure to obtain a pressure difference | P1-P2|, and if the pressure difference | P1-P2| is within a preset threshold, the current working state of the digital gas density relay or the gas density monitoring device is a normal working state, otherwise, the current working state is an abnormal working state.

The intelligent control unit 2 and/or the background can compare the ambient temperature value with the temperature value acquired by the temperature sensor 102 of the gas density detection sensor 1 to complete the calibration of the temperature sensor 102 of the gas density detection sensor 1. Specifically, the intelligent control unit 2 and/or the background compares a first temperature value T1 acquired by the temperature sensor 102 of the gas density detection sensor 1 at the same gas temperature with an ambient temperature value (which is a second temperature value TH and can be provided by the background) to obtain a temperature difference | T1-TH |, and if the temperature difference | T1-TH | is within a preset threshold value, the current working state of the digital gas density relay or the gas density monitoring device is a normal working state, otherwise, the current working state is an abnormal working state.

Or, the first temperature value T1A acquired by the temperature sensor 102 of the gas density detection sensor 1 of the device a, the first temperature value T1B acquired by the temperature sensor 102 of the gas density detection sensor 1 of the device B, the first temperature value T1C acquired by the temperature sensor 102 of the gas density detection sensor 1 of the device C, and so on, can also pass through the same substation in the background. The background can compare and diagnose the temperature values of T1A, T1B and T1C, and if a certain temperature value is obviously deviated, the current working state of the temperature sensor 102 of the gas density detection sensor 1 of the equipment is monitored to be an abnormal working state; if the current working states of the digital gas density relay or the gas density monitoring device are basically close to each other, the current working states of the digital gas density relay or the gas density monitoring device are normal working states.

Example three:

as shown in fig. 5, unlike the second embodiment, in the present embodiment, the comparison sensor 6 includes a second pressure sensor 601 and a second temperature sensor 602. On the gas path, the pressure sensor 101 of the gas density detection sensor 1 and the second pressure sensor 601 of the comparison sensor 6 are respectively communicated with the multi-way joint 11.

Specifically, the pressure value collected by the pressure sensor 101 of the gas density detection sensor 1 is a first pressure value P1, and the temperature value collected by the temperature sensor 102 is a first temperature value T1; the pressure value acquired by the second pressure sensor 601 of the comparison sensor 6 is a second pressure value P2, and the temperature value acquired by the second temperature sensor 602 is a second temperature value T2. Alternatively, the gas density detection sensor 1 collects the gas density value as the first density value P1₂₀Comparing the gas density value collected by the sensor 6 to a second density value P2₂₀。

The intelligent control unit 2 and/or the background can compare a first pressure value P1 with a second pressure value P2 under the same gas pressure to obtain a pressure difference | P1-P2|, and/or the intelligent control unit 2 and/or the background compares a first temperature value T1 with a second temperature value T2 under the same gas temperature to obtain a temperature difference | T1-T2 |; if the pressure difference | P1-P2| and/or the temperature difference | T1-T2| are/is within the preset threshold value, the current working state of the digital gas density relay or the gas density monitoring device is a normal working state, otherwise, the current working state is an abnormal working state. Or, the intelligent control unit 2 and/or the background converts the first density value P1₂₀And a second density value P2₂₀Comparing to obtain density difference | P1₂₀-P2₂₀If the density difference is | P1₂₀-P2₂₀If the absolute value is within the preset threshold value, the current working state of the digital gas density relay or the gas density monitoring device is a normal working state, otherwise, the current working state is an abnormal working state.

As long as the detection data of the pressure sensor 101, the temperature sensor 102, the second pressure sensor 601, the second temperature sensor 602 and the like are consistent and normal, the digital gas density relay is normal, so that the digital gas density relay is verified on site by maintenance personnel in a traditional mode, and the service life can be prolonged without manual verification. Unless the detected data of the pressure sensor 101, the temperature sensor 102, the second pressure sensor 601, the second temperature sensor 602, and the like of one of the electrical devices in the substation are inconsistent and abnormal, the maintenance personnel is not scheduled to process the data. And for anastomotic and normal, manual verification is not needed, so that the reliability and the working efficiency are greatly improved, and the cost is reduced. In addition, in the case of no zero pressure, the pressure signal collected by the pressure sensor 101 of the gas density detection sensor 1 and/or the pressure sensor 601 of the comparison sensor 6 may be subjected to a zero adjustment process to return to a normal state, thereby prolonging the service life or returning to the normal state as soon as possible.

The intelligent control unit 2 and/or the background can also compare the ambient temperature value with a first temperature value acquired by the temperature sensor 102 of the gas density detection sensor 1 to complete the verification of the temperature sensor 102 of the gas density detection sensor 1; and comparing the ambient temperature value with a second temperature value acquired by a second temperature sensor 602 of the comparison sensor 6, thereby completing the verification of the comparison on the second temperature sensor 602 of the sensor 6. Specifically, the intelligent control unit 2 and/or the background compares a first temperature value T1 acquired by the temperature sensor 102 of the gas density detection sensor 1 at the same gas temperature with an ambient temperature value (which is a second temperature value TH and can be provided by the background) to obtain a temperature difference | T1-TH |, and if the temperature difference | T1-TH | is within a preset threshold, the current working state of the temperature sensor 102 of the gas density detection sensor 1 is a normal working state, otherwise, the current working state is an abnormal working state. The intelligent control unit 2 and/or the background compares the second temperature value T2 acquired by the second temperature sensor 602 of the comparison sensor 6 with the ambient temperature value (for the second temperature value TH, which can be provided by the background) at the same gas temperature to obtain a temperature difference | T2-TH |, and if the temperature difference | T2-TH | is within a preset threshold value, the current working state of the second temperature sensor 602 of the comparison sensor 6 is a normal working state, otherwise, the current working state is an abnormal working state.

In addition, the gas density detection sensor 1 can also realize self-diagnosis of its own components. In a preferred embodiment, the gas density detection sensor 1 comprises at least one pressure sensor and at least one temperature sensor. Randomly arranging and combining the pressure values acquired by the pressure sensors and the temperature values acquired by the temperature sensors, converting the combinations into a plurality of pressure values corresponding to 20 ℃ according to gas pressure-temperature characteristics, namely gas density values, and comparing the gas density values to finish self diagnosis of the pressure sensors and the temperature sensors; or the pressure values acquired by the pressure sensors and the temperature values acquired by the temperature sensors are subjected to all permutation and combination, and each combination is converted into a plurality of corresponding pressure values at 20 ℃ according to the gas pressure-temperature characteristic, namely gas density values, and each gas density value is compared to finish the self-diagnosis of each pressure sensor and each temperature sensor; or comparing a plurality of gas density values, pressure values and temperature values obtained by each pressure sensor and each temperature sensor to finish the self-diagnosis of each pressure sensor and each temperature sensor.

Through the comparison, the online self-checking, the zero position checking and diagnosing or the comparison diagnosing of the digital gas density relay can be realized, the maintenance is not needed, the working efficiency is improved, the cost is reduced, and the safe operation of a power grid is ensured.

The gas density detection sensor 1 may include a pressure sensor 101 and a temperature sensor 102; alternatively, a gas density transmitter consisting of a pressure sensor and a temperature sensor can also be used; alternatively, a gas density detection sensor of quartz tuning fork technology may be employed. The above comparison sensor 6 may comprise a second pressure sensor 601; alternatively, a second pressure sensor 601 and a second temperature sensor 602 may be included; or, a comparison gas density transmitter consisting of a second pressure sensor and a second temperature sensor can also be adopted; alternatively, a second gas density detection sensor of quartz tuning fork technology may also be employed.

In this embodiment, other working principles are the same as those of the second embodiment, and are not described herein again.

The pressure sensors in the present application may be absolute pressure sensors, relative pressure sensors, or absolute pressure sensors and relative pressure sensors, and the number of the pressure sensors may be several. The pressure sensor can be in the form of a diffused silicon pressure sensor, a MEMS pressure sensor, a chip pressure sensor, a coil-induced pressure sensor (such as a pressure measurement sensor with an induction coil of a Badon tube), a resistance pressure sensor (such as a pressure measurement sensor with a slide wire resistance of a Badon tube), an analog pressure sensor or a digital pressure sensor. The pressure sensor is a pressure sensor, a pressure transmitter, and other pressure-sensitive elements, such as diffused silicon, sapphire, piezoelectric, and strain gauge (resistance strain gauge, ceramic strain gauge).

The temperature sensor in the application can be a thermocouple, a thermistor or a semiconductor type; contact and contactless are also possible; the temperature sensor may be a thermal resistor and a thermocouple, depending on the sensor material and the characteristics of the electronic components. In short, the temperature acquisition can be realized by various temperature sensing elements such as a temperature sensor, a temperature transmitter and the like.

The digital gas density relay in the application has the functions of pressure and temperature measurement and software conversion. On the premise of not influencing the safe operation of electrical equipment, the alarm and/or locking contact action value and/or return value of the digital gas density relay can be detected on line. Of course, the return value of the alarm and/or latch contact signal may also be left untested as desired.

The intelligent control unit 2 in the application mainly completes the control of the normally open electric control valve 10 and the normally closed electric control valve 12, the signal acquisition and the control of the annunciator 5. Of course, the intelligent control unit 2 can also realize: storing the test data; and/or test data derivation; and/or the test data may be printed; and/or the upper computer can carry out data communication; and/or analog quantity and digital quantity information can be input. Through intelligent control unit 2, digital gas density relay can contrast the judgement automatically, if the error phase difference is big, will send unusual suggestion: the digital gas density relay has a problem in that it can perform a self-diagnostic function of its own pressure sensor, temperature sensor, density transmitter, or the like. The intelligent control unit 2 can also automatically generate a comparison diagnosis report of the gas density relay, and if the comparison diagnosis report is abnormal, the intelligent control unit can automatically send an alarm or send the alarm to a specified receiver, such as a mobile phone; and the gas density value and the comparison diagnosis result can be displayed on site or in a background, and the specific mode can be flexibly set. The intelligent control unit 2 can also have the functions of real-time online density value, pressure value, temperature value and other data display, change trend analysis, historical data query, real-time alarm and the like; the gas density value, or the density value, the pressure value and the temperature value can be monitored on line; the self-diagnosis function is provided, and abnormal and timely notices such as line breakage, short circuit alarm, sensor damage and the like can be notified; the performance of the digital gas density relay can be judged by comparing the error performance of the gas density relay in different time periods at different temperatures, namely comparing the error performance of the gas density relay in the same temperature range in different periods; the comparison of each period with history and the comparison of the history and the present are carried out. The intelligent control unit 2 can also judge whether the gas density values of the digital gas density relay and the monitored electrical equipment are normal or not, namely, can judge, analyze and compare the normality and the abnormality of the gas density values of the electrical equipment, the pressure sensor and the temperature sensor of the gas density relay. The intelligent control unit 2 can also comprise an analysis system (expert management analysis system) for detecting, analyzing and judging gas density monitoring, a gas density relay and a monitoring element, and knowing where the problem points are, whether the problem points are electrical equipment or the problem points of the gas density relay; the contact signal state of the gas density relay is monitored, and the state is remotely transmitted, so that the contact signal state of the gas density relay can be known at the background: the open or closed state is realized, so that one more layer of monitoring is realized, and the reliability is improved. The intelligent control unit 2 can also detect, or detect and judge contact resistance of a contact of the digital gas density relay; the system has the functions of data analysis and data processing, and can carry out corresponding fault diagnosis and prediction on the electrical equipment.

As described above, the digital gas density relay or the gas density monitoring apparatus having the self-diagnosis function has the self-diagnosis function, and can perform self-diagnosis for each element. The digital gas density relay or gas density monitoring device with the self-diagnosis function comprises a plurality of pressure sensors and temperature sensors, and comparison diagnosis can be performed between test data of the pressure sensors and between test data of the temperature sensors. The digital gas density relay or the gas density monitoring device with the self-diagnosis function can also compare the environmental temperature value with the sampling value of the temperature sensor to complete the calibration of the temperature sensor. The method and the device have the advantages that online self-checking or self-diagnosis of the digital gas density relay or the gas density monitoring device is realized, the working efficiency is improved, passive maintenance is not needed, the operation and maintenance cost is reduced, and the safe operation of a power grid is guaranteed.

It should be noted that, the digital gas density relay with self-diagnostic function described in this application generally refers to that its constituent elements are designed into an integral structure; the gas density monitoring device generally refers to that the components of the gas density monitoring device are designed into a split structure and flexibly formed. Gas temperature broadly refers to the temperature within the gas, or the corresponding ambient temperature. The utility model provides a check-up diagnostic method includes, but is not limited to corresponding difference respectively in its preset threshold value, the detection value in its settlement range, two correspond the quotient that the detection value divides in its preset threshold value arbitrary one. In the self-diagnosis method, the intelligent control unit and/or the background can complete comparison of corresponding detection results, and the mode can be flexible.

The above detailed description of the embodiments of the present invention is only for exemplary purposes, and the present invention is not limited to the above described embodiments. Any equivalent modifications and substitutions to those skilled in the art are also within the scope of the present invention. Accordingly, variations and modifications in equivalents may be made without departing from the spirit and scope of the invention, which is intended to be covered by the following claims.

Claims (17)

1. A digital gas density relay with a self-diagnostic function, comprising: the intelligent control system comprises a gas density detection sensor, an intelligent control unit, a signaler, a communication module, a normally open electric control valve and a normally closed electric control valve;

one end of the normally open electric control valve is provided with an interface communicated with electrical equipment, the other end of the normally open electric control valve is communicated with one end of the normally closed electric control valve, the other end of the normally closed electric control valve is communicated with air, and a gas density detection sensor is arranged on a gas path between the normally open electric control valve and the normally closed electric control valve and is used for collecting a pressure value, a temperature value and/or a gas density value of the gas path between the normally open electric control valve and the normally closed electric control valve;

the intelligent control unit is respectively connected with the gas density detection sensor, the annunciator, the communication module, the normally open electric control valve and the normally closed electric control valve; the intelligent control unit is configured to acquire the gas density value acquired by the gas density detection sensor, or acquire the pressure value and the temperature value acquired by the gas density detection sensor and convert the pressure value and the temperature value into the gas density value according to the gas pressure-temperature characteristic; the intelligent control unit uploads one or more of a gas density value, a pressure value and a temperature value through the communication module and is used for completing the online monitoring of the gas density of the monitored electrical equipment by the digital gas density relay; the intelligent control unit is also configured to control the annunciator, enable the annunciator to output an alarm and/or a locking contact signal, and control the switching state of the normally-open electric control valve and the normally-closed electric control valve.

2. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: the intelligent control unit control annunciator does not output an alarm and/or a locking contact signal during zero position checking diagnosis.

3. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: when the gas density value is lower than and/or higher than the preset threshold value, the intelligent control unit controls the annunciator to enable the annunciator to output an alarm and/or a locking contact signal for finishing monitoring the gas density value in the electrical equipment.

4. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: the gas density detection sensor comprises a pressure sensor and a temperature sensor; or the gas density detection sensor is a gas density transmitter consisting of a pressure sensor and a temperature sensor; or, the gas density detection sensor is a density detection sensor adopting a quartz tuning fork technology.

5. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: the normally open electric control valve, the gas density detection sensor and the normally closed electric control valve are respectively arranged on the multi-way joint; and on the gas path, the other end of the normally open electric control valve is respectively communicated with the gas density detection sensor and one end of the normally closed electric control valve through a multi-way joint.

6. The digital gas density relay with self-diagnostic function according to claim 5, characterized in that: still including comparing the sensor, it also sets up on the joint to compare the sensor, it communicates on the gas circuit with gas density detection sensor through many logical joints to compare the sensor.

7. The digital gas density relay with self-diagnostic function according to claim 6, characterized in that: the comparison sensor comprises a second pressure sensor; or, the comparison sensor comprises a second pressure sensor and a second temperature sensor; or the comparison sensor is a second gas density transmitter consisting of a second pressure sensor and a second temperature sensor; or the comparison sensor is a second density detection sensor adopting a quartz tuning fork technology.

8. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: the annunciator comprises one of an electromagnetic relay, a solid state relay, an MOS FET relay, a power relay, an electronic switch and a silicon controlled rectifier.

9. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: the filter is connected to the other end of the normally closed electric control valve.

10. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: the communication mode of the communication module comprises a wired communication mode and a wireless communication mode.

11. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: still include protection circuit, protection circuit sets up on the unit is controlled to the intelligence or is connected with the unit is controlled to the intelligence, protection circuit includes surge protection circuit, filter circuit, short-circuit protection circuit, polarity protection circuit, overvoltage crowbar one kind or several kinds.

12. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: also included is a short and/or open diagnostic circuit configured to diagnose a circuit that has a short and/or open fault.

13. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: the intelligent control unit is connected with the intelligent control unit, and the heater is started when the temperature is lower than a set value, or the radiator is started when the temperature is higher than the set value.

14. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: the intelligent control unit comprises a microprocessor, a power supply and data storage.

15. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: still include the display element, the intelligence is controlled the unit and is passed through the display element display and include gas density value, pressure value, temperature value, one or several kinds of monitoring signal and/or information in the current operating condition.

16. The digital gas density relay with self-diagnostic function according to claim 1, characterized in that: at least two digital gas density relays with self-diagnosis functions are connected with a remote background detection system through communication modules; the digital gas density relay with the self-diagnosis function is arranged on the electrical equipment corresponding to the gas chamber, and the communication mode of the communication module comprises a wired communication mode and a wireless communication mode.

17. Digital gas density monitoring devices with self-diagnostic function characterized in that: the digital gas density monitoring device with the self-diagnosis function is composed of the digital gas density relay with the self-diagnosis function according to any one of claims 1 to 16; or, the digital gas density monitoring device with self-diagnosis function comprises the digital gas density relay with self-diagnosis function according to any one of claims 1 to 16.

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