An artificial intelligence-based regulator for a pole-mounted transformer substation complete equipment

Abstract

The present application relates to the technical field of transformer voltage regulation, in particular to a pole-mounted transformer substation complete equipment regulator based on artificial intelligence, which comprises a regulator shell, a sealing shell installed on the back side of the regulator shell, and the bottom surface of the sealing shell is connected with the upper surface of the transformer shell, a display screen is installed on the front side of the regulator shell, a load tap changer is installed through the inside of the upper surface of the transformer shell, and the upper end of the load tap changer is connected with the regulation and control assembly inside the sealing shell. The pole-mounted transformer substation complete equipment regulator based on artificial intelligence tightly fits the sealing assembly and the outer side of the regulator shell to seal and cover the first air vent, so that the humidity in the external environment cannot enter the regulator shell, thereby protecting the electrical elements in the regulator shell and prolonging the service life of the entire regulator. The load tap changer is rotated by the motor to control the gear, thereby facilitating dynamic voltage regulation.

Description

Technical Field

[0001] This invention relates to the field of transformer voltage regulation technology, specifically to an artificial intelligence-based regulator for a complete set of equipment for pole-mounted transformer substations. Background Technology

[0002] The regulator of a pole-mounted transformer substation is a key component of the complete set of equipment. It is mainly used to adjust the output voltage of the transformer to ensure the stability and adaptability of the power supply. It is widely used in smart distribution systems to ensure the stability of the grid voltage, compensate for grid voltage fluctuations, ensure the stability of the user-end voltage, reduce energy loss, and thus ensure the safety of the smart grid industry. Currently, regulators on the market can be combined with artificial intelligence (AI) and energy storage technology. Excess grid-connected loads can be connected to the energy storage system to reduce grid pressure, improve grid stability, and reduce wind and solar power curtailment. Through the integrated energy storage system, peak shaving and valley filling can also be achieved to reduce electricity costs.

[0003] For example, the patent disclosed in the prior art with publication number "CN216250335U" is entitled "A Novel On-Load Tap Changing Structure for Transformers". It discloses that the center line of the plate-shaped structure is parallel to but not on the same straight line as the axis of the cylindrical structure. This is suitable for connecting paper-sheathed cables to a three-phase integrated on-load tap changer, effectively avoiding contact between the paper-sheathed cable and the connection wire of the three-phase integrated on-load tap changer itself. It also reduces the mechanical distance between the three-phase integrated on-load tap changer and the transformer tank and regulating windings. An on-load tap changer control box is provided next to the three-phase integrated on-load tap changer. The vertical and horizontal rotation axes of the on-load tap changer control box are respectively connected to the three-phase integrated on-load tap changer. The three-phase integrated on-load tap changer is controlled by manipulating the vertical and horizontal rotation axes of the on-load tap changer through the external control box. Another example is the prior art with publication number "CN2155". The patent disclosed in "78023U" is titled "Long-Life Transformer Voltage Regulator." It discloses an electric fan installed through the center of the lower surface of a movable plate, parallel to the transformer body. Several filter layers are installed inside the air outlets and inlets. Several air outlets are located through the center of both sides of the housing, and two air inlets are located through the center of one side of a triangular sealing plate. When the electric fans are operating, they blow cold air into the housing through the air inlets. The air entering the housing cools the transformer body before being discharged through the air outlets, creating a circulation. The airflow dissipates the heat generated by the transformer body during operation. Simultaneously, the filter layers inside the air inlets and outlets filter impurities and dust from the air, preventing them from entering the housing and damaging the cooling mechanism, transformer body, and voltage regulator. This better protects the device and significantly extends its service life.

[0004] The existing AI-based pole-mounted transformer substation equipment regulator has an issue where, during use, both the air inlet and outlet ports on the casing are open. In rainy weather, the humidity around the regulator is low, and external moisture can enter the regulator through these ports, causing damage to the electrical components and affecting its later use and operation. Therefore, we propose an AI-based pole-mounted transformer substation equipment regulator to address these problems. Summary of the Invention

[0005] The purpose of this invention is to provide an artificial intelligence-based regulator for pole-mounted transformer substation equipment, to solve the problem mentioned in the background art. Currently available artificial intelligence-based regulators for pole-mounted transformer substation equipment have open air inlets and outlets on the housing surface during use. In rainy weather, the humidity around the regulator is low, and external moisture can enter the regulator through the air inlets and outlets on the housing surface. This moisture can damage the electrical components inside the regulator, thus affecting its later use and preventing it from performing regulation operations effectively.

[0006] To achieve the above objectives, the present invention provides the following technical solution: an artificial intelligence-based pole-mounted transformer substation equipment regulator, comprising a regulator housing and a sealed housing installed on its rear side, wherein the bottom surface of the sealed housing is connected to the upper surface of the transformer housing, a display screen is installed on the front side of the regulator housing, an on-load tap changer is installed through the upper surface of the transformer housing, and the upper end of the on-load tap changer is connected to a control component inside the sealed housing, a mounting bracket is symmetrically installed on the bottom surface of the regulator housing, and a lifting control component is connected to the mounting bracket, wherein the left and right sides of the lifting control component are connected to a sealing cover plate through elastic connectors, and a sponge component is placed inside the upper part of the sealing cover plate.

[0007] Preferably, the regulator housing has a first vent groove on both the left and right sides.

[0008] Preferably, the control component includes a drive shaft installed inside a sealed housing, one end of which is connected to the upper end of an on-load tap changer via a bevel gear set. A motor is installed inside the upper part of the regulator housing, and the end of the drive shaft away from the on-load tap changer is connected to the output end of the motor via a coupling.

[0009] Preferably, the lifting control assembly includes a guide rod installed above the mounting bracket, and an abutment plate is installed through the outer side of the guide rod. A connecting spring is nested on the outer side of the upper end of the guide rod, and the surface of the "U"-shaped mounting bracket is provided with mounting holes.

[0010] Preferably, the elastic connector includes connecting frames installed on the left and right sides of the abutment plate, and a manual telescopic rod is installed above the connecting frames in an "L" shape. The upper end of the manual telescopic rod is connected to the bottom surface of the sealing cover plate, and a return spring is nested on the outer side of the upper end of the manual telescopic rod.

[0011] Preferably, the sealing cover is arranged in a "7" shape, and a sealing component is installed on the side of the sealing cover near the regulator housing. The sealing component is made of rubber and is in close contact with the side of the regulator housing. A second vent groove is opened in the vertical surface of the sealing cover and the inside of the sealing component. A third vent groove is opened in the horizontal surface of the sealing cover. A copper heat-conducting sheet is installed through the vertical surface of the sealing cover. One side of the heat-conducting sheet is in close contact with the sponge component, and the other side of the heat-conducting sheet is in close contact with the inside of the sealing component. The distance between the other side of the heat-conducting sheet and the side of the regulator housing is 2 cm.

[0012] Preferably, the sealing cover plate forms a lifting structure via a manually telescopic rod.

[0013] Preferably, a rotating rod is rotatably mounted on the upper surface of the regulator housing, and a wind, light and rain sensor is fixedly fixed through the outer side of the rotating rod. A wind speed sensor is mounted on the upper surface of the end of the wind, light and rain sensor away from the rotating rod, and a light sensor is mounted on the lower surface of the end of the wind, light and rain sensor away from the rotating rod. A rain sensor is mounted on the upper surface of the wind, light and rain sensor.

[0014] Preferably, a rack and pinion assembly is mounted on the rear side of the abutment plate.

[0015] Preferably, a protective shell is fixed to the rear side of the regulator housing, and the rear end of the rotating rod passes through the interior of the protective shell. A transmission gear is keyed to the outer side of the rotating rod located inside the protective shell, and the upper end of the rack assembly is inserted into the protective shell and meshes with the transmission gear on the left side.

[0016] Compared with the prior art, the beneficial effects of this invention are as follows: This artificial intelligence-based pole-mounted transformer substation equipment regulator seals and covers the first vent groove by tightly fitting the sealing component to the outer surface of the regulator housing, preventing external moisture from entering the regulator housing. This effectively protects the electrical components inside the regulator housing, improving the overall service life of the regulator. The on-load tap changer is rotated by a motor to control the tap position, facilitating dynamic voltage adjustment. This allows for dynamic adjustment of grid parameters to cope with fluctuations in renewable energy sources. The specific details are as follows:

[0017] (1) When encountering heavy rain, the sponge component absorbs a certain amount of rainwater and its gravity increases. Therefore, the sponge component automatically moves the sealing cover downward, which causes the second venting groove to be staggered with the first venting groove. Thus, the first venting groove is sealed and covered by the tight fit between the sealing component and the outer side of the regulator housing, preventing external moisture from entering the regulator housing. This effectively protects the electrical components inside the regulator housing and improves the service life of the entire regulator.

[0018] Furthermore, when the entire regulator is not installed and in use, the first vent slot can be sealed and covered by the cooperation of the sealing cover plate and the sealing component, which can prevent external moisture and impurities from entering the regulator housing. Therefore, the electrical components inside the regulator housing can be further protected, which facilitates the subsequent regulation operation, ensures the stable operation of the intelligent power distribution system, and ensures the safety of the smart grid industry.

[0019] (2) The heat conduction sheet made of copper can conduct heat from the surface of the regulator housing to the periphery of the sponge assembly. At the same time, the outside wind can blow to the sponge assembly through the third ventilation groove, and the outside sunlight can irradiate the sponge assembly to remove the moisture inside the sponge assembly. This makes it easier to automatically move the sealing cover plate upward and reset it later by the storage force of the reset spring, so that the second ventilation groove coincides with the first ventilation groove, thus avoiding affecting the ventilation and heat dissipation inside the regulator housing.

[0020] (3) When the regulator is installed and used, the abutment plate drives the rack assembly to rise, and the rack assembly drives the transmission gear and the rotating rod to rotate. This causes the rotating rod to rotate the wind, light and rain sensor to a vertical position, so that the wind speed sensor, rain sensor and light sensor in the wind, light and rain sensor can monitor the wind force, light intensity and rainfall in the natural environment. The voltage sensor and current sensor installed in the transformer can monitor the voltage and current in the power grid. Then, the motor drives the on-load tap changer to rotate, thereby controlling the gear and facilitating dynamic voltage adjustment. Attached Figure Description

[0021] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0022] Figure 2 For the present invention Figure 1 Enlarged structural diagram at point A in the middle;

[0023] Figure 3 This is a schematic diagram of the rear view structure of the present invention;

[0024] Figure 4 This is a top sectional view of the connection between the regulator housing and the sealing housing of the present invention;

[0025] Figure 5 This is a schematic diagram of the separation structure of the regulator housing and the sealing cover plate of the present invention;

[0026] Figure 6 This is a schematic diagram of the three-dimensional structure of the sealing cover plate of the present invention;

[0027] Figure 7 This is a schematic diagram of the sealing assembly structure of the present invention;

[0028] Figure 8 This is a schematic diagram of the separation structure of the sealing cover and the sealing assembly of the present invention;

[0029] Figure 9 This is a schematic cross-sectional view of the protective shell structure of the present invention;

[0030] Figure 10 This is a schematic diagram of the three-dimensional structure of the wind, light and rain sensor of the present invention after rotation.

[0031] In the diagram: 1. Regulator housing; 101. First vent slot; 2. Sealing housing; 3. Transformer housing; 4. Display screen; 5. Mounting bracket; 51. Mounting hole; 52. Guide rod; 53. Connecting spring; 6. Abutment plate; 7. Connecting frame; 8. Manual telescopic rod; 81. Return spring; 9. Sealing cover plate; 91. Second vent slot; 92. Third vent slot; 93. Sealing assembly; 94. Heat-conducting sheet; 10. Sponge assembly; 11. Wind, light, and rain sensor; 111. Wind speed sensor; 112. Rain sensor; 113. Light sensor; 12. Protective housing; 13. Rack assembly; 14. On-load tap changer; 15. Motor; 16. Drive shaft; 17. Rotating rod; 171. Transmission gear. Detailed Implementation

[0032] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0033] Please see Figures 1-10 The present invention provides the following technical solution:

[0034] Example 1: The AI-based pole-mounted transformer substation equipment regulator in this example can automatically prevent external moisture from entering the regulator housing 1 during heavy rain. This facilitates the protection of electrical components inside the regulator housing 1 and improves the overall service life of the regulator. See attached diagram for the specific structure. Figures 1-7 As shown, the device includes a regulator housing 1 and a sealed housing 2 installed on its rear side. The bottom surface of the sealed housing 2 is connected to the upper surface of the transformer housing 3. A display screen 4 is installed on the front side of the regulator housing 1. An on-load tap changer 14 is installed through the upper surface of the transformer housing 3. The upper end of the on-load tap changer 14 is connected to the control component inside the sealed housing 2. A mounting bracket 5 is symmetrically installed on the bottom surface of the regulator housing 1. A lifting control component is connected to the mounting bracket 5. The left and right sides of the lifting control component are connected to the sealing cover plate 9 through elastic connectors. A sponge component 10 is placed inside the upper part of the sealing cover plate 9. A first ventilation groove 101 is opened on both the left and right sides of the regulator housing 1.

[0035] The control assembly includes a drive shaft 16 installed inside the sealed housing 2, with one end of the drive shaft 16 connected to the upper end of the on-load tap changer 14 via a bevel gear set. A motor 15 is installed inside the upper part of the regulator housing 1, and the end of the drive shaft 16 away from the on-load tap changer 14 is connected to the output end of the motor 15 via a coupling. The lifting control assembly includes a guide rod 52 installed above the mounting bracket 5, with an abutment plate 6 installed through the outer side of the guide rod 52. A connecting spring 53 is nested on the outer side of the upper end of the guide rod 52. The surface of the "U"-shaped mounting bracket 5 has mounting holes 51. The elastic connector includes connecting frames 7 installed on the left and right sides of the abutment plate 6, with a manual telescopic rod 8 installed above the "L"-shaped connecting frame 7. The upper end of the manual telescopic rod 8 is connected to the bottom surface of the sealing cover plate 9. Furthermore, a return spring 81 is nested on the outer side of the upper end of the manual telescopic rod 8. The sealing cover 9 is arranged in a "7" shape, and a sealing component 93 is installed on the side of the sealing cover 9 near the regulator housing 1. The sealing component 93, made of rubber, is in close contact with the side of the regulator housing 1. A second venting groove 91 is opened inside the vertical surface of the sealing cover 9 and inside the sealing component 93. A third venting groove 92 is opened inside the horizontal surface of the sealing cover 9. The sealing cover 9 forms a lifting structure through the manual telescopic rod 8. A copper heat-conducting plate 94 is installed through the vertical surface of the sealing cover 9. One side of the heat-conducting plate 94 is in close contact with the sponge component 10, and the other side of the heat-conducting plate 94 penetrates the interior of the sealing component 93. The distance between the other side of the heat-conducting plate 94 and the side of the regulator housing 1 is 2 cm.

[0036] Move the entire regulator to the working area, and then place the bottom of the regulator on the installation area. At this time, connect the sealing shell 2 to the upper part of the transformer shell 3 with sealing screws. This makes the bevel gear on the outside of the drive shaft 16 mesh with the bevel gear on the upper part of the on-load tap changer 14. At the same time, the external installation area will apply an upward thrust to the abutment plate 6, causing the abutment plate 6 to move upward automatically. The abutment plate 6 moves upward on the outside of the guide rod 52, while compressing and storing force on the connecting spring 53. Then, use external screws to pass through the mounting hole 51 and connect to the installation area, so that the entire regulator can be stably installed in the installation area for use. When the abutment plate 6 moves upward, it drives the sealing cover plate 9 to move upward to a certain position through the connecting frame 7 and the manual telescopic rod 8. At this time, the second vent groove 91 opened in the sealing cover plate 9 and the sealing assembly 93 coincides with the first vent groove 101 opened on the side of the regulator shell 1. Then, when the regulator is in use, it can be ventilated and cooled through the overlapping first vent groove 101 and second vent groove 91.

[0037] Simultaneously, the abutment plate 6 drives the rack assembly 13 to move upwards. As the rack assembly 13 moves upwards, it drives the transmission gear 171 and the rotating rod 17 to rotate 90°, causing the rotating rod 17 to rotate the wind, light, and rain sensor 11 90° to a vertical position. The entire regulator is then ready for use. During operation, voltage and current sensors installed inside the transformer monitor the voltage and current in the power grid. When voltage regulation of the transformer is required, the voltage sensor transmits this signal to the central processing module. The central processing module then controls the motor 15 to start. The motor 15 drives the drive shaft 16 to rotate, and the drive shaft 16 drives the on-load tap changer 14 to rotate through the outer bevel gear set. This controls the tap position, compensates for line voltage drop, ensures stable voltage at the user end, thereby improving the efficiency of power transmission and use and reducing energy loss. Simultaneously, when the regulator is in use, it monitors wind speed, light intensity, and rainfall in the natural environment through the wind speed sensor 111, rainfall sensor 112, and light sensor 113 within the wind, light, and rain sensors 11. When strong winds or strong light intensity are detected, the external renewable energy generation... When the power generation is high, the load sent from renewable energy generation to the grid becomes too large, causing damage to equipment in the power system. The wind, solar and rain sensors 11 then transmit this signal to the central processing module installed in the regulator housing 1. The central processing module controls the motor 15 to start, and the motor 15 drives the drive shaft 16 to rotate. The drive shaft 16 drives the on-load tap changer 14 to rotate through the outer bevel gear set, thereby controlling the tap position, suppressing voltage fluctuations, and facilitating dynamic voltage regulation. By dynamically adjusting the grid parameters to cope with renewable energy fluctuations, the stable operation of the smart distribution system is ensured, and the safety of the smart grid industry is guaranteed. Since this part is existing technology, it will not be described in detail here. (At the same time, when the power generation is high, the regulator can also be used in conjunction with components such as bidirectional converters to realize bidirectional energy flow between the grid and the energy storage system. Excess grid-connected loads can be connected to the energy storage system, automatically switching to the energy storage charging mode, reducing grid pressure, improving grid stability, and reducing wind and solar curtailment. Through the integrated energy storage system, peak shaving and valley filling can also be achieved, reducing electricity costs. Since this part is existing technology, it will not be described in detail here.)

[0038] When the regulator is in use during heavy rain, a certain amount of rainwater comes into contact with the sponge component 10. After absorbing the rainwater, the sponge component 10's own weight increases. Then, the water-absorbing sponge component 10 automatically moves the sealing cover 9 and the sealing component 93 downwards. At this time, the sealing cover 9 applies a certain pressure to the manual telescopic rod 8, causing the manual telescopic rod 8 to retract. The return spring 81 is compressed and stored. This causes the second vent groove 91 in the sealing cover 9 and the sealing component 93 to be staggered with the first vent groove 101 without overlapping. Then, the sealing component 93 is in close contact with the outer side of the regulator housing 1, thus effectively sealing and covering the first vent groove 101, preventing external moisture from entering the regulator housing 1, and protecting the electrical components inside the regulator housing 1. At this time, because the rainwater drips onto the surface of the regulator housing 1, it can help dissipate heat and cool down the inside of the regulator housing 1, preventing the temperature inside the regulator housing 1 from being too high. When the rain stops, the external... Air can be blown onto the sponge assembly 10 through the third vent 92, and heat inside the regulator housing 1 can be conducted to the heat-conducting plate 94. The heat-conducting plate 94 conducts heat to the periphery of the sponge assembly 10. Then, the sponge assembly 10 is irradiated by sunlight, which can quickly remove the moisture inside the sponge assembly 10. When the moisture inside the sponge assembly 10 is removed, its own weight decreases. At this time, the manual telescopic rod 8 is automatically pulled back to its original position by the stored force of the return spring 81. The manual telescopic rod 8 drives the sealing cover 9 to move upward and reset. At this time, the second vent 91 opened in the sealing cover 9 and the sealing assembly 93 overlaps with the first vent 101. Then, the outside air can enter the regulator housing 1 through the overlapped second vent 91 and first vent 101 for ventilation and heat dissipation. At the same time, a filter plate can be installed in the second vent 91 opened in the sealing cover 9 to prevent external impurities from entering the regulator housing 1. Therefore, the electrical components inside the regulator housing 1 can be well protected.

[0039] Example 2: The AI-based pole-mounted transformer substation equipment regulator in this example, based on Example 1, also prevents external moisture and impurities from entering the regulator housing 1 when not installed or in use. See attached diagram for the specific structure. Figure 1 and Figure 9As shown, a rotating rod 17 is rotatably mounted on the upper surface of the regulator housing 1, and a wind, light and rain sensor 11 is fixed through the outer side of the rotating rod 17. A wind speed sensor 111 is mounted on the upper surface of the end of the wind, light and rain sensor 11 away from the rotating rod 17, and a light sensor 113 is mounted on the lower surface of the end of the wind, light and rain sensor 11 away from the rotating rod 17. A rain sensor 112 is mounted on the upper surface of the wind, light and rain sensor 11. A rack assembly 13 is mounted on the rear side of the abutment plate 6. A protective housing 12 is fixed on the rear side of the regulator housing 1, and the rear end of the rotating rod 17 passes through the interior of the protective housing 12. A transmission gear 171 is keyed to the outer side of the rotating rod 17 located inside the protective housing 12. The upper end of the rack assembly 13 is inserted into the protective housing 12 and meshes with the transmission gear 171 on the left side.

[0040] When the entire regulator is not installed or used, the second vent groove 91 opened in the sealing cover plate 9 and the sealing assembly 93 is staggered with the first vent groove 101 without overlapping. Therefore, the sealing assembly 93 is in close contact with the outer side of the regulator housing 1, which facilitates the sealing and covering of the first vent groove 101, preventing external moisture from entering the regulator housing 1. This makes it easier to transport and store the regulator in rainy weather. At the same time, when the regulator is not installed or used, the wind, light and rain sensor 11 is placed horizontally, which avoids the wind, light and rain sensor 11 occupying a large area due to its vertical placement, further facilitating the transport and storage of the regulator, thus completing a series of tasks.

[0041] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.

Claims

1. A regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence, comprising a regulator housing (1) and a sealed housing (2) installed on its rear side, wherein the bottom surface of the sealed housing (2) is connected to the upper surface of the transformer housing (3), and a display screen (4) is installed on the front side of the regulator housing (1), characterized in that: An on-load tap changer (14) is installed through the upper surface of the transformer housing (3), and the upper end of the on-load tap changer (14) is connected to the control component inside the sealed housing (2). A mounting bracket (5) is symmetrically installed on the bottom surface of the regulator housing (1), and a lifting control component is connected to the mounting bracket (5). The left and right sides of the lifting control component are connected to the sealing cover plate (9) through elastic connectors. A sponge component (10) is placed inside the upper part of the sealing cover plate (9).

2. The regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence as described in claim 1, characterized in that: The regulator housing (1) has a first ventilation slot (101) on both the left and right sides.

3. The regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence as described in claim 1, characterized in that: The control assembly includes a drive shaft (16) installed inside a sealed housing (2), and one end of the drive shaft (16) is connected to the upper end of an on-load tap changer (14) via a bevel gear set. A motor (15) is installed inside the upper part of the regulator housing (1), and the end of the drive shaft (16) away from the on-load tap changer (14) is connected to the output end of the motor (15) via a coupling.

4. The regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence as described in claim 1, characterized in that: The lifting control assembly includes a guide rod (52) installed above the mounting bracket (5), and an abutment plate (6) is installed through the outer side of the guide rod (52), and a connecting spring (53) is nested on the outer side of the upper end of the guide rod (52). The surface of the "U"-shaped mounting bracket (5) is provided with mounting holes (51).

5. A regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence as described in claim 4, characterized in that: The elastic connector includes a connecting frame (7) installed on the left and right sides of the abutment plate (6), and a manual telescopic rod (8) is installed above the "L"-shaped connecting frame (7). The upper end of the manual telescopic rod (8) is connected to the bottom surface of the sealing cover plate (9), and a return spring (81) is nested on the outer side of the upper end of the manual telescopic rod (8).

6. The regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence according to claim 1, characterized in that: The sealing cover (9) is arranged in a "7" shape, and a sealing component (93) is installed on the side of the sealing cover (9) near the regulator housing (1). The sealing component (93) is made of rubber and is in close contact with the side of the regulator housing (1). A second venting groove (91) is provided inside the vertical surface of the sealing cover (9) and inside the sealing component (93). A third venting groove (92) is provided inside the horizontal surface of the sealing cover (9). A copper heat-conducting sheet (94) is installed through the vertical surface of the sealing cover (9). One side of the heat-conducting sheet (94) is in close contact with the sponge component (10), and the other side of the heat-conducting sheet (94) penetrates the interior of the sealing component (93). The distance between the other side of the heat-conducting sheet (94) and the side of the regulator housing (1) is 2 cm.

7. A regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence, as described in claim 5, characterized in that: The sealing cover (9) forms a lifting structure via a manual telescopic rod (8).

8. A regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence, as described in claim 4, characterized in that: A rotating rod (17) is rotatably mounted on the upper surface of the regulator housing (1), and a wind, light and rain sensor (11) is fixed through the outer side of the rotating rod (17). A wind speed sensor (111) is mounted on the upper surface of the end of the wind, light and rain sensor (11) away from the rotating rod (17), and a light sensor (113) is mounted on the lower surface of the end of the wind, light and rain sensor (11) away from the rotating rod (17). A rain sensor (112) is mounted on the upper surface of the wind, light and rain sensor (11).

9. A regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence as described in claim 8, characterized in that: A rack assembly (13) is mounted on the rear side of the abutment plate (6).

10. A regulator for a complete set of equipment for a pole-mounted transformer substation based on artificial intelligence, as described in claim 9, characterized in that: The rear side of the regulator housing (1) is fixed with a protective housing (12), and the rear end of the rotating rod (17) passes through the interior of the protective housing (12). The outer side of the rotating rod (17) located inside the protective housing (12) is keyed with a transmission gear (171). The upper end of the rack assembly (13) is inserted into the protective housing (12) and meshes with the transmission gear (171) on the left side.

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