CN115902861A - Site selection positioning exploration auxiliary equipment for energy storage power station construction - Google Patents

Abstract

The invention relates to the field of site selection, positioning and exploration, in particular to a site selection, positioning and exploration auxiliary device for energy storage power station construction, which comprises: the device comprises a bracket, a power supply, a controller and a radar transmitting device; the radar transmitting device is arranged on the bracket through the adjusting mechanism; when the bumps on the ground touch the contact plate, the electric push rod is adjusted to drive the radar transmitting device to move upwards to avoid the bumps on the ground, and then the electric push rod is controlled and adjusted to drive the radar transmitting device to move downwards after the contact plate and the radar transmitting device cross the bumps on the ground; compared with the situation that workers push the whole device to avoid soil blocks or stones on the ground, the device is more convenient for the workers to avoid the soil blocks or stones, meanwhile, the ground below the raised soil blocks or stones can be explored, and the situation that the workers cannot avoid the soil blocks or stones on the ground timely and collide with the radar transmitting device to cause damage to the radar transmitting device can be prevented.

Description

Site selection positioning exploration auxiliary equipment for energy storage power station construction

Technical Field

The invention relates to the technical field of site selection, positioning and exploration, in particular to site selection, positioning and exploration auxiliary equipment for energy storage power station construction.

Background

The energy storage power station is used for adjusting the peak-valley power utilization problem of a power grid, namely storing electric energy in the power grid during the peak power utilization, releasing the electric energy during the peak power utilization, supplementing the electric energy in the power grid and adjusting the peak-valley power utilization problem of the power grid; the station site is selected, the distribution of the power load and the influence of natural geological disasters on the energy storage power station are considered, and therefore the station site selection of the energy storage power station is particularly important;

the site selection of the energy storage power station needs to consider network distribution, load distribution and urban and rural planning of a power grid, reasonably use land and use land with low economic benefits such as wasteland, inferior land and the like as the site of the energy storage power station as much as possible; the selected site should have proper geological and topographic conditions to avoid the topography such as underground karst cave, goaf and fault, so that the underground of the selected site needs to be detected and explored when the site is selected, and whether the topography such as the underground karst cave, the goaf and the fault exists or not;

underground topography exploration equipment's a great variety, wherein when the staff uses ground penetrating radar to carry out underground detection and exploration to the site selection of energy storage power station, because the exploration place is mostly wasteland and inferior land, the land unevenness, and ground need be pressed close to ground penetrating radar's radar emitter, consequently radar emitter can be blockked by bellied clod or stone in ground at the in-process of exploration, the staff need promote whole equipment and bypass bellied clod or stone on the ground, operate promptly, it is inconvenient also to make exist the exploration omission in subaerial bellied clod or stone department.

In view of the above, in order to overcome the above technical problems, the invention provides an auxiliary device for location and exploration in energy storage power station construction, which solves the above technical problems by lifting a radar transmitting device upwards when an adjusting mechanism encounters a soil block or a stone block protruding on the ground, and then falling down after passing over the protruding soil block or stone block, so that a worker does not need to push the whole device to bypass the soil block or stone block.

Disclosure of Invention

In order to overcome the defects of the prior art, the auxiliary equipment for location and exploration in energy storage power station construction provided by the invention has the advantages that when a bulge on the ground touches a contact plate, the contact plate is enabled to rotate upwards, so that the electric push rod is controlled and adjusted to drive the radar transmitting device to move upwards to avoid the bulge on the ground, then after the contact plate and the radar transmitting device cross the bulge on the ground, the contact plate rotates downwards, the electric push rod is controlled and adjusted to drive the radar transmitting device to move downwards to return to the initial position, so that a soil block or a stone block which is bulged on a detection and exploration road is avoided, compared with the situation that a worker pushes the whole equipment to avoid the soil block or the stone block on the ground, the worker can use the auxiliary equipment to avoid the soil block or the stone block more conveniently, meanwhile, the ground below the bulged soil block or the stone block can also be explored, and the situation that the worker collides with the radar transmitting device to cause damage to the radar transmitting device can be prevented.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a site selection positioning exploration auxiliary device for energy storage power station construction, which comprises:

a support;

a power source; the power supply is clamped on the bracket through a bolt and a buckle;

a controller; the controller is fixedly connected to the bracket;

a radar transmitting device; the radar transmitting device is arranged at the bottom of the bracket and used for transmitting radar waves;

a roller; the roller is fixedly connected to the bottom of the bracket and used for moving the bracket;

the radar transmitting device is installed on the support through the adjusting mechanism, and when the ground in front of the radar transmitting device is convex, the adjusting mechanism moves the radar transmitting device upwards, so that the radar transmitting device avoids the convex on the ground.

Preferably, the adjusting mechanism comprises a mounting block, a contact plate, a control switch and an adjusting electric push rod; the mounting blocks are fixedly connected to two sides of the bottom of the support; two sides of the contact plate are respectively connected to the two mounting blocks in a rotating manner through a first torsion spring; the adjusting electric push rod is fixedly connected to the support, the output end of the adjusting electric push rod faces downwards, and the output end of the adjusting electric push rod is fixedly connected with the radar transmitting device; the control switch is arranged on the contact plate and used for controlling and adjusting the stretching amount of the electric push rod; the control switch is communicated with the power supply and the adjusting electric push rod through a circuit.

When the contact plate is touched by the bulge on the ground, the contact plate is rotated upwards, so that the electric push rod is controlled and adjusted to drive the radar transmitting device to move upwards to avoid the bulge soil blocks or stones on the ground; after the contact plate and the radar transmitting device cross the raised soil blocks or stones on the ground, the contact plate rotates downwards, the electric push rod is controlled and adjusted to drive the radar transmitting device to move downwards and return to the initial position, so that the raised soil blocks or stones on the detection and exploration road are avoided, compared with the situation that a worker pushes the whole device to avoid the soil blocks or stones on the ground, the radar transmission device is more convenient for the worker to avoid the soil blocks or stones when using the radar transmission device, meanwhile, the ground below the raised soil blocks or stones can also be explored, the situation that the worker avoids untimely collision between the raised soil blocks or stones on the ground and the radar transmitting device to cause damage to the radar transmitting device can be prevented.

Preferably, the contact plate is provided with a first groove; the control switch is a stepless regulating switch and is fixedly connected to the groove wall of the first groove, and a long rod is fixedly connected to a regulating knob of the control switch; the long rod is fixedly connected with the bracket.

Preferably, when the contact plate is in contact with the ground, the end face of the radar transmitting device close to the ground is 1cm away from the ground.

Because the sizes of the soil blocks or the stones protruding on the ground are different, the heights of the contact plates jacked up every time are different, so that the degrees of the adjusting knobs of the control switch which are twisted every time are different, when the soil blocks or the stones protruding on the ground are relatively large, the heights of the contact plates jacked up are relatively high, the degrees of the twisting in the adjusting knobs of the control switch are relatively large, and the distance of the electric push rod with the radar transmitting device moving upwards is adjusted to be relatively large; similarly, when bellied clod or stone are less relatively on the ground, control switch's adjust knob wrench movement degree is less relatively to can adjust the distance that radar emitter moved upwards according to the size of the bellied clod or stone on the ground, make even radar emitter move upwards, when avoiding bellied clod or stone on the ground, radar emitter also can keep the shortest with the distance on ground, reduce the influence to radar emitter exploration precision.

Preferably, the bottom surface of the bracket is fixedly connected with a protective frame; the electric push rod is adjusted to be positioned in the protective frame; a first through groove is formed in the protection frame; a cleaning block is slidably connected in the first through groove.

Preferably, two sides of the cleaning block are inclined, and a second through groove with an inverted trapezoidal cross section is formed in the middle of the cleaning block; the side wall of the second penetrating groove is fixedly connected with a brush; the upper end of the brush is flush with the radar transmitting device.

Preferably, one end of the contact plate, which is in contact with the ground, is connected with a U-shaped block in a sliding manner; the U-shaped block can clean the contact block.

Preferably, the contact plate is provided with an accommodating groove; the U-shaped block is located in the receiving channel in the initial position and the curved portion of the U-shaped block is made of a resilient material, such as rubber.

Preferably, the U-shaped block is disposed obliquely at both sides in the moving direction.

Preferably, a magnet block is embedded in one end, provided with the accommodating groove, of the contact plate; the two ends of the U-shaped block, which are in contact with the contact plate, are made of metal.

When the U-shaped piece was in the holding tank, the part that the U-shaped piece was made by the metal was adsorbed by the magnet piece in the contact plate to the contact plate is lived in the both ends centre gripping of U-shaped piece, fixes in the holding tank, can not take place to rock along with the contact plate rotates from top to bottom, finally breaks away from the condition in the holding tank, causes the U-shaped piece to lose.

The invention has the following beneficial effects:

1. when the contact plate is touched by the bulge on the ground, the contact plate is rotated upwards, so that the electric push rod is controlled and adjusted to drive the radar transmitting device to move upwards to avoid the bulge soil blocks or stones on the ground; after the contact plate and the radar transmitting device cross the raised soil blocks or stones on the ground, the contact plate rotates downwards, the electric push rod is controlled and adjusted to drive the radar transmitting device to move downwards and return to the initial position, so that the raised soil blocks or stones on the detection and exploration road are avoided, compared with the situation that a worker pushes the whole device to avoid the soil blocks or stones on the ground, the radar transmission device is more convenient for the worker to avoid the soil blocks or stones when using the radar transmission device, meanwhile, the ground below the raised soil blocks or stones can also be explored, the situation that the worker avoids untimely collision between the raised soil blocks or stones on the ground and the radar transmitting device to cause damage to the radar transmitting device can be prevented.

2. According to the invention, the protective frame is arranged, and the cleaning block is arranged on the protective frame, so that dust adhered to the radar transmitting device when the radar transmitting device is close to the ground is scraped off after each exploration contact, and the exploration precision of the radar transmitting device is prevented from being influenced by the dust; meanwhile, the radar transmitting device is retracted into the protective frame after exploration is finished, and damage caused by collision in the transportation process is prevented.

Drawings

The invention will be further described with reference to the accompanying drawings.

FIG. 1 is a perspective view of the device of the present invention;

FIG. 2 is a side view of the apparatus of the present invention;

FIG. 3 isbase:Sub>A partial cross-sectional view of the guard frame, cleaning block and support shown in FIG. 1 at A-A;

FIG. 4 is an enlarged view of B of FIG. 1;

FIG. 5 is an enlarged view of C in FIG. 1;

FIG. 6 is a partial cross-sectional view of the contact plate and U-shaped block of FIG. 2 at D-D;

FIG. 7 is a schematic view of the connection between the mounting block, torsion spring I and contact plate of the present invention;

in the figure: 1. a support; 2. a power source; 3. a controller; 4. an adjustment mechanism; 41. mounting blocks; 42. a contact plate; 43. a control switch; 44. adjusting the electric push rod; 45. a first torsion spring; 46. a first groove; 47. a long rod; 5. a roller; 6. a protective frame; 61. a first through groove; 62. cleaning the block; 63. a second through groove; 64. a brush; 65. a U-shaped block; 66. accommodating a tank; 7. a radar emitting device; 8. and a magnet block.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

The first embodiment is as follows:

as shown in fig. 1, the present embodiment provides an auxiliary device for location selection and exploration in energy storage power station construction, including:

a bracket 1;

a power supply 2; the power supply 2 is clamped on the bracket 1 through a bolt and a buckle;

a controller 3; the controller 3 is fixedly connected to the bracket 1;

a radar transmission device 7; the radar transmitting device 7 is arranged at the bottom of the bracket 1 and used for transmitting radar waves;

a roller 5; the roller 5 is fixedly connected to the bottom of the support 1 and used for moving the support 1;

radar emission device 7 passes through adjustment mechanism 4 to be installed on support 1, and when the ground in radar emission device 7 the place ahead was protruding, adjustment mechanism 4 upwards removed radar emission device 7 for radar emission device 7 avoids bellied clod or stone on the ground.

As shown in fig. 2 and 7, in the present embodiment, the adjusting mechanism 4 includes a mounting block 41, a contact plate 42, a control switch 43, and an adjusting electric push rod 44; the mounting blocks 41 are fixedly connected to two sides of the bottom of the bracket 1; two sides of the contact plate 42 are respectively connected to the two mounting blocks 41 through a first torsion spring 45 in a rotating manner; the adjusting electric push rod 44 is fixedly connected to the support 1, the output end of the adjusting electric push rod 44 faces downwards, and the output end of the adjusting electric push rod is fixedly connected with the radar transmitting device 7; the control switch 43 is installed on the contact plate 42 and used for controlling and adjusting the expansion and contraction amount of the electric push rod 44; the control switch 43 is in circuit communication with the power source 2 and the adjustment power push rod 44.

When the radar transmission device is used by a worker, the power supply 2 of the radar transmission device is controlled by the controller 3 to supply power to the radar transmission device 7, so that radar waves are transmitted by the radar transmission device 7 and penetrate the underground, and are reflected when passing through an underground karst cave, a goaf and a fault, so that the radar waves are displayed on the controller 3, the worker pushes the support 1 at a constant speed, so that the roller 5 below the support 1 rolls, and the support 1 drives the radar transmission device 7, the power supply 2 and the controller 3 to move;

when there is a raised obstacle on the ground, as the bracket 1 carries the radar emission device 7 to move forward, the contact plate 42 on the bracket 1 contacts with the protrusion on the ground first, the contact plate 42 is jacked up by the protrusion on the ground, so that the contact plate 42 rotates, the contact plate 42 rotates upward and simultaneously twists the first torsion spring 45 and triggers the control switch 43, so that the control switch 43 transmits current information to the controller 3, the controller 3 controls the adjusting electric push rod 44, the output end of the adjusting electric push rod 44 carries the radar emission device 7 to move upward, so that the radar emission device 7 passes through the raised soil or stone on the ground; after the contact plate 42 and the radar transmission device 7 both pass over the soil or stone raised on the ground, the contact plate 42 is rotated downward by the torsion spring 45 to return to the initial position, and the torsion spring 45 pulls the contact plate 42 so that the contact plate 42 maintains the inclined state; in the process that the contact plate 42 rotates downwards, the contact plate 42 triggers the control switch 43 again, at the moment, after the controller 3 receives current information of the control switch 43, the controller 3 carries out delay control, and after 2 seconds, the output end of the electric push rod 44 is controlled and adjusted to drive the radar transmitting device 7 to move downwards, and the radar transmitting device 7 returns to the initial position and is close to the ground; the controller 3 carries out delay control, so that the worker pushes the radar transmitting device to cross soil blocks or stones on the ground within a delay time, and the radar transmitting device 7 is prevented from not crossing the soil blocks or stones on the ground after the contact plate 42 is contacted with the ground, and the electric push rod 44 is adjusted to drive the radar transmitting device 7 to move downwards to collide the soil blocks or stones;

when the contact plate 42 is touched by the bulge on the ground, the contact plate 42 is rotated upwards, so that the electric push rod 44 is controlled and adjusted to drive the radar transmitting device 7 to move upwards to avoid the bulge soil blocks or stone blocks on the ground; after the contact plate 42 and the radar transmitting device 7 cross the soil or stone protruding on the ground, the contact plate 42 rotates downwards, the electric push rod 44 is controlled and adjusted to drive the radar transmitting device 7 to move downwards to return to the initial position, so that the soil or stone protruding on the detection and exploration road is avoided, compared with the situation that a worker pushes the whole device to avoid the soil or stone on the ground, the soil or stone is avoided by the worker more conveniently when the radar device is used by the worker, meanwhile, the ground below the protruding soil or stone can be explored, the situation that the worker avoids untimely, the soil or stone protruding on the ground collides with the radar transmitting device 7, and the radar transmitting device 7 is damaged can be prevented.

As shown in fig. 4, in the present embodiment, a first groove 46 is formed on the contact plate 42; the control switch 43 is a stepless regulating switch, the control switch 43 is fixedly connected on the groove wall of the first groove 46, and a regulating knob of the control switch 43 is fixedly connected with a long rod 47; the long rod 47 is fixedly connected with the bracket 1.

In the present embodiment, when the contact plate 42 is in contact with the ground, the end face of the radar transmission device 7 close to the ground is 1cm away from the ground.

When the contact plate 42 rotates upwards, the contact plate 42 drives the control switch 43 to rotate, and the adjusting knob of the control switch 43 is connected with the bracket 1 through the long rod 47, so that the adjusting knob is equivalent to the adjusting knob of the control switch 43; when the soil or stone protruding from the ground contacts the contact plate 42 and pushes up the contact plate 42, the height of the contact plate 42 pushed up each time is different due to the different sizes of the soil or stone protruding from the ground, so that the degree of twisting of the adjusting knob of the control switch 43 each time is different, when the soil or stone protruding from the ground is relatively large, the height of the contact plate 42 pushed up is relatively high, the degree of twisting in the adjusting knob of the control switch 43 is relatively large, and the distance of upward movement of the electric push rod 44 with the radar transmitting device 7 is relatively large; similarly, when the soil or stone protruding on the ground is relatively small, the twisting degree of the adjusting knob of the control switch 43 is relatively small, and the distance that the electric push rod 44 adjusts the radar transmitting device 7 to drive the radar transmitting device 7 to move upwards is relatively small, so that the distance that the radar transmitting device 7 moves upwards can be adjusted according to the size of the soil or stone protruding on the ground, and even if the radar transmitting device 7 moves upwards and avoids the soil or stone protruding on the ground, the distance between the radar transmitting device 7 and the ground can be kept shortest, so that the influence on the exploration precision of the radar transmitting device 7 caused by the distance between the radar transmitting device 7 and the ground is reduced as much as possible, and the exploration precision of the radar transmitting device 7 is ensured; when the extension of the output end of the electric push rod 44 is adjusted to the maximum, the distance between the end face of the radar transmitting device 7 close to the ground and the ground is 1cm, the contact plate 42 is in contact with the ground, and the radar transmitting device 7 is 1cm higher than the contact plate 42, so that when the contact plate 42 is in contact with the ground, the situation that dust on the ground is in contact with the radar transmitting device 7 can be prevented, the dust is adhered to the radar transmitting device 7 to the greatest extent, and the influence on the exploration precision of the radar transmitting device 7 is reduced.

Example two:

compared with the first embodiment, the present embodiment is different in that:

as shown in fig. 2, in this embodiment, a protection frame 6 is fixedly connected to the bottom surface of the support 1; the adjusting electric push rod 44 is positioned in the protective frame 6; a first through groove 61 is formed in the protection frame 6; a cleaning block 62 is slidably connected in the first through groove 61.

As shown in fig. 3, in the present embodiment, two sides of the cleaning block 62 are inclined, and a second penetrating groove 63 with an inverted trapezoidal cross section is formed in the middle; a brush 64 is fixedly connected to the side wall of the second through groove 63; the upper end of the brush 64 is flush and can be brought into contact with the radar transmission device 7.

After the user finishes exploration detection, the controller 3 controls and adjusts the output end of the electric push rod 44 to contract, so that the output end of the electric push rod 44 is adjusted to drive the radar transmitting device 7 to retract into the protective frame 6, then a worker pushes the cleaning block 62 to slide back and forth in the first through groove 61, so that dust or dust particles adhered to the radar transmitting device 7 are scraped by the inclined end of the cleaning block 62, meanwhile, the brush 64 on the cleaning block 62 scrapes the bottom surface of the radar transmitting device 7 back and forth, the brushed dust falls down through the second through groove 63, and therefore the bottom surface of the radar transmitting device 7 is cleaned after each underground detection and exploration is finished, the situation that the bottom surface of the radar transmitting device 7 is close to the ground during detection and exploration and adheres to the dust and dust scraped when the contact plate 42 moves is avoided, and the detection and exploration precision of the radar transmitting device 7 is reduced; when the radar transmitting device 7 retracts into the protective frame 6, the protective frame 6 can also play a role in protecting the radar transmitting device 7, and the radar transmitting device 7 is prevented from being collided with in the transportation process.

As shown in fig. 5, in the present embodiment, a U-shaped block 65 is slidably connected to one end of the contact plate 42 contacting with the ground; the U-shaped block 65 enables cleaning of the contact block during sliding.

As shown in fig. 6, in the present embodiment, the contact plate 42 has accommodating grooves 66 symmetrically formed on the upper and lower sides thereof; the U-shaped block 65 is located in the receiving groove 66 at both ends in the initial position, and the bent portion of the U-shaped block 65 is made of an elastic material, such as rubber.

In this embodiment, the U-shaped block 65 is provided obliquely on both sides in the moving direction.

When the contact plate 42 contacts with the ground, dust and water stains on the ground are adhered to the contact plate 42, so that the dust can be agglomerated under the action of the water stains, and as the contact plate 42 moves on the ground, the agglomerated masses are accumulated to be larger and larger during each detection exploration, so that the contact plate 42 is jacked up by the agglomerated masses, the adjusting knob of the control switch 43 is twisted, and the adjusting electric push rod 44 is driven to move upwards along with the radar transmitting device 7 when no raised soil or stone is on the ground; therefore, the staff manually presses the two ends of the U-shaped block 65 and slides the U-shaped block 65 after detection and exploration are finished, so that the two ends of the U-shaped block 65 are propped open under the action of the side wall of the accommodating groove 66 inclined, the U-shaped block 65 slides out of the accommodating groove 66, under the action of pressing of the staff, the two ends of the U-shaped block 65 are attached to the contact plate 42 after sliding out of the accommodating groove 66, the U-shaped block 65 can scrape the surfaces of the contact plate 42 and one end in contact with the ground when sliding, dust blocks on the contact plate 42 and the ground contact surface are scraped, and the two sides of the U-shaped block 65 are obliquely arranged to enable the U-shaped block 65 to have the effect of shoveling when moving.

Example three:

compared with the two embodiments, the present embodiment is different in that:

as shown in fig. 6, in the present embodiment, the magnet block 8 is embedded inside the end of the contact plate 42 having the receiving slot 66; both ends of the U-shaped block 65 contacting the contact plate 42 are made of metal;

when the U-shaped block 65 is in the receiving groove 66, the metal portion of the U-shaped block 65 is attracted by the magnet 8 in the contact plate 42, so that the contact plate 42 is held at both ends of the U-shaped block 65 and fixed in the receiving groove 66, and the U-shaped block 65 is not separated from the receiving groove 66 due to shaking caused by the vertical rotation of the contact plate 42.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising a … …" does not exclude the presence of another identical element in a process, method, article, or apparatus that comprises the element.

Claims (10)

1. An auxiliary device for location and exploration in energy storage power station construction, comprising:

a support (1);

a power supply (2); the power supply (2) is arranged on the bracket (1);

a controller (3); the controller (3) is fixedly connected to the support (1);

a radar emitting device (7); the radar transmitting device (7) is arranged at the bottom of the bracket (1) and is used for transmitting radar waves;

a roller (5); the roller (5) is fixedly connected to the bottom of the support (1) and is used for moving the support (1);

the method is characterized in that:

radar emission device (7) are installed on support (1) through adjustment mechanism (4), work as when the ground in radar emission device (7) the place ahead is protruding, adjustment mechanism (4) drive radar emission device (7) rebound makes radar emission device (7) avoid subaerial arch.

2. The auxiliary site selection, positioning and exploration equipment for energy storage power station construction as claimed in claim 1, wherein: the adjusting mechanism (4) comprises a mounting block (41), a contact plate (42), a control switch (43) and an adjusting electric push rod (44); the mounting blocks (41) are fixedly connected to two sides of the bottom of the support (1); two sides of the contact plate (42) are respectively connected to the two mounting blocks (41) in a rotating manner through a first torsion spring (45); the adjusting electric push rod (44) is fixedly connected to the support (1), the output end of the adjusting electric push rod (44) faces downwards, and the output end of the adjusting electric push rod is fixedly connected with the radar transmitting device (7); the control switch (43) is arranged on the contact plate (42) and is used for controlling and adjusting the expansion and contraction amount of the electric push rod (44); the control switch (43) is in circuit communication with the power source (2) and the adjusting electric push rod (44).

3. The auxiliary device for location and exploration of energy storage power station construction according to claim 2, wherein: a first groove (46) is formed in the contact plate (42); the control switch (43) is a stepless regulating switch, the control switch (43) is fixedly connected to the wall of the first groove (46), and a regulating knob of the control switch (43) is fixedly connected with a long rod (47); the long rod (47) is fixedly connected with the bracket (1).

4. The auxiliary device for location and exploration of energy storage power station construction according to claim 2, wherein: when the contact plate (42) is in contact with the ground, the distance between the end face, close to the ground, of the radar transmitting device (7) and the ground is 1cm.

5. The auxiliary device for location and exploration of energy storage power station construction according to claim 2, wherein: the bottom surface of the bracket (1) is fixedly connected with a protective frame (6); the adjusting electric push rod (44) is positioned in the protective frame (6); a first through groove (61) is formed in the protective frame (6); a cleaning block (62) is connected in the first through groove (61) in a sliding mode.

6. The auxiliary site selection, positioning and exploration equipment for energy storage power station construction as claimed in claim 5, wherein: two sides of the cleaning block (62) are obliquely arranged, and a second penetrating groove (63) with an inverted trapezoidal cross section is formed in the middle of the cleaning block; the side wall of the second penetrating groove (63) is fixedly connected with a brush (64); the upper end of the brush (64) is flush with the radar transmitting device (7).

7. The auxiliary device for location and exploration of energy storage power station construction according to claim 2, wherein: one end of the contact plate (42) contacting with the ground is connected with a U-shaped block (65) in a sliding way; the U-shaped block (65) can clean the contact block.

8. An auxiliary equipment for location and exploration of energy storage power station construction according to claim 7, wherein: an accommodating groove (66) is formed in the contact plate (42); the U-shaped block (65) is located in the receiving groove (66) at the initial position, and the bent portion of the U-shaped block (65) is made of an elastic material.

9. An auxiliary equipment for location and exploration of energy storage power station construction according to claim 7, wherein: the U-shaped blocks (65) are obliquely arranged on two sides in the moving direction.

10. The auxiliary device for location and exploration of energy storage power station construction according to claim 8, wherein: a magnet block (8) is embedded in one end, provided with the accommodating groove (66), of the contact plate (42); both ends of the U-shaped block (65) contacting the contact plate (42) are made of metal.

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