Transformer substation relay protection equipment state monitoring method and system based on digital twinning
1. A transformer substation relay protection equipment state monitoring method based on digital twinning is characterized by comprising the following steps:
s1, constructing a digital twinning scene map of the transformer substation by utilizing a digital twinning technology based on the three-dimensional point cloud map of the transformer substation, wherein the digital twinning scene map comprises simulation position information of relay protection equipment in the transformer substation;
s2, obtaining operation environment data of each relay protection device in the transformer substation, wherein the operation environment data comprises temperature and humidity;
s3, comparing the operating environment data with a preset safe environment threshold value to judge whether the operating environment data are normal or not, and if not, calling an environment regulation and control system to regulate the operating environment of the corresponding relay protection equipment so as to enable the operating environment data to be normal;
s4, acquiring influence factor parameters of each relay protection device, wherein the influence factor parameters comprise a fault-free time parameter, a family fault-free time parameter, a correct action rate parameter, an insulation condition parameter, a data sampling parameter, a communication parameter, a channel test parameter and a difference flow parameter;
s5, evaluating the influence factor parameters based on a preset state evaluation rule, judging whether the state of the relay protection equipment is normal or not according to an evaluation result, and if the state of the relay protection equipment is judged to be abnormal, acquiring the real-scene position information of the corresponding relay protection equipment in the transformer substation;
s6, matching corresponding simulation position information in the digital twin scene map according to the live-action position information, and marking the simulation position information in the digital twin scene map according to the matching simulation position information to determine the position of the relay protection device in a fault state, wherein the live-action position information and the simulation position information are in a mapping relation.
2. The method for monitoring the state of the digital twin-based substation relay protection device according to claim 1, comprising before step S1:
s01, polling the transformer substation by a polling robot carrying a laser radar to obtain point cloud data of the transformer substation and point cloud data of each relay protection device in the transformer substation;
s02, constructing a three-dimensional point cloud map of the transformer substation based on the point cloud data of the transformer substation;
s03, matching in the three-dimensional point cloud map based on the point cloud data of each relay protection device in the transformer substation to obtain point cloud position information of each relay protection device in the three-dimensional point cloud map;
s04, acquiring a global live-action image of the transformer substation, and acquiring live-action position information of each relay protection device in the global live-action image;
s05, comparing the three-dimensional point cloud map with the global live-action image to obtain a mapping relation between the point cloud position information and the live-action position information of each relay protection device, and distributing the same ID to the point cloud position information and the live-action position information with the mapping relation.
3. The method for monitoring the state of the digital twin-based substation relay protection device according to claim 1, wherein step S2 specifically comprises:
acquiring the internal temperature, the external temperature, the internal humidity and the external humidity of each relay protection device in the transformer substation;
correspondingly, step S3 specifically includes:
s301, if the internal temperature is lower than a preset minimum safe temperature, judging whether the external temperature is higher than the preset minimum safe temperature or higher than a preset first temperature threshold, wherein the preset first temperature threshold is the sum of the internal temperature and a preset temperature difference, if the external temperature is higher than the preset minimum safe temperature or higher than the preset first temperature threshold, calling a ventilation system to enable the internal temperature to be equal to the external temperature, and if the external temperature is lower than the preset minimum safe temperature, calling a heat source system to heat the internal temperature to a preset safe temperature range; if the external temperature is not higher than the preset minimum safe temperature or higher than a preset first temperature threshold, calling the heat source system to heat the internal temperature to be within a preset safe temperature range;
the preset safety temperature range is a temperature interval between the preset minimum safety temperature and the preset maximum safety temperature;
s302, if the internal temperature is higher than the preset maximum safe temperature, determining whether the external temperature is lower than the preset maximum safe temperature or lower than a preset second temperature threshold, wherein the second temperature threshold is the difference between the internal temperature and the preset temperature difference, if the external temperature is lower than the preset maximum safe temperature or lower than the preset second temperature threshold, calling the ventilation system to enable the internal temperature to be equal to the external temperature, and if the external temperature is higher than the preset maximum safe temperature, calling the heat source system to heat the internal temperature to the preset safe temperature range;
if the external temperature is judged not to be below the preset maximum safe temperature or below a preset second temperature threshold, calling a cold source system to cool the internal temperature to be within a preset safe temperature range;
s303, if the internal humidity is greater than a preset maximum safe humidity, judging whether the external humidity is within a preset safe humidity range, if the external humidity is within the preset safe humidity range, judging whether the external humidity is below the preset maximum safe humidity or below a preset first humidity threshold value, wherein the preset first humidity threshold value is the difference between the internal humidity and a preset humidity difference, if the external humidity is below the preset maximum safe humidity or below the preset first humidity threshold value, calling the ventilation system to enable the internal humidity to be equal to the external humidity, and if the external humidity is greater than the preset maximum safe humidity, calling the drying system to dry the internal humidity to the preset safe humidity range;
the preset safe humidity range is a humidity interval between a preset minimum safe humidity and the preset maximum safe humidity;
s304, if when inside humidity is less than predetermined minimum safe humidity, judge whether outside humidity is at predetermined safe humidity scope, if outside humidity is at predetermined safe humidity scope, then judge whether outside humidity does more than predetermined minimum safe humidity or predetermine more than the second humidity threshold value, predetermine the second humidity threshold value and do inside humidity with predetermine the sum of humidity difference, if outside humidity is do more than predetermined minimum safe humidity or predetermine more than the second humidity threshold value, then call ventilation system makes inside humidity with outside humidity equals, works as outside humidity is less than predetermined minimum safe humidity, then calls humidification system will inside humidity humidification extremely in the predetermined safe humidity scope.
4. The method for monitoring the state of the digital twin-based substation relay protection device according to claim 1, wherein the non-failure time parameters comprise an expected non-failure time and an actual non-failure time of the relay protection device;
the family fault-free time parameters comprise fault-free running time of relay protection equipment of the same model and fault-free running time of relay protection equipment of the same batch;
the correct action rate parameters comprise correct action rate parameters of the relay protection equipment, correct action rate parameters of the relay protection equipment with the same model and correct action rate parameters of the relay protection equipment in the same batch;
the insulation condition parameters comprise insulation data of each plug-in the relay protection equipment;
the data sampling parameters comprise analog quantity sampling and switching value sampling;
the communication parameters comprise communication conditions and related communication parameters thereof;
the channel test parameters comprise high-frequency channel test parameters and optical fiber channel test data;
the differential flow parameters comprise main transformer differential flow parameters, bus differential flow parameters and optical fiber longitudinal differential flow parameters.
5. The method for monitoring the state of the digital twin-based substation relay protection device according to claim 1, comprising after step S6:
s7, generating maintenance information according to fault information of the relay protection equipment in a fault state, and sending the maintenance information to a substation operation and maintenance center, wherein the fault information comprises position information of the relay protection equipment and an evaluation result of an influence factor parameter;
and S8, calling a rendering interface to perform color rendering on the relay protection equipment in the fault state in the digital twin scene map.
6. A digital twin-based substation relay protection equipment state monitoring system is used for executing the digital twin-based substation relay protection equipment state monitoring method of any one of claims 1-5, and is characterized by comprising the following steps: the system comprises a digital twin module, an operating environment acquisition module, an operating environment adjustment module, an influence factor acquisition module, an influence factor evaluation module and a fault positioning module;
the digital twinning module is used for constructing a digital twinning scene map of the transformer substation by utilizing a digital twinning technology based on a three-dimensional point cloud map of the transformer substation, and the digital twinning scene map comprises simulation position information of relay protection equipment in the transformer substation;
the operation environment acquisition module is used for acquiring operation environment data of each relay protection device in the transformer substation, wherein the operation environment data comprises temperature and humidity;
the operation environment adjusting module is used for comparing the operation environment data with a preset safe environment threshold value so as to judge whether the operation environment data is normal or not, and is also used for calling an environment regulating and controlling system to adjust the operation environment of the corresponding relay protection equipment when the operation environment data is judged to be abnormal so as to enable the operation environment data to be normal;
the system comprises an influence factor acquisition module, a data sampling module and a data processing module, wherein the influence factor acquisition module is used for acquiring influence factor parameters of each relay protection device, and the influence factor parameters comprise a fault-free time parameter, a family fault-free time parameter, a correct action rate parameter, an insulation condition parameter, a data sampling parameter, a communication parameter, a channel test parameter and a difference flow parameter;
the influence factor evaluation module is used for evaluating the influence factor parameters based on a preset state evaluation rule, judging whether the state of the relay protection equipment is normal according to an evaluation result, and acquiring real-scene position information of the corresponding relay protection equipment in the transformer substation if the state of the relay protection equipment is judged to be abnormal;
and the fault positioning module is used for matching corresponding simulation position information in the digital twin scene map according to the live-action position information and marking the simulation position information obtained by matching in the digital twin scene map so as to determine the position of the relay protection equipment in a fault state.
7. The system for monitoring the state of the digital twin-based substation relay protection device according to claim 6, further comprising a point cloud construction unit; the point cloud construction unit comprises an inspection robot, a point cloud map construction module, a point cloud matching module, an image acquisition module and a mapping determination module;
the inspection robot is provided with a laser radar and is used for inspecting the transformer substation and obtaining point cloud data of the transformer substation and point cloud data of each relay protection device in the transformer substation;
the point cloud map building module is used for building a three-dimensional point cloud map of the transformer substation based on the point cloud data of the transformer substation;
the point cloud matching module is used for matching in the three-dimensional point cloud map based on point cloud data of each relay protection device in the transformer substation to obtain point cloud position information of each relay protection device in the three-dimensional point cloud map;
the image acquisition module is used for acquiring a global live-action image of the transformer substation and also used for acquiring live-action position information of each relay protection device in the global live-action image;
the mapping determining module is used for comparing the three-dimensional point cloud map with the global live-action image to obtain a mapping relation between the point cloud position information and the live-action position information of each relay protection device, and is also used for allocating the same ID to the point cloud position information and the live-action position information with the mapping relation.
8. The system for monitoring the state of the digital twin-based substation relay protection device according to claim 6, wherein the operating environment obtaining module is specifically configured to obtain an internal temperature, an external temperature, an internal humidity and an external humidity of each relay protection device in the substation;
correspondingly, the operating environment adjusting module comprises a temperature comparison sub-module, a humidity comparison sub-module, a ventilation sub-module, a heat source sub-module, a cold source sub-module, a drying sub-module and a humidifying sub-module;
the temperature comparison submodule is used for comparing the internal temperature with a preset minimum safe temperature and a preset maximum safe temperature respectively; the temperature control device is also used for comparing the external temperature with the preset minimum safe temperature, the preset maximum safe temperature, the preset first temperature threshold and the preset second temperature threshold respectively; also for numerically comparing the internal temperature and the external temperature; the preset first temperature threshold is the sum of the internal temperature and a preset temperature difference, and the second temperature threshold is the difference between the internal temperature and the preset temperature difference;
the humidity comparison submodule is used for comparing the internal humidity with a preset minimum safe humidity and a preset maximum safe humidity respectively through humidity values; the humidity value comparison module is further used for comparing the external humidity with the preset minimum safe humidity, the preset maximum safe humidity, the preset first humidity threshold value and the preset second humidity threshold value respectively; also for numerically comparing said internal humidity with said external humidity; the preset first humidity threshold is the difference between the internal humidity and a preset humidity difference, and the second humidity threshold is the sum of the internal humidity and the preset humidity difference;
the ventilation sub-module is used for mutually ventilating the inside and the outside of the relay protection device, so that the inside temperature is equal to the outside temperature and/or the inside humidity is equal to the outside humidity;
the heat source submodule is used for heating the interior of the relay protection equipment so as to heat the interior temperature to a preset safe temperature range, and the preset safe temperature range is a temperature interval between the preset minimum safe temperature and a preset maximum safe temperature;
the cold source submodule is used for cooling the interior of the relay protection equipment so as to cool the interior temperature to a preset safe temperature range;
the drying submodule is used for drying the interior of the relay protection device so as to dry the interior humidity to a preset safe humidity range, and the preset safe humidity range is a humidity interval between the preset minimum safe humidity and the preset maximum safe humidity;
the humidifying submodule is used for humidifying the inside of the relay protection device, so that the inside humidity is humidified to a preset safe humidity range.
9. The system of claim 6, further comprising: a sending module and a rendering module;
the sending module is used for generating maintenance information according to fault information of the relay protection equipment in a fault state and sending the maintenance information to a substation operation and maintenance center, wherein the fault information comprises position information of the relay protection equipment and an evaluation result of an influence factor parameter;
and the rendering module is used for calling a rendering interface to perform color rendering on the relay protection equipment in the fault state in the digital twin scene map.
Background
The digital twin is to construct a mapping of a same entity world in a digital world in a virtual space by utilizing a physical model, an internet of things sensor and simulation through a digital means. The transformer substation deeply fuses digital twins and three-dimensional design, greatly promotes the digital transformation of engineering design, construction, operation and maintenance links, and has important significance for high-quality construction of national power grids.
The market operation and maintenance of the transformer substation is an important means for ensuring the safe production of the transformer substation and improving the whole life cycle of equipment. The relay protection equipment is an important component of a power system of a transformer substation, and the running state of the relay protection equipment directly influences the safety and reliability of the power system, so that the state of the relay protection equipment is monitored, the real-time state of the relay protection equipment is facilitated to be known, and a reference basis is provided for maintenance of the relay protection equipment.
The traditional maintenance of the relay protection equipment is generally carried out according to a fixed period, the maintenance of the relay protection equipment cannot be realized in a targeted and accurate mode, and the over-detection and the omission detection states occur. Therefore, it is necessary to improve the accuracy of monitoring the state of the relay protection device.
In the display process, because the existing monitoring map mainly uses a two-dimensional logic view, the problems of shielding and incapability of visually embodying exist, in the maintenance process, specific equipment needs to be positioned, and most of equipment is close to or even the same in appearance when viewed from the appearance of the equipment due to the fact that substation equipment is dense and close to each other, and the problem of misoperation of an operator during maintenance due to positioning deviation exists.
Furthermore, the operation environment mainly comprises temperature and humidity, the temperature is too high or too low, the operation of the relay protection equipment can be seriously damaged due to too humid work and environment, and the accuracy of monitoring the state of the relay protection equipment can be influenced.
Disclosure of Invention
The application provides a method and a system for monitoring the state of relay protection equipment of a transformer substation based on digital twins, which are used for solving the technical problems that the existing transformer substation monitoring map easily causes positioning deviation and the running environment influences the accuracy of monitoring the state of the relay protection equipment.
In view of this, the first aspect of the present application provides a method for monitoring a state of a digital twin-based substation relay protection device, including the following steps:
s1, constructing a digital twinning scene map of the transformer substation by utilizing a digital twinning technology based on the three-dimensional point cloud map of the transformer substation, wherein the digital twinning scene map comprises simulation position information of relay protection equipment in the transformer substation;
s2, obtaining operation environment data of each relay protection device in the transformer substation, wherein the operation environment data comprises temperature and humidity;
s3, comparing the operating environment data with a preset safe environment threshold value to judge whether the operating environment data are normal or not, and if not, calling an environment regulation and control system to regulate the operating environment of the corresponding relay protection equipment so as to enable the operating environment data to be normal;
s4, acquiring influence factor parameters of each relay protection device, wherein the influence factor parameters comprise a fault-free time parameter, a family fault-free time parameter, a correct action rate parameter, an insulation condition parameter, a data sampling parameter, a communication parameter, a channel test parameter and a difference flow parameter;
s5, evaluating the influence factor parameters based on a preset state evaluation rule, judging whether the state of the relay protection equipment is normal or not according to an evaluation result, and if the state of the relay protection equipment is judged to be abnormal, acquiring the real-scene position information of the corresponding relay protection equipment in the transformer substation;
s6, matching corresponding simulation position information in the digital twin scene map according to the live-action position information, and marking the simulation position information in the digital twin scene map according to the matching simulation position information to determine the position of the relay protection device in a fault state, wherein the live-action position information and the simulation position information are in a mapping relation.
Preferably, step S1 is preceded by:
s01, polling the transformer substation by a polling robot carrying a laser radar to obtain point cloud data of the transformer substation and point cloud data of each relay protection device in the transformer substation;
s02, constructing a three-dimensional point cloud map of the transformer substation based on the point cloud data of the transformer substation;
s03, matching in the three-dimensional point cloud map based on the point cloud data of each relay protection device in the transformer substation to obtain point cloud position information of each relay protection device in the three-dimensional point cloud map;
s04, acquiring a global live-action image of the transformer substation, and acquiring live-action position information of each relay protection device in the global live-action image;
s05, comparing the three-dimensional point cloud map with the global live-action image to obtain a mapping relation between the point cloud position information and the live-action position information of each relay protection device, and distributing the same ID to the point cloud position information and the live-action position information with the mapping relation.
Preferably, step S2 specifically includes:
acquiring the internal temperature, the external temperature, the internal humidity and the external humidity of each relay protection device in the transformer substation;
correspondingly, step S3 specifically includes:
s301, if the internal temperature is lower than a preset minimum safe temperature, judging whether the external temperature is higher than the preset minimum safe temperature or higher than a preset first temperature threshold, wherein the preset first temperature threshold is the sum of the internal temperature and a preset temperature difference, if the external temperature is higher than the preset minimum safe temperature or higher than the preset first temperature threshold, calling a ventilation system to enable the internal temperature to be equal to the external temperature, and if the external temperature is lower than the preset minimum safe temperature, calling a heat source system to heat the internal temperature to a preset safe temperature range; if the external temperature is not higher than the preset minimum safe temperature or higher than a preset first temperature threshold, calling the heat source system to heat the internal temperature to be within a preset safe temperature range;
the preset safety temperature range is a temperature interval between the preset minimum safety temperature and the preset maximum safety temperature;
s302, if the internal temperature is higher than the preset maximum safe temperature, determining whether the external temperature is lower than the preset maximum safe temperature or lower than a preset second temperature threshold, wherein the second temperature threshold is the difference between the internal temperature and the preset temperature difference, if the external temperature is lower than the preset maximum safe temperature or lower than the preset second temperature threshold, calling the ventilation system to enable the internal temperature to be equal to the external temperature, and if the external temperature is higher than the preset maximum safe temperature, calling the heat source system to heat the internal temperature to the preset safe temperature range; if the external temperature is judged not to be below the preset maximum safe temperature or below a preset second temperature threshold, calling a cold source system to cool the internal temperature to be within a preset safe temperature range;
s303, if the internal humidity is greater than a preset maximum safe humidity, judging whether the external humidity is within a preset safe humidity range, if the external humidity is within the preset safe humidity range, judging whether the external humidity is below the preset maximum safe humidity or below a preset first humidity threshold value, wherein the preset first humidity threshold value is the difference between the internal humidity and a preset humidity difference, if the external humidity is below the preset maximum safe humidity or below the preset first humidity threshold value, calling the ventilation system to enable the internal humidity to be equal to the external humidity, and if the external humidity is greater than the preset maximum safe humidity, calling the drying system to dry the internal humidity to the preset safe humidity range;
the preset safe humidity range is a humidity interval between a preset minimum safe humidity and the preset maximum safe humidity;
s304, if when inside humidity is less than predetermined minimum safe humidity, judge whether outside humidity is at predetermined safe humidity scope, if outside humidity is at predetermined safe humidity scope, then judge whether outside humidity does more than predetermined minimum safe humidity or predetermine more than the second humidity threshold value, predetermine the second humidity threshold value and do inside humidity with predetermine the sum of humidity difference, if outside humidity is do more than predetermined minimum safe humidity or predetermine more than the second humidity threshold value, then call ventilation system makes inside humidity with outside humidity equals, works as outside humidity is less than predetermined minimum safe humidity, then calls humidification system will inside humidity humidification extremely in the predetermined safe humidity scope.
Preferably, the no-fault time parameter includes a predicted no-fault time and an actual no-fault time of the relay protection device;
the family fault-free time parameters comprise fault-free running time of relay protection equipment of the same model and fault-free running time of relay protection equipment of the same batch;
the correct action rate parameters comprise correct action rate parameters of the relay protection equipment, correct action rate parameters of the relay protection equipment with the same model and correct action rate parameters of the relay protection equipment in the same batch;
the insulation condition parameters comprise insulation data of each plug-in the relay protection equipment;
the data sampling parameters comprise analog quantity sampling and switching value sampling;
the communication parameters comprise communication conditions and related communication parameters thereof;
the channel test parameters comprise high-frequency channel test parameters and optical fiber channel test data;
the differential flow parameters comprise main transformer differential flow parameters, bus differential flow parameters and optical fiber longitudinal differential flow parameters.
Preferably, after step S6, the method includes:
s7, generating maintenance information according to fault information of the relay protection equipment in a fault state, and sending the maintenance information to a substation operation and maintenance center, wherein the fault information comprises position information of the relay protection equipment and an evaluation result of an influence factor parameter;
and S8, calling a rendering interface to perform color rendering on the relay protection equipment in the fault state in the digital twin scene map.
In a second aspect, the present invention provides a digital twin-based substation relay protection device status monitoring system, which is configured to execute the above-mentioned digital twin-based substation relay protection device status monitoring method, and includes: the system comprises a digital twin module, an operating environment acquisition module, an operating environment adjustment module, an influence factor acquisition module, an influence factor evaluation module and a fault positioning module;
the digital twinning module is used for constructing a digital twinning scene map of the transformer substation by utilizing a digital twinning technology based on a three-dimensional point cloud map of the transformer substation, and the digital twinning scene map comprises simulation position information of relay protection equipment in the transformer substation;
the operation environment acquisition module is used for acquiring operation environment data of each relay protection device in the transformer substation, wherein the operation environment data comprises temperature and humidity;
the operation environment adjusting module is used for comparing the operation environment data with a preset safe environment threshold value so as to judge whether the operation environment data is normal or not, and is also used for calling an environment regulating and controlling system to adjust the operation environment of the corresponding relay protection equipment when the operation environment data is judged to be abnormal so as to enable the operation environment data to be normal;
the system comprises an influence factor acquisition module, a data sampling module and a data processing module, wherein the influence factor acquisition module is used for acquiring influence factor parameters of each relay protection device, and the influence factor parameters comprise a fault-free time parameter, a family fault-free time parameter, a correct action rate parameter, an insulation condition parameter, a data sampling parameter, a communication parameter, a channel test parameter and a difference flow parameter;
the influence factor evaluation module is used for evaluating the influence factor parameters based on a preset state evaluation rule, judging whether the state of the relay protection equipment is normal according to an evaluation result, and acquiring real-scene position information of the corresponding relay protection equipment in the transformer substation if the state of the relay protection equipment is judged to be abnormal;
and the fault positioning module is used for matching corresponding simulation position information in the digital twin scene map according to the live-action position information and marking the simulation position information obtained by matching in the digital twin scene map so as to determine the position of the relay protection equipment in a fault state.
Preferably, the system further comprises a point cloud construction unit; the point cloud construction unit comprises an inspection robot, a point cloud map construction module, a point cloud matching module, an image acquisition module and a mapping determination module;
the inspection robot is provided with a laser radar and is used for inspecting the transformer substation and obtaining point cloud data of the transformer substation and point cloud data of each relay protection device in the transformer substation;
the point cloud map building module is used for building a three-dimensional point cloud map of the transformer substation based on the point cloud data of the transformer substation;
the point cloud matching module is used for matching in the three-dimensional point cloud map based on point cloud data of each relay protection device in the transformer substation to obtain point cloud position information of each relay protection device in the three-dimensional point cloud map;
the image acquisition module is used for acquiring a global live-action image of the transformer substation and also used for acquiring live-action position information of each relay protection device in the global live-action image;
the mapping determining module is used for comparing the three-dimensional point cloud map with the global live-action image to obtain a mapping relation between the point cloud position information and the live-action position information of each relay protection device, and is also used for allocating the same ID to the point cloud position information and the live-action position information with the mapping relation.
Preferably, the operating environment obtaining module is specifically configured to obtain an internal temperature, an external temperature, an internal humidity, and an external humidity of each relay protection device in the substation;
correspondingly, the operating environment adjusting module comprises a temperature comparison sub-module, a humidity comparison sub-module, a ventilation sub-module, a heat source sub-module, a cold source sub-module, a drying sub-module and a humidifying sub-module;
the temperature comparison submodule is used for carrying out numerical comparison on the internal temperature and the preset minimum safe temperature and the preset maximum safe temperature respectively; the temperature control device is also used for comparing the external temperature with the preset minimum safe temperature, the preset maximum safe temperature, the preset first temperature threshold and the preset second temperature threshold respectively; also for comparing the internal temperature and the external temperature values; the preset first temperature threshold is the sum of the internal temperature and a preset temperature difference, and the second temperature threshold is the difference between the internal temperature and the preset temperature difference;
the humidity comparison submodule is used for comparing the internal humidity with a preset minimum safe humidity and a preset maximum safe humidity respectively through humidity values; the humidity value comparison module is further used for comparing the external humidity with the preset minimum safe humidity, the preset maximum safe humidity, the preset first humidity threshold value and the preset second humidity threshold value respectively; also for numerically comparing said internal humidity with said external humidity; the preset first humidity threshold is the difference between the internal humidity and a preset humidity difference, and the second humidity threshold is the sum of the internal humidity and the preset humidity difference;
the ventilation sub-module is used for mutually ventilating the inside and the outside of the relay protection device, so that the inside temperature is equal to the outside temperature and/or the inside humidity is equal to the outside humidity;
the heat source submodule is used for heating the interior of the relay protection equipment so as to heat the interior temperature to a preset safe temperature range, and the preset safe temperature range is a temperature interval between the preset minimum safe temperature and a preset maximum safe temperature;
the cold source submodule is used for cooling the interior of the relay protection equipment so as to cool the interior temperature to a preset safe temperature range;
the drying submodule is used for drying the interior of the relay protection device so as to dry the interior humidity to a preset safe humidity range, and the preset safe humidity range is a humidity interval between the preset minimum safe humidity and the preset maximum safe humidity;
the humidifying submodule is used for humidifying the inside of the relay protection device, so that the inside humidity is humidified to a preset safe humidity range.
Preferably, the system further comprises: a sending module and a rendering module;
the sending module is used for generating maintenance information according to fault information of the relay protection equipment in a fault state and sending the maintenance information to a substation operation and maintenance center, wherein the fault information comprises position information of the relay protection equipment and an evaluation result of an influence factor parameter;
and the rendering module is used for calling a rendering interface to perform color rendering on the relay protection equipment in the fault state in the digital twin scene map.
According to the technical scheme, the invention has the following advantages:
according to the method, the digital twin scene map of the transformer substation is constructed by using the digital twin technology, so that when the relay protection equipment in a fault state is determined, the corresponding fault relay protection equipment can be visually positioned in the digital twin scene map, the problems that an existing two-dimensional logic view is shielded and cannot be visually embodied are solved, and the risk of misoperation of an operator during maintenance due to positioning deviation is reduced. Meanwhile, the operating environment of the relay protection equipment is controlled to ensure that the operating environment is normal, the adverse effect of the operating environment on the influencing factor parameters of the relay protection equipment is reduced, the actual reference value of each influencing factor is improved, and the accuracy of monitoring the state of the relay protection equipment is improved.
Drawings
Fig. 1 is a flowchart of a method for monitoring a state of a digital twin-based substation relay protection device according to an embodiment of the present application;
fig. 2 is a schematic structural diagram of a digital twin-based substation relay protection device state monitoring system according to an embodiment of the present application;
fig. 3 is a schematic structural diagram of a point cloud construction unit of a digital twin-based substation relay protection device state monitoring system according to an embodiment of the present application;
fig. 4 is a schematic structural diagram of a temperature and humidity adjusting device provided in an embodiment of the present application;
fig. 5 is a side view of a temperature and humidity adjustment device provided in an embodiment of the present application;
fig. 6 is another schematic structural diagram of a digital twin-based substation relay protection device state monitoring system according to an embodiment of the present application.
Detailed Description
In order to make the technical solutions of the present application better understood, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
The traditional maintenance of the relay protection equipment is generally carried out according to a fixed period, the maintenance of the relay protection equipment cannot be realized in a targeted and accurate mode, and the over-detection and the omission detection states occur. Therefore, it is necessary to improve the accuracy of monitoring the state of the relay protection device.
In the display process, because the existing monitoring map mainly uses a two-dimensional logic view, the problems of shielding and incapability of visually embodying exist, in the maintenance process, specific equipment needs to be positioned, and most of equipment is close to or even the same in appearance when viewed from the appearance of the equipment due to the fact that substation equipment is dense and close to each other, and the problem of misoperation of an operator during maintenance due to positioning deviation exists.
Furthermore, the operation environment mainly comprises temperature and humidity, the temperature is too high or too low, the operation of the relay protection equipment can be seriously damaged due to too humid work and environment, and the accuracy of monitoring the state of the relay protection equipment can be influenced.
Therefore, the invention provides a method for monitoring the state of a digital twin-based substation relay protection device, so as to solve the above problems, and for easy understanding, please refer to fig. 1, the invention provides a method for monitoring the state of a digital twin-based substation relay protection device, which comprises the following steps:
s1, constructing a digital twinning scene map of the transformer substation by utilizing a digital twinning technology based on the three-dimensional point cloud map of the transformer substation, wherein the digital twinning scene map comprises simulation position information of relay protection equipment in the transformer substation;
s2, obtaining operation environment data of each relay protection device in the transformer substation, wherein the operation environment data comprises temperature and humidity;
s3, comparing the operating environment data with a preset safe environment threshold value to judge whether the operating environment data is normal, and if not, calling an environment regulation and control system to regulate the operating environment of the corresponding relay protection equipment so as to enable the operating environment data to be normal;
s4, acquiring influence factor parameters of each relay protection device, wherein the influence factor parameters comprise a fault-free time parameter, a family fault-free time parameter, a correct action rate parameter, an insulation condition parameter, a data sampling parameter, a communication parameter, a channel test parameter and a difference flow parameter;
s5, evaluating the influence factor parameters based on a preset state evaluation rule, judging whether the state of the relay protection equipment is normal or not according to the evaluation result, and if the state of the relay protection equipment is judged to be abnormal, acquiring the real-scene position information of the corresponding relay protection equipment in the transformer substation;
and S6, matching corresponding simulation position information in the digital twin scene map according to the live-action position information, and marking the simulation position information in the digital twin scene map according to the matched simulation position information to determine the position of the relay protection device in the fault state, wherein the live-action position information and the simulation position information are in a mapping relation.
According to the method, the digital twin scene map of the transformer substation is constructed by using the digital twin technology, so that when the relay protection equipment in a fault state is determined, the corresponding fault relay protection equipment can be visually positioned in the digital twin scene map, the problems that an existing two-dimensional logic view is shielded and cannot be visually embodied are solved, and the risk of misoperation of an operator during maintenance due to positioning deviation is reduced. Meanwhile, the operating environment of the relay protection equipment is controlled to ensure that the operating environment is normal, the adverse effect of the operating environment on the influencing factor parameters of the relay protection equipment is reduced, the actual reference value of each influencing factor is improved, and the accuracy of monitoring the state of the relay protection equipment is improved.
The following is a detailed description of an embodiment of a digital twin-based substation relay protection device state monitoring method provided by the present invention.
S100, constructing a digital twinning scene map of the transformer substation by utilizing a digital twinning technology based on a three-dimensional point cloud map of the transformer substation, wherein the digital twinning scene map comprises simulation position information of relay protection equipment in the transformer substation;
before step S100, the method includes:
s01, polling the transformer substation by the polling robot carrying the laser radar to obtain point cloud data of the transformer substation and point cloud data of each relay protection device in the transformer substation;
s02, constructing a three-dimensional point cloud map of the transformer substation based on the point cloud data of the transformer substation;
s03, matching in a three-dimensional point cloud map based on point cloud data of each relay protection device in the transformer substation to obtain point cloud position information of each relay protection device in the three-dimensional point cloud map;
s04, acquiring a global live-action image of the transformer substation, and acquiring live-action position information of each relay protection device in the global live-action image;
it should be noted that the global live-action image of the substation may be acquired by using an unmanned aerial vehicle, so as to obtain the layout of the whole substation and the live-action position information of each relay protection device in the global live-action image.
And S05, comparing the three-dimensional point cloud map with the global live-action image to obtain the mapping relation between the point cloud position information and the live-action position information of each relay protection device, and distributing the same ID to the point cloud position information and the live-action position information with the mapping relation.
It can be stated that the three-dimensional point cloud map and the global live-action image are both obtained based on the same substation scene, and therefore, the three-dimensional point cloud map and the global live-action image are compared in a direct proportion, so as to obtain a mapping relationship between the point cloud position information and the live-action position information of the relay protection device, and meanwhile, the same ID is assigned to each pair of point cloud position information and live-action position information having the mapping relationship, so that the corresponding position can be conveniently searched subsequently. Meanwhile, different relay protection devices have different IDs.
S200, acquiring operation environment data of each relay protection device in the transformer substation, wherein the operation environment data comprises temperature and humidity;
in this embodiment, step S200 specifically includes: the internal temperature, the external temperature, the internal humidity and the external humidity of each relay protection device in the transformer substation are obtained.
The internal temperature and the internal humidity are main factors influencing the influencing factor parameters of the relay protection equipment.
S300, comparing the operating environment data with a preset safe environment threshold value to judge whether the operating environment data is normal or not, and if not, calling an environment regulation and control system to regulate the operating environment of the corresponding relay protection equipment so as to enable the operating environment data to be normal;
step S3 specifically includes:
s301, if the internal temperature is less than the preset minimum safe temperature, judging whether the external temperature is higher than the preset minimum safe temperature or higher than a preset first temperature threshold, wherein the preset first temperature threshold is the sum of the internal temperature and a preset temperature difference, if the external temperature is higher than the preset minimum safe temperature or higher than the preset first temperature threshold, calling a ventilation system to enable the internal temperature to be equal to the external temperature, and if the external temperature is lower than the preset minimum safe temperature, calling a heat source system to heat the internal temperature to a preset safe temperature range; if the external temperature is not above the preset minimum safe temperature or above the preset first temperature threshold, calling a heat source system to heat the internal temperature to the preset safe temperature range;
the preset safety temperature range is a temperature interval between a preset minimum safety temperature and a preset maximum safety temperature;
s302, if the internal temperature is higher than the preset maximum safe temperature, judging whether the external temperature is lower than the preset maximum safe temperature or lower than a preset second temperature threshold, wherein the second temperature threshold is the difference between the internal temperature and the preset temperature difference, if the external temperature is lower than the preset maximum safe temperature or lower than the preset second temperature threshold, calling a ventilation system to enable the internal temperature to be equal to the external temperature, and if the external temperature is higher than the preset maximum safe temperature, calling a heat source system to heat the internal temperature to a preset safe temperature range; if the external temperature is judged not to be below the preset maximum safe temperature or below the preset second temperature threshold, calling the cold source system to cool the internal temperature to be within the preset safe temperature range;
s303, if the internal humidity is larger than the preset maximum safe humidity, judging whether the external humidity is in a preset safe humidity range, if so, judging whether the external humidity is below the preset maximum safe humidity or below a preset first humidity threshold value, wherein the preset first humidity threshold value is the difference between the internal humidity and a preset humidity difference, if so, calling a ventilation system to enable the internal humidity to be equal to the external humidity, and calling a drying system to dry the internal humidity to be in the preset safe humidity range when the external humidity is larger than the preset maximum safe humidity;
the preset safe humidity range is a humidity interval between a preset minimum safe humidity and a preset maximum safe humidity;
s304, if the internal humidity is smaller than the preset minimum safe humidity, judging whether the external humidity is in a preset safe humidity range, if the external humidity is in the preset safe humidity range, judging whether the external humidity is higher than the preset minimum safe humidity or higher than a preset second humidity threshold value, wherein the preset second humidity threshold value is the sum of the internal humidity and a preset humidity difference, if the external humidity is higher than the preset minimum safe humidity or higher than the preset second humidity threshold value, calling a ventilation system to enable the internal humidity to be equal to the external humidity, and calling a humidification system to humidify the internal humidity to the preset safe humidity range when the external humidity is smaller than the preset minimum safe humidity.
It should be noted that the steps S301 to S304 can be switched according to actual situations.
In another embodiment, a low-temperature critical temperature range, a high-temperature critical temperature range, and a humidity critical range of the relay protection device are further set, and steps S301 to S304 are executed only when the temperature or the humidity is within the low-temperature critical temperature range, the high-temperature critical temperature range, and the humidity critical range and is maintained for a preset time. With cooperation safety range, when guaranteeing to reduce the operational environment influence, provide the protection to the temperature humidity control process, improve the holistic life of equipment.
S400, acquiring influence factor parameters of each relay protection device, wherein the influence factor parameters comprise a no-fault time parameter, a family no-fault time parameter, a correct action rate parameter, an insulation condition parameter, a data sampling parameter, a communication parameter, a channel test parameter and a difference flow parameter;
it should be noted that the non-fault time parameter includes the estimated non-fault time and the actual non-fault time of the relay protection device;
the family fault-free time parameters comprise fault-free running time of relay protection equipment of the same model and fault-free running time of relay protection equipment of the same batch;
the correct action rate parameters comprise correct action rate parameters of the relay protection equipment, correct action rate parameters of the relay protection equipment with the same model and correct action rate parameters of the relay protection equipment in the same batch;
the insulation condition parameters comprise insulation data of each plug-in the relay protection equipment;
the data sampling parameters comprise analog quantity sampling and switching value sampling;
the communication parameters comprise communication conditions and related communication parameters;
the channel test parameters comprise high-frequency channel test parameters and optical fiber channel test data;
the differential flow parameters comprise main transformer differential flow parameters, bus differential flow parameters and optical fiber longitudinal differential flow parameters.
S500, evaluating the influence factor parameters based on a preset state evaluation rule, judging whether the state of the relay protection equipment is normal or not according to an evaluation result, and if the state of the relay protection equipment is judged to be abnormal, acquiring the real-scene position information of the corresponding relay protection equipment in the transformer substation;
it can be understood that the factors affecting the state of the relay protection device include an operating environment, time without failure, familial time without failure, correct action rate, insulation condition, data sampling, communication condition, and channel test condition, and whether the state of the relay protection device is normal can be accurately evaluated by the impact factor parameters in this embodiment based on a predetermined scoring method and standard, if so, the monitoring is continued, and if not, the actual position of the faulty relay protection device is obtained.
S600, matching corresponding simulation position information in the digital twin scene map according to the live-action position information, and marking the simulation position information in the digital twin scene map according to the simulation position information obtained through matching to determine the position of the relay protection device in a fault state, wherein the live-action position information and the simulation position information are in a mapping relation.
It can be understood that the real-scene position information and the simulation position information are in a mapping relation, after the real-scene position information of the relay protection equipment in the transformer substation is obtained, corresponding simulation position information can be matched in a digital twin scene map according to the mapping relation, and the digital twin scene map is marked to determine the position of the relay protection equipment in a fault state, so that the problems that an existing two-dimensional logic view is shielded and cannot be visually embodied are solved, the problem that an operator performs misoperation during maintenance due to positioning deviation is solved, and the accuracy of monitoring the state of the relay protection equipment is improved.
S700, generating maintenance information according to fault information of the relay protection equipment in a fault state, and sending the maintenance information to a substation operation and maintenance center, wherein the fault information comprises position information of the relay protection equipment and an evaluation result of an influence factor parameter;
it should be noted that, when the fault relay protection device and the position thereof are determined, the maintenance information is generated according to the position information and the evaluation result of the influence factor parameter, and the relevant operation and maintenance personnel are notified to perform maintenance in time.
And S800, calling a rendering interface to perform color rendering on the relay protection equipment in the fault state in the digital twin scene map.
It should be noted that, in an embodiment, in order to distinguish different states of the relay protection device, such as normal state, failure state, shutdown state, and maintenance state, different states of the relay protection device are displayed according to different colors through the rendering interface, the relay protection device in the same state is displayed in the same color, and the relay protection devices in different states are displayed in different colors, so that operation and maintenance personnel can visually check the states.
The above is a detailed description of an embodiment of the method for monitoring the state of the digital twin-based substation relay protection device provided by the invention, and the following is a detailed description of an embodiment of the system for monitoring the state of the digital twin-based substation relay protection device provided by the invention.
For convenience of understanding, please refer to fig. 2, the present invention provides a digital twin-based substation relay protection device status monitoring system, which is configured to execute the digital twin-based substation relay protection device status monitoring method according to the foregoing embodiment, and includes: the system comprises a digital twin module 100, an operating environment acquisition module 200, an operating environment adjustment module 300, an influence factor acquisition module 400, an influence factor evaluation module 500 and a fault positioning module 600;
the digital twinning module 100 is used for constructing a digital twinning scene map of the transformer substation by using a digital twinning technology based on a three-dimensional point cloud map of the transformer substation, wherein the digital twinning scene map comprises simulation position information of relay protection equipment in the transformer substation;
the operation environment acquisition module 200 is configured to acquire operation environment data of each relay protection device in the substation, where the operation environment data includes temperature and humidity;
the operation environment adjusting module 300 is configured to compare the operation environment data with a preset safe environment threshold value, so as to determine whether the operation environment data is normal, and when the operation environment data is determined to be abnormal, invoke an environment regulating and controlling system to adjust the operation environment of the corresponding relay protection device, so as to restore the operation environment data to normal;
the influence factor acquisition module 400 is used for acquiring influence factor parameters of each relay protection device, wherein the influence factor parameters comprise a fault-free time parameter, a family fault-free time parameter, a correct action rate parameter, an insulation condition parameter, a data sampling parameter, a communication parameter, a channel test parameter and a difference flow parameter;
the influence factor evaluation module 500 is configured to evaluate an influence factor parameter based on a preset state evaluation rule, judge whether a state of the relay protection device is normal according to an evaluation result, and acquire real-scene position information of the corresponding relay protection device in the substation if the state of the relay protection device is judged to be abnormal;
and the fault positioning module 600 is configured to match corresponding simulation position information in the digital twin scene map according to the live-action position information, and further configured to mark the digital twin scene map according to the matched simulation position information to determine the position of the relay protection device in the fault state.
Further, referring to fig. 3, the system further includes a point cloud constructing unit 700; the point cloud construction unit 700 comprises an inspection robot 701, a point cloud map construction module 702, a point cloud matching module 703, an image acquisition module 704 and a mapping determination module 705;
the inspection robot 701 is provided with a laser radar for inspecting the transformer substation and obtaining point cloud data of the transformer substation and point cloud data of each relay protection device in the transformer substation;
the point cloud map building module 702 is used for building a three-dimensional point cloud map of the transformer substation based on the point cloud data of the transformer substation;
the point cloud matching module 703 is configured to match in a three-dimensional point cloud map based on point cloud data of each relay protection device in the substation to obtain point cloud position information of each relay protection device in the three-dimensional point cloud map;
the image acquisition module 704 is used for acquiring a global live-action image of the transformer substation and acquiring live-action position information of each relay protection device in the global live-action image;
the mapping determining module 705 is configured to compare the three-dimensional point cloud map with the global live-action image to obtain a mapping relationship between the point cloud location information and the live-action location information of each relay protection device, and is further configured to assign the same ID to the point cloud location information and the live-action location information having the mapping relationship.
Further, the operating environment obtaining module is specifically configured to obtain an internal temperature, an external temperature, an internal humidity, and an external humidity of each relay protection device in the substation;
correspondingly, the operating environment adjusting module comprises a temperature comparison submodule, a humidity comparison submodule, a ventilation submodule, a heat source submodule, a cold source submodule, a drying submodule and a humidifying submodule;
the temperature comparison submodule is used for comparing the internal temperature with a preset minimum safe temperature and a preset maximum safe temperature respectively; the temperature control device is also used for comparing the external temperature with a preset minimum safety temperature, a preset maximum safety temperature, a preset first temperature threshold value and a preset second temperature threshold value respectively; also used for comparing the internal temperature and the external temperature; the preset first temperature threshold is the sum of the internal temperature and the preset temperature difference, and the second temperature threshold is the difference between the internal temperature and the preset temperature difference;
the humidity comparison submodule is used for comparing the internal humidity with a preset minimum safe humidity and a preset maximum safe humidity respectively through humidity values; the humidity comparison module is also used for comparing the external humidity with a preset minimum safe humidity, a preset maximum safe humidity, a preset first humidity threshold value and a preset second humidity threshold value respectively; the device is also used for comparing the internal humidity with the external humidity; the preset first humidity threshold value is the difference between the internal humidity and the preset humidity difference, and the second humidity threshold value is the sum of the internal humidity and the preset humidity difference;
the ventilation sub-module is used for forming mutual ventilation between the inside and the outside of the relay protection device, so that the inside temperature is equal to the outside temperature and/or the inside humidity is equal to the outside humidity;
the heat source submodule is used for heating the interior of the relay protection equipment so as to heat the interior temperature to a preset safe temperature range, and the preset safe temperature range is a temperature interval between a preset minimum safe temperature and a preset maximum safe temperature;
the cold source submodule is used for cooling the interior of the relay protection equipment, so that the internal temperature is cooled to a preset safe temperature range;
the drying submodule is used for drying the interior of the relay protection equipment so as to dry the interior humidity to a preset safe humidity range, and the preset safe humidity range is a humidity interval between a preset minimum safe humidity and a preset maximum safe humidity;
the humidifying submodule is used for humidifying the interior of the relay protection device, so that the interior humidity is humidified to be within a preset safe humidity range.
It should be noted that, the operation environment adjustment module in this embodiment is used to execute steps S301 to S304 in the above embodiments, and the working processes are consistent, which is not described herein again.
Referring to fig. 4 to 5, a specific example of the temperature and humidity adjusting device for implementing the temperature and humidity adjusting process in the present system is shown below.
In this embodiment, a ventilation inlet and a ventilation outlet are penetratingly formed in a side wall of the relay protection device body 1, the ventilation inlet includes a plurality of forward air inlets 10 arranged in a matrix (the forward air inlets 10 include m rows × n rows arranged in a horizontal direction, and a distance between any two adjacent forward air inlets 10 in the horizontal direction is equal), and meanwhile, a temperature and humidity adjusting device is arranged on the relay protection device body 1, and the temperature and humidity adjusting device includes an adjusting box 2, an air suction box 3, a first telescopic motor 4, a guide cover 5, a drying plate 7, a second telescopic motor 8 and a fan 30;
the adjusting box 2 is arranged in the relay protection device body 1, a heat source, a cold source, a humidifier and a controller are arranged in the adjusting box 2, the controller is electrically connected with the heat source, the cold source and the humidifier respectively, the heat source is used for providing heat in the relay protection device body 1, the cold source is used for cooling the interior of the relay protection device body 1, the humidifier is used for humidifying the interior of the relay protection device body 1, lower adjusting holes 20 are arranged at the top end of the adjusting box 2 in a matrix arrangement mode, the lower adjusting holes 20 comprise k rows of multiplied p rows, the rows are arranged in the horizontal direction and are parallel to the rows of the front air inlets 10, concrete phases between any two adjacent lower adjusting holes 20 in the row direction of the lower adjusting holes 20 are equal, and the distance between any two adjacent front air inlets 10 in the horizontal direction is equal;
the air suction box 3 is arranged at the top end of the adjusting box 2 in a sliding way, and one side of the air suction box 3 close to the front air inlet 10, the air inlet is connected with one side of a front air inlet 10 arranged on the relay protection device body 1 in a sliding way, the distance between the bottom end of the air suction box 3 and the top end of the adjusting box 2, the distance between one side of the air suction box 3 close to the front air inlet 10 and one side of the relay protection device provided with the front air inlet 10 are set to be not influenced by relative sliding, the distance between the two is as small as possible, specifically 0.2-0.3mm, one side of the air suction box 3 far away from the front air inlet 10 is provided with a fan 30 for providing the wind direction, wherein, the top end of the air suction box 3 is provided with upper adjusting holes 31 matched with the lower adjusting holes 20 in a matrix arrangement, one side of the air suction box 3 close to the air inlet is penetrated with a rear air inlet matched with the front air inlet 10, and both sides of the adjusting box 2 in the sliding direction of the air suction box 3 are penetrated with a plurality of through holes 22;
the first telescopic motor 4 is fixedly connected to the corresponding side wall of the relay protection equipment body 1 and located on one side of the sliding direction of the air pumping box 3, the telescopic end of the first telescopic motor 4 is fixedly connected to the side wall of the air pumping box 3 to drive the air pumping box 3 to slide to a first position and a second position, wherein when the air pumping box 3 is located at the first position, the front air inlets 10 and the rear air inlets are in one-to-one correspondence and are communicated so that the air pumping box 3 is communicated with the outside, and the projection of the upper adjusting hole 31 on the horizontal plane is not intersected with the projection of the lower adjusting hole 20 on the horizontal plane so that the adjusting box 2 is isolated from the air pumping box 3; when the air pumping box 3 is located at the second position, the upper adjusting holes 31 are correspondingly communicated with the lower adjusting holes 20 one by one, so that the adjusting box 2 is communicated with the air pumping box 3, and the air pumping box 3 is not communicated with the outside through the rear air inlet;
the guide cover 5 is arranged on one side of the air extracting box 3 far away from the rear air inlet and covers the circumference of the fan 30, and the caliber of the guide cover 5 is reduced along the direction far away from the air extracting box 3;
the drying plate 7 comprises a shell 6 fixedly arranged at the opening end of the guide cover 5, the shell 6 is communicated with the guide cover 5, a filter screen is covered at the communication position to filter air, a through hole 60 communicated with the relay protection equipment is formed in one end, far away from the guide cover 5, of the shell 6, the bottom end of the shell 6 penetrates through a strip-shaped hole 61, the drying plate 7 is arranged in the strip-shaped hole 61 in a sliding mode, the drying plate 7 specifically comprises a frame body and a drying material arranged in the frame body, and the drying material can be fixed through the filter screen;
the second telescopic motor 8 is used for driving the drying plate 7 to slide, the output end of the second motor extends to drive the drying plate 7 to cover the opening end of the guide cover 5, specifically, the drying plate 7 divides the shell 6 into two spaces, the filter screen and the through hole 60 are respectively positioned in the two spaces, the output end of the second motor is shortened to open the opening end of the guide cover 5, and at the moment, air entering the shell 6 through the filter screen is directly led out through the through hole 60 without passing through the drying plate 7; the second telescopic motor 8 is fixed by a support plate 9 arranged on the air pumping box 3.
It can be understood that the one step replacement of ventilation accuse temperature and inner loop accuse temperature can be realized to the temperature humidity control device that this embodiment provided, when reducing the space and occuping, the quick synchro operation of being convenient for improves the control effect of temperature, through guide housing cooperation drying plate 7, and selectivity is dry in the air inlet, when humidity control, realizes the one step replacement of ventilation drying and inner loop drying.
Further, referring to fig. 6, the system further includes: a sending module 800 and a rendering module 900;
the sending module 800 is configured to generate maintenance information according to fault information of the relay protection device in a fault state, and is further configured to send the maintenance information to a substation operation and maintenance center, where the fault information includes position information of the relay protection device and an evaluation result of an influence factor parameter;
the rendering module 900 is configured to invoke a rendering interface to perform color rendering on the relay protection device in the fault state in the digital twin scene map.
In the embodiment, the digital twin scene map of the transformer substation is constructed by using the digital twin technology, so that when the relay protection equipment in a fault state is determined, the corresponding fault relay protection equipment can be visually positioned in the digital twin scene map, the problems that an existing two-dimensional logic view is shielded and cannot be visually embodied are solved, and the risk of misoperation of an operator during maintenance due to positioning deviation is reduced. Meanwhile, the operating environment of the relay protection equipment is controlled to ensure that the operating environment is normal, the adverse effect of the operating environment on the influencing factor parameters of the relay protection equipment is reduced, the actual reference value of each influencing factor is improved, and the accuracy of monitoring the state of the relay protection equipment is improved.
In the several embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, and for example, a division of a unit is merely a logical division, and an actual implementation may have another division, for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection through some interfaces, devices or units, and may be in an electrical, mechanical or other form.
Units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.
In addition, functional units in the embodiments of the present application may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit. The integrated unit can be realized in a form of hardware, and can also be realized in a form of a software functional unit.
The above embodiments are only used to illustrate the technical solutions of the present application, and not to limit the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions in the embodiments of the present application.
- 上一篇:石墨接头机器人自动装卡簧、装栓机
- 下一篇:战时航材需求预测方法