CN114759457A - Transformer substation for electric energy storage system and detection system thereof - Google Patents

Abstract

The invention provides a transformer substation for an electric energy storage system and a detection system thereof, and the transformer substation comprises a transformer substation box body, a moisture-proof base and a solar cell panel, wherein a plurality of detection components which are arranged in an upper vertical direction and an lower vertical direction in an equal-adjacent and separated mode and can detect the entry of rainwater are embedded in the inner position of the longitudinal inner wall of the transformer substation box body, and prompt components which can prompt maintenance personnel to maintain are also embedded in the inner position of the longitudinal inner wall of the transformer substation box body; each group of detection components comprises a shell, an inclined plate, a movable component capable of automatically moving after rainwater enters, a pipeline and a water absorption component capable of absorbing rainwater. The transformer substation for the electric energy storage system and the detection system thereof can play a role in enabling the transformer substation to detect whether rainwater enters the transformer substation box body or not in time and inform maintenance personnel to carry out corresponding maintenance work in time when the transformer substation runs into rainy and snowy weather in the process of electric energy storage.

Description

Transformer substation for electric energy storage system and detection system thereof

Technical Field

The invention relates to the technical field of power systems, in particular to a transformer substation for an electric energy storage system and a detection system thereof.

Background

At present, the box-type substation installed outdoors only dispels the heat by the heat dissipation hole, and this kind of radiating mode is not good, and the transformer substation often receives the weather when outdoor use, the erosion of rainwater in addition, has reduced the life of transformer substation's box like this to do not set up rainwater collection device in the open air, cause the waste of certain resource like this, it is very inconvenient to use.

Aiming at the problems, regarding the technical problems of poor heat dissipation, short service life and the like of a transformer substation, through a large number of searches, an outdoor corrosion-resistant box-type transformer substation with the patent number of CN202020467047.X is inquired, and belongs to the technical field of box-type transformer substations, the outdoor corrosion-resistant box-type transformer substation comprises a transformer substation box body, wherein a water collecting tank is fixedly arranged on two sides of the outer wall surface of the transformer substation box body through bolts, a water pipe is fixedly arranged on one side of the bottom end surface of the water collecting tank, and water storage tanks are fixedly arranged on two sides of the outer wall surface of the transformer substation box body; the rainwater is collected by utilizing the functions of the water guide groove, the water collecting groove and the water storage tank, so that resources are saved; the solar energy is converted into electric energy to be stored in the storage battery pack by utilizing the action of the solar photovoltaic panel, so that the electric energy is provided; when the transformer substation is used, the water pump is used for pumping the water storage tank condenser pipe into the condenser pipe, and the combined action of the heat dissipation fan is utilized, so that the transformer substation is better cooled; by arranging the anti-oxidation layer, the anti-corrosion layer and the anti-weathering layer, the service life of the transformer substation box body can be prolonged.

However, the technical scheme that this patent provided is to the transformer substation at electric energy storage's in-process, when meetting sleet weather, can not in time detect the rainwater and whether get into to the transformer substation box in, and maintenance personal often causes the just perception in damage rear to the electrical equipment in it after the rainwater gets into the transformer substation box.

Disclosure of Invention

The present invention is directed to solve the technical problems of the background art, and provides a substation for an electric energy storage system and a detection system thereof.

In order to achieve the purpose, the invention provides the following technical scheme: a transformer substation for an electric energy storage system comprises a transformer substation box body, a damp-proof base and a solar cell panel, wherein a plurality of detection components which are arranged in an upper vertical direction and a lower vertical direction in an equal-adjacent and separated mode and can detect rainwater entering are embedded in the inner position of the longitudinal inner wall of the transformer substation box body, and prompt components which can prompt maintenance personnel to maintain are also embedded in the inner position of the longitudinal inner wall of the transformer substation box body;

each group of detection components comprises a shell, an inclined plate, a movable component capable of automatically moving after rainwater enters, a pipeline and a water absorption component capable of absorbing rainwater.

Further preferred embodiments: every the outward appearance of casing all is inside hollow hemisphere form, every the left end top position of casing has all seted up the entry, every the left end upper portion of casing all in entry position slant fixed mounting has the swash plate, every the tail end of swash plate all extends to the inside middle-end right position of casing, every the swash plate is 45, every with the inclination of horizontal plane casing and swash plate all have magnetism, every the equal movable mounting in inside middle-end position of casing has movable subassembly, every the equal slant of right-hand member lower part position of casing is to running through and installing the pipeline, every the inclination of pipeline and horizontal plane is 45, every the equal fixed mounting in inside bottom position of casing has the subassembly that absorbs water.

Further preferred embodiments: each group of movable components comprises a rotating shaft and a movable plate.

Further preferred embodiments: every the pivot all is the rotation of horizontal direction around installing in every the inner wall middle-end left part position of casing, every the right side surface of pivot all encircles fixed mounting has a fly leaf, every the right-hand member afterbody of fly leaf all extends to every the inner wall right-hand member position of casing, every the fly leaf all has with every the magnetism different with casing and swash plate, every the fly leaf all is because of with every under normal conditions shells inner wall and every the swash plate magnetism is inhaled and is in the static balanced state of level.

Further preferred embodiments: each water absorption component comprises an air bag, activated carbon powder and a conduit.

Further preferred embodiments: the bottom end of the inner wall of each shell is fixedly provided with an air bag, the appearance of each air bag is fan-shaped on a longitudinal section, the outer surfaces of the left side and the right side of each air bag are fixedly attached to the inner wall of the shell, activated carbon powder is pre-installed in the inner position of each air bag, a conduit is obliquely installed at the lower position of the right end of each air bag in a penetrating mode, each conduit penetrates through the lower position of the right end of each shell, and the inclination angle between each conduit and the horizontal plane is 30 degrees.

Further preferred embodiments: the inside head end position of every pipe all movable mounting has the accuse material subassembly that can control the material that absorbs water and come in and out, every group accuse material subassembly all includes 2 bull sticks, 2 baffles and 2 supporting shoes.

Further preferred embodiments: every 2 the bull stick all is that the fore-and-aft horizontal direction is rotatory respectively and installs in every two positions about the inner wall head end of pipe, every 2 the relative one side surface of bull stick all encircles and installs the baffle, every 2 the baffle all is in the magnetism of each other and seals every under normal conditions the state of pipe head end entry, every two positions are equallyd divide and are not in being close to every about the inner wall head end of pipe the near fixed mounting in baffle head end position has the supporting shoe, every the material of supporting shoe is rubber.

Further preferred embodiments: each group of the prompt component comprises a slide rail, a plurality of slide grooves and an alarm component capable of giving an alarm.

Further preferred embodiments: every the slide rail all is vertical direction fixed mounting in the vertical inner wall internal position of transformer substation box, every the equal slidable mounting in internal position of slide rail has a plurality of spout, the total amount of spout with detecting element's total amount equals, every slide rail and spout all have the magnetism that is different each other, every the tail end of pipeline and pipe all runs through extremely in the slide rail, every the initial position of spout all is located every the inside of slide rail is close to every the position of pipe tail end, every the spout all is because of with every under the normal condition slide rail magnetism is inhaled and is static balance state attached to every the inner wall of slide rail is close to every the position of pipe tail end.

Further preferred embodiments: each group of alarm components comprises a wireless alarm, an alarm button and a movable plate.

Further preferred embodiments: every the equal fixed mounting of wireless alarm in every vertical inner wall bottom position of transformer substation's box, every the equal fixed mounting in inside bottom position of slide rail has alarm button, every alarm button all with rather than adjacent every wireless alarm electric connection, every alarm button all in every directly over the position the inner wall slidable mounting of slide rail has a movable plate, every the outward appearance of movable plate all is the shape of falling letter T on a longitudinal section, every the movable plate all has with every the different magnetism of slide rail, every the movable plate all is because of with every under the normal condition the slide rail magnetism is inhaled and is static balanced state attached to every the inner wall of slide rail and is located every the bottom position in the slide rail the position under the spout.

A sensing system for an electrical energy storage system, the system comprising the steps of:

s1: the solar panel converts solar energy into electric energy and stores the electric energy in the transformer substation;

s2: the detection assembly detects whether rainwater enters the transformer substation box body in real time, if so, the transformer substation box body enters S3, and if not, the detection assembly continues to the S1;

S3: rainwater slides downwards through the inner wall of the transformer substation box body and enters the shell of the detection assembly;

s4: triggering the movable component of the detection component to move;

s5: rainwater is guided into the sliding groove of the prompting component through the pipeline of the detection component, and meanwhile, the water absorption component of the detection component is pressed to guide water absorption materials in the water absorption component into the sliding groove;

s6: after the water absorption materials absorb rainwater, the sliding groove is weighted, so that the sliding groove slides downwards in the sliding rail of the prompt component, and finally the alarm component is triggered to alarm and maintain.

Has the advantages that:

1. the substation for the electric energy storage system is provided with a detection component and a prompt component, utilizes a lever, a negative pressure principle and dynamic change between gravity and suction, when the substation is in rainy and snowy weather in the process of converting solar energy into electric energy for storage, rainwater flows down through gaps of a box body of the substation and slides into the shell from an inclined plate at an inlet of the shell of the detection component, a movable component of the detection component moves under the action of the lever principle, then the rainwater is guided into a water absorption component through a pipeline of the detection component for collection, the movable component triggers the water absorption component of the detection component to release water absorption materials into the prompt component through the negative pressure principle in the moving process, the water absorption materials trigger the prompt component to give an alarm through the dynamic change between gravity and magnetic force after absorbing the rainwater in the prompt component, the maintenance personnel are informed to come to handle the water inlet problem in time, so that the rainwater entering detection and the alarm notification are realized;

2. According to the transformer substation for the electric energy storage system, the movable assembly is arranged, and by utilizing the lever principle, when rainwater does not enter the inner wall of the box body of the transformer substation, the movable plate of the movable assembly is in a horizontal static balance state due to the fact that the movable plate is magnetically attracted with the inner wall of the shell and the inclined plate; however, when rainwater enters the inner wall of the transformer substation box body, the state can be gradually broken, namely, the rainwater can be accumulated to the right end of the movable plate after flowing into the shell through the inclined plate of the detection assembly, the gravity of the right end of the movable plate is gradually greater than the suction threshold value of the inner wall of the shell and the inclined plate to the movable plate, the movable plate leaves the inner wall of the shell and the inclined plate to rotate clockwise, and then the rainwater is guided into the prompting assembly through the surface of the movable plate and a pipeline of the detection assembly, so that the subsequent water absorption and alarm processes can be facilitated;

3. according to the transformer substation for the electric energy storage system, the water absorption assembly and the material control assembly are arranged, and by utilizing the negative pressure principle, when rainwater does not enter the inner wall of a box body of the transformer substation, the air bag of the water absorption assembly is in a natural expansion state, activated carbon powder in the air bag is not released outwards, and the two baffles of the material control assembly are in a state of mutually magnetically attracting to seal the inlet at the head end of the guide pipe; however, after rainwater enters the inner wall of the box body of the transformer substation, the state can be gradually broken, namely, after the movable plate rotates clockwise in the rainwater flowing into the shell as described above, the movable plate can gradually approach the air bag and finally press the air bag to deform, gas in the air bag surges towards the inlet direction of the head end of the guide pipe under the action of a negative pressure principle, so that a magnetic force sealing threshold value between two baffles and a supporting force threshold value of two supporting blocks are broken through, the supporting plates are pressed to deform to enable the baffles to rotate to open the inlet of the head end of the guide pipe, and activated carbon powder in the air bag is guided out into the prompting component through the guide pipe to be in mixed contact with the rainwater entering the prompting component in the past, so that the rainwater is absorbed;

4. According to the transformer substation for the electric energy storage system, by arranging the prompting component and the alarming component, when rainwater does not enter the inner wall of the box body of the transformer substation, each sliding chute of the prompting component is positioned in the position, close to the tail end of each guide pipe, of each sliding rail by utilizing the dynamic change between gravity and suction force, and each sliding chute is attached to the inner wall of each sliding rail in a static balance state due to the fact that each sliding rail is attracted by the magnetic force of each sliding rail (namely, the gravity of the sliding chute is equal to the suction force of the sliding rail to the sliding rail at the moment); when rainwater enters the inner wall of the box body of the transformer substation, the rainwater is led into the chute closest to the rainwater through the pipeline after entering the shell of the detection assembly, then the activated carbon powder in the air bag of the water absorption assembly of the detection assembly is led out into the chute closest to the rainwater through the conduit, the gravity of the whole chute is increased while the activated carbon powder in the chute adsorbs the rainwater so as to break through the suction threshold value of the prior chute on the chute and slide downwards in the chute, so that under the common cooperation effect of the chutes, the chutes press the chute at the bottommost end position in the chute to slide onto the moving plate of the alarm assembly, and further the moving plate also slides downwards after being weighted so as to press the alarm button, so that the wireless alarm gives an alarm and timely informs maintenance personnel of the rainwater infiltration, so as to carry out corresponding maintenance work, thus realizing prompt and alarm;

5. In conclusion, the transformer substation for the electric energy storage system can timely detect whether rainwater enters the transformer substation box body or not in the electric energy storage process in rainy and snowy weather through the combined cooperation effect of the detection assembly, the movable assembly, the water absorption assembly, the material control assembly, the prompt assembly, the alarm assembly and the like, and timely informs maintenance personnel to perform corresponding maintenance work.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic cross-sectional view of the present invention;

FIG. 3 is an enlarged schematic view of the structure at A in FIG. 2 according to the present invention;

FIG. 4 is a schematic view of the overall structure of the detecting assembly of the present invention;

FIG. 5 is an enlarged view of the structure of FIG. 3B according to the present invention;

FIG. 6 is a schematic diagram of a partially exploded configuration of the reminder assembly of the present invention;

FIG. 7 is a schematic flow diagram of a detection system for an electrical energy storage system according to the present invention;

in FIGS. 1-7: 1-a transformer substation box body; 2-a moisture-proof base; 3-a solar panel;

4-a detection component; 401-a housing; 402-a swash plate; 403-active components; 404-a pipeline; 405-a water absorbing component;

4031-rotating shaft; 4032-active plate;

4051-balloon; 4052-activated carbon powder; 4053-catheter;

40531-material control component; 40532-rotating rod; 40533-baffle; 40534-a support block;

5-a prompt component; 501-a slide rail; 502-a chute; 503-an alarm component;

5031-a wireless alarm; 5032-alarm button; 5033-moving plate.

Detailed Description

The technical solution in the embodiment of the present invention will be clearly and completely described below with reference to fig. 1 to 7 in the embodiment of the present invention.

Example 1

Referring to fig. 1-4, in the embodiment of the invention, a transformer substation for an electric energy storage system comprises a transformer substation box body 1, a moisture-proof base 2 and a solar panel 3, wherein a plurality of detection assemblies 4 capable of detecting rainwater entering are embedded in the inner positions of the longitudinal inner wall of the transformer substation box body 1, the detection assemblies are arranged in an upper vertical direction and an adjacent and separated mode, and the detection assemblies are embedded in the inner positions of the longitudinal inner wall of the transformer substation box body 1 and can prompt maintenance personnel to maintain;

each set of detecting elements 4 comprises a shell 401, a sloping plate 402, a movable element 403 which can move autonomously after entering with rainwater, a pipeline 404 and a water absorbing element 405 which can absorb rainwater.

In the embodiment of the invention, the appearance of each shell 401 is in a shape of a hemisphere with a hollow interior, the top position of the left end of each shell 401 is provided with an inlet, the upper part of the left end of each shell 401 is fixedly provided with an inclined plate 402 obliquely at the inlet position, the tail end of each inclined plate 402 extends to the right position of the middle end in the shell 401, the inclination angle between each inclined plate 402 and the horizontal plane is 45 degrees, each shell 401 and each inclined plate 402 have magnetism, the middle position in the interior of each shell 401 is movably provided with a movable assembly 403, the lower position of the right end of each shell 401 is obliquely provided with a pipeline 404 in a penetrating manner, the inclination angle between each pipeline 404 and the horizontal plane is 45 degrees, and the bottom position in the interior of each shell 401 is fixedly provided with a water absorption assembly 405;

The appearance of the shell 401 is a hollow hemisphere, so that rainwater can be conveniently guided, collected and alarm triggered; the inclination angle of the sloping plate 402 to the horizontal plane is set to 45 ° here, so as to facilitate the rainwater to flow down through the inlet of the housing 401; the inclination angle of the pipe 404 to the horizontal plane is set to 45 ° here, so that the rainwater introduced through the inclined plate 402 can be further introduced into the cue member 5 through the pipe 404.

The substation for the electric energy storage system is provided with the detection component 4 and the prompt component 5, and utilizes the lever, the negative pressure principle and the dynamic change between gravity and suction, when the substation converts solar energy into electric energy for storage, and in rainy and snowy weather, rainwater flows down through the gap of the substation box body 1 and then slides down from the inclined plate 402 at the inlet of the shell 401 of the detection component 4 to the shell 401, the movable component 403 of the detection component 4 moves under the action of the lever principle, and then the rainwater is guided into the water absorption component 405 through the pipeline 404 of the detection component 4 for collection, the water absorption component 405 of the detection component 4 is triggered by the negative pressure principle to release water absorption materials towards the prompt component 5 in the moving process by the movable component 403, and the water absorption materials are dynamically changed between gravity and magnetic force after the prompt component 5 absorbs the rainwater, the prompt component 5 is triggered to give an alarm, and a maintenance worker is informed of coming to deal with the problem of water inflow in time, so that rainwater entering is detected and the alarm is informed.

Example 2

Referring to fig. 3, the embodiment of the present invention is different from embodiment 1 in that: each set of movable components 403 includes a rotating shaft 4031 and a movable plate 4032.

In the embodiment of the present invention, each rotating shaft 4031 is rotatably mounted at the left position of the middle end of the inner wall of each housing 401 in the front-back horizontal direction, a movable plate 4032 is fixedly mounted on the outer surface of the right side of each rotating shaft 4031 in a surrounding manner, the tail part of the right end of each movable plate 4032 extends to the right position of the inner wall of each housing 401, each movable plate 4032 has magnetism different from that of each housing 401 and each inclined plate 402, and each movable plate 4032 is in a horizontal static balance state due to magnetic attraction with the inner wall of each housing 401 and each inclined plate 402 under a normal condition;

the movable plate 4032 is designed to trigger the movable plate 4032 to rotate clockwise after rainwater is guided into the housing 401 by using the principle of leverage, so as to trigger the water absorbing assembly 405 to release water absorbing material.

According to the transformer substation for the electric energy storage system, by arranging the movable assembly 403 and utilizing the lever principle, when rainwater does not enter the inner wall of the transformer substation box body 1, the movable plate 4032 of the movable assembly 403 is in a horizontal static balance state due to the magnetic attraction with the inner wall of the shell 401 and the inclined plate 402; however, when rainwater enters the inner wall of the substation box 1, the rainwater is accumulated at the right end of the movable plate 4032 after flowing into the housing 401 through the inclined plate 402 of the detection assembly, so that the gravity at the right end of the movable plate 4032 is gradually greater than the suction threshold of the inner wall of the housing 401 and the inclined plate 402 to the movable plate 4032, the movable plate 4032 is separated from the inner wall of the housing 401 and the inclined plate 402 to rotate clockwise, and then the rainwater is guided into the prompting assembly 5 through the surface of the movable plate 4032 and the pipeline 404 of the detection assembly, thereby facilitating the subsequent water absorption and alarm processes.

Example 3

Referring to fig. 3 and 5, the embodiment of the present invention is different from embodiment 1 in that: each set of water absorbent assemblies 405 includes a balloon 4051, activated carbon powder 4052, and a catheter 4053.

In the embodiment of the invention, air bags 4051 are fixedly mounted at the bottom end of the inner wall of each shell 401, the appearance of each air bag 4051 is fan-shaped on a longitudinal section, the outer surfaces of the left side and the right side of each air bag 4051 are fixedly attached to the inner wall of the shell 401, activated carbon powder 4052 is pre-mounted at the inner position of each air bag 4051, a guide pipe 4053 obliquely penetrates through the lower part of the right end of each air bag 4051, each guide pipe 4053 penetrates through the lower part of the right end of each shell 401, and the inclination angle of each guide pipe 4053 to the horizontal plane is 30 degrees;

the air bag 4051 with a fan-shaped appearance on one longitudinal section is used for pressing the air bag 4051 to lead out the activated carbon powder 4052 in the air bag 4051 to absorb water through the conduit 4053 after the movable plate 4032 rotates by utilizing the negative pressure principle; here, the inclination angle of the guide tube 4053 with respect to the horizontal plane is set to 30 degrees in order to prevent the guide tube 4053 from being excessively inclined and the activated carbon powder 4052 from overflowing when no rainwater is present.

In the embodiment of the invention, a material control component 40531 capable of controlling the inlet and outlet of the water-absorbing material is movably mounted at the head end position inside each conduit 4053, and each group of material control components 40531 comprises 2 rotating rods, 2 baffle plates 40533 and 2 supporting blocks 40534.

In the embodiment of the present invention, each 2 rotating rods 40531 are respectively rotatably installed at two positions on the left and right of the head end of the inner wall of each conduit 4053 in the front-back horizontal direction, the outer surface of the opposite side of each 2 rotating rods 40531 is respectively provided with a baffle 40533 in a surrounding manner, each 2 baffles 40533 are normally in a state of being magnetically attracted to each other to close the inlet of the head end of each conduit 4053, the two positions on the left and right of the head end of the inner wall of each conduit 4053 are respectively fixedly provided with a supporting block 40534 near the head end of each baffle 40533, and each supporting block 40534 is made of rubber;

the material of the supporting block 40534 is selected to be rubber, which is to use the toughness of rubber to seal the inlet of the head end of the conduit 4053 by the supporting baffle 40533 when the normal air bag 4051 is not pressed, so as to prevent the activated carbon powder 4052 from overflowing.

According to the transformer substation for the electric energy storage system, the water absorption assembly 405 and the material control assembly 40531 are arranged, and by utilizing the negative pressure principle, when rainwater does not enter the inner wall of the transformer substation box body 1, the air bag 4051 of the water absorption assembly 405 is in a natural expansion state, the activated carbon powder 4052 in the air bag is not released outwards, and the two baffles 40533 of the material control assembly 40531 are in a state that the inlet at the head end of the guide pipe 4053 is closed due to mutual magnetic attraction; however, when rainwater enters the inner wall of the substation box 1, the state is gradually broken, that is, after the rainwater flows into the housing 401 to rotate the movable plate 4032 clockwise as described above, the movable plate 4032 gradually approaches the air bag 4051, and finally the air bag 4051 is pressed to deform, so that the gas in the air bag 4051 surges toward the inlet of the head end of the conduit 4053 under the action of the negative pressure principle, and further the magnetic force sealing threshold between the two baffles 40533 and the supporting force threshold of the two supporting blocks 40534 are broken through, the supporting plate 40534 is pressed to deform so that the baffles 40533 rotate to open the inlet of the head end of the conduit 4053, and the activated carbon powder 4052 in the air bag 4051 is guided out through the conduit 4053 to the prompting component 5 to be in mixed contact with the rainwater entering previously, so as to absorb the rainwater.

Example 4

Referring to fig. 3 and 6, in the embodiment of the present invention, each group of prompting components 5 includes a sliding rail 501, a plurality of sliding grooves 502, and an alarm component 503 capable of alarming.

In the embodiment of the invention, each slide rail 501 is fixedly mounted at the inner position of the longitudinal inner wall of the transformer substation box body 1 in the vertical and vertical directions, a plurality of slide grooves 502 are slidably mounted at the inner position of each slide rail 501, the total number of the slide grooves 502 is equal to the total number of the detection components 4, each slide rail 501 and each slide groove 502 have different magnetism, the tail ends of each pipeline 404 and each conduit 4053 penetrate into the slide rail 501, the initial position of each slide groove 502 is located at the position close to the tail end of each conduit 4053 in the inner part of each slide rail 501, and each slide groove 502 is attached to the position close to the tail end of each conduit 4053 in the inner wall of each slide rail 501 in a static balance state due to magnetic attraction with each slide rail 501 under normal conditions;

the chute 502 can ensure that rainwater can be guided into the chute 502 after water enters the housing 401 of each detection assembly 4, and simultaneously, the activated carbon powder 4052 is released into the chute 502 to enable the weight to increase and slide downwards in the slide rail 501, so that the subsequent alarm assembly 503 is triggered to alarm.

In the embodiment of the invention, each set of alarm assemblies 503 comprises a wireless alarm 5031, an alarm button 5032 and a movable plate 5033.

In the embodiment of the invention, each wireless alarm 5031 is fixedly mounted at the bottom end of each longitudinal inner wall of the substation box body 1, an alarm button 5032 is fixedly mounted at the bottom end of the interior of each sliding rail 501, each alarm button 5032 is electrically connected with each wireless alarm 5031 adjacent to the alarm button 5032, a moving plate 5033 is slidably mounted at the inner wall of each sliding rail 501 at the position right above each alarm button 5032, the appearance of each moving plate 5033 is inverted letter T-shaped on a longitudinal section, each moving plate 5033 has magnetism different from that of each sliding rail 501, and each moving plate 5033 is attached to the inner wall of each sliding rail 501 in a static balance state due to magnetic attraction with each sliding rail 501 and is located at a position right below a sliding groove 502 at the bottom end in each sliding rail 501 under normal conditions;

the movable plate 5033 with an inverted letter T-shaped longitudinal section is used for pushing the chute 502 to press the alarm button 5032 downwards after the chute 502 moves downwards so as to trigger the wireless alarm 5031 to allow rainwater to penetrate into the substation box 1, and informing a maintenance worker of relevant maintenance work in time.

According to the substation for the electric energy storage system, by arranging the prompting component 5 and the alarm component 503, when rainwater does not enter the inner wall of the substation box body 1, by utilizing the dynamic change between gravity and suction force, each sliding chute 502 of the prompting component 5 is positioned in the sliding rail 501 at a position close to the tail end of each guide pipe 4053, and each sliding chute 502 is attached to the inner wall of the sliding rail 501 in a static balance state due to the fact that the sliding chute 502 is magnetically attracted to each sliding rail 501 (namely, the gravity of the sliding chute 502 is equal to the suction force of the sliding rail 501 to the sliding chute 502 at the moment); however, when rainwater enters the inner wall of the substation box 1, the rainwater enters the housing 401 of the detection assembly 4 and then enters the chute 502 closest to the detection assembly through the pipe 404, the activated carbon powder 4052 in the air bag 4051 of the water absorption assembly 405 of the detection assembly 4 is guided out of the chute 502 closest to the detection assembly through the pipe 4053, the activated carbon powder 4052 in the chute 502 adsorbs the rainwater, and simultaneously the gravity of the whole chute 502 is increased to break through the suction threshold of the slide rail 501 to the chute 502, so that the downward sliding in the slide rail 501 occurs, and thus under the cooperative action of the plurality of chutes 502, the plurality of chutes 502 press the chute 502 at the bottom end position in the slide rail 501 to slide onto the moving plate 5033 of the alarm assembly 503, and the moving plate 5033 also slides downward to press the alarm button 5032, the wireless alarm 5031 is enabled to alarm, and maintenance personnel are informed of the rainwater infiltration in time to perform corresponding maintenance work, so as to realize prompting and alarming.

Example 5

Referring to fig. 7, in an embodiment of the present invention, a detection system for an electric energy storage system includes the following steps:

s1: the solar panel 3 converts solar energy into electric energy and stores the electric energy in the transformer substation;

s2: the detection assembly 4 detects whether rainwater enters the transformer substation box body 1 in real time, if so, the transformer substation box body enters S3, and if not, the detection assembly continues to the S1;

s3: rainwater slides downwards through the inner wall of the transformer substation box body 1 and enters a shell 401 of the detection assembly 4;

s4: the movable element 403 of the trigger detection element 4 moves;

s5: rainwater is guided into the chute 502 of the prompting component 5 through the pipeline 404 of the detection component 4, and meanwhile, the water absorption component 405 of the detection component 4 is pressed to guide water absorption materials in the chute 502;

s6: after the water absorption materials absorb rainwater, the sliding groove 502 is weighted, so that the sliding groove 502 slides downwards in the sliding rail 501 of the prompt component 5, and finally the alarm component 503 is triggered to alarm and maintain.

Claims (10)

1. The utility model provides a transformer substation that electric energy storage system used, includes transformer substation box (1), dampproofing base (2) and solar cell panel (3), its characterized in that: the transformer substation box body (1) is provided with a plurality of detection assemblies (4) capable of detecting rainwater entering, and the transformer substation box body (1) is also provided with a prompt assembly (5) capable of prompting maintenance personnel to maintain;

Each group of detection components (4) comprises a shell (401), an inclined plate (402), a movable component (403) capable of moving automatically after rainwater enters, a pipeline (404) and a water absorption component (405) capable of absorbing rainwater.

2. A substation for an electrical energy storage system according to claim 1, characterized in that: the appearance of each shell (401) is in a semi-sphere shape with a hollow interior.

3. A substation for an electrical energy storage system according to claim 1, characterized in that: each set of said movable elements (403) comprises a movable plate (4032), each movable plate (4032) being normally in a horizontal resting equilibrium state.

4. A substation for an electrical energy storage system according to claim 1, characterized in that: each group of the water absorption components (405) comprises air bags (4051), and the appearance of each air bag (4051) is fan-shaped on a longitudinal section.

5. A substation for an electrical energy storage system according to claim 4, characterized in that: each of the air cells (4051) is pre-loaded with activated carbon powder (4052).

6. A substation for an electrical energy storage system according to claim 1, characterized in that: each group of the prompt component (5) comprises a sliding rail (501).

7. A substation for an electrical energy storage system according to claim 1, characterized in that: each group of the prompt component (5) further comprises a plurality of sliding grooves (502), and the total number of the sliding grooves (502) is equal to the total number of the detection components (4).

8. A substation for an electrical energy storage system according to claim 1, characterized in that: each group of the prompting assemblies (5) also comprises alarm assemblies (503) capable of giving an alarm, and each group of the alarm assemblies (503) comprises a wireless alarm (5031).

9. A substation for an electrical energy storage system according to claim 8, characterized in that: each group of alarm assemblies (503) also comprises a movable plate (5033), and the appearance of each movable plate (5033) is in an inverted letter T shape on a longitudinal section.

10. A detection system for an electrical energy storage system, characterized by: a substation for an electrical energy storage system according to any of claims 1-9, the system comprising the steps of:

s1: the solar panel (3) converts solar energy into electric energy and stores the electric energy in a transformer substation;

s2: the detection assembly (4) detects whether rainwater enters the transformer substation box body (1) in real time, if so, the transformer substation box body enters S3, and if not, the transformer substation box body continues to enter S1;

S3: rainwater slides downwards through the inner wall of the transformer substation box body (1) and enters the shell (401) of the detection assembly (4);

s4: -triggering the movement of the movable element (403) of the detection element (4);

s5: rainwater is guided into the chute (502) of the prompting component (5) through the pipeline (404) of the detection component (4), and meanwhile, the water absorption component (405) of the detection component (4) is pressed to guide the water absorption material in the chute (502);

s6: after the water absorption materials absorb rainwater, the sliding groove (502) is weighted, so that the sliding groove (502) slides downwards in the sliding rail (501) of the prompt component (5), and finally the alarm component (503) is triggered to alarm and maintain.

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