A structure for monitoring large capacity battery storage of a slope

Abstract

The utility model belongs to the field of battery storage structure, concretely relates to a structure for slope monitoring large capacity battery storage includes the structure wall body of pre -buried in the earth mass, the structure wall body top opening and cover is equipped with the structure cover plate, the structure wall body is bonded together with the structure cover plate through the building cementing agent, the structure wall body and structure cover plate form the battery containing storehouse, the structure cover plate includes the cover portion of with the structure wall body top opening matching, the support lug portion of position higher than the cover portion and the connecting plate of connecting cover portion and support lug portion, the earth mass is filled in between connecting plate and cover portion, the utility model can avoid the battery group storage underground to be damped, while the earth mass on the cover portion can avoid the sunlight heat to the battery containing storehouse, is favorable to avoid the condition of battery storehouse temperature rise, the utility model is convenient for battery overhaul, avoids the present battery to be roughly buried in the underground or to be directly sealed with cement concrete, cannot overhaul the condition.

Description

Technical Field

[0001] This utility model belongs to the field of battery storage structure technology, specifically relating to a structure for storing large-capacity batteries for slope monitoring. Background Technology

[0002] The stability of highway slopes is crucial to the safety of life and property of residents along highways and the safety of traffic. Especially in recent years, with the rapid development of my country's transportation infrastructure, highway slope monitoring has received increasing attention from highway construction and maintenance departments. Currently, most highway slope monitoring equipment is powered by solar energy. Previously, the number of devices used for slope monitoring was small, and the power consumption was low; small-capacity batteries placed in external column boxes were generally sufficient for monitoring needs. However, in recent years, with the gradual improvement of relevant standards and guidelines for slope monitoring, the number of devices required to be installed on a slope has increased significantly, leading to higher power consumption. Traditional small-capacity batteries are no longer sufficient, making large-capacity batteries the preferred choice. However, due to the larger size of large-capacity batteries, traditional battery storage methods are not suitable.

[0003] Currently, during the installation of slope monitoring equipment, most methods simply and crudely bury large-capacity batteries underground or directly cover and fix them with concrete. However, this method is problematic because the underground environment is damp, and rainwater seepage affects the battery's lifespan. Furthermore, it is inconvenient for battery inspection and maintenance.

[0004] Therefore, there is a need to provide an improved technical solution that addresses the shortcomings of the existing technology. Utility Model Content

[0005] The purpose of this invention is to overcome the shortcomings of the prior art and provide a structure for storing large-capacity batteries for slope monitoring. The large-capacity batteries for slope monitoring are stored underground, and a specially designed storage structure is adopted to facilitate the proper preservation and maintenance of the large-capacity batteries for slope monitoring.

[0006] To achieve the above objectives, this utility model provides the following technical solution:

[0007] A structure for storing large-capacity batteries for slope monitoring includes: a structural wall embedded in the soil, the top of the structural wall being open and covered with a structural cover plate; the structural wall and the structural cover plate are bonded together by a building adhesive, and the structural wall and the structural cover plate together form a battery storage compartment.

[0008] The structural cover plate includes a cover portion that matches the opening at the top of the structural wall, a support portion positioned higher than the cover portion, and a connecting plate connecting the cover portion and the support portion, with soil filling the space between the connecting plate and the cover portion.

[0009] Furthermore, the distance from the cover to the upper surface of the soil is not less than 30cm.

[0010] Furthermore, the connecting plate is vertically arranged.

[0011] Furthermore, the support lug is provided with several fixing holes, and the fixing holes are provided with anchors for fixing the structural cover plate to the soil.

[0012] Furthermore, the structural cover plate consists of two symmetrically arranged sub-covers.

[0013] Furthermore, the upper surface of the cover is provided with an auxiliary component to facilitate lifting the structural cover plate.

[0014] Furthermore, the structural cover plate is a precast reinforced concrete structure, and the thickness of the cover is not less than 5cm.

[0015] Furthermore, the battery compartment contains a battery pack and a desiccant, with the battery pack symmetrically placed within the battery compartment.

[0016] Furthermore, the structure for storing large-capacity batteries for slope monitoring also includes a column for installing solar panels, the lower end of which passes through the structural cover plate and structural wall and is inserted into the soil.

[0017] Furthermore, the column is provided with a through hole located inside the battery compartment, and the lower end of the column extends downwards beyond the bottom of the structural wall by a distance of not less than 30cm.

[0018] The beneficial effects of this utility model are:

[0019] This utility model provides a solution for storing large-capacity batteries used in slope monitoring. By sealing and bonding a structural cover plate and structural wall together, a sealed and dry battery storage compartment is formed, which can prevent the battery pack from getting damp underground. At the same time, the soil covering the cover can prevent sunlight heat from being transferred to the battery storage compartment, which helps to prevent the battery compartment from overheating.

[0020] This invention facilitates battery maintenance, avoiding the current situation where batteries are roughly buried underground or directly sealed with cement concrete, making maintenance impossible. Attached Figure Description

[0021] The accompanying drawings, which form part of this application, are used to provide a further understanding of the present invention. The illustrative embodiments of the present invention and their descriptions are used to explain the present invention and do not constitute an undue limitation of the present invention. Wherein:

[0022] Figure 1 This is an exploded structural diagram of Embodiment 1 of the present invention.

[0023] Figure 2 This is an exploded structural diagram of Embodiment 2 of the present invention.

[0024] Figure 3 This is a structural diagram of the cover plate in Embodiment 2 of this utility model.

[0025] Figure 4 This is a top view of the structural cover plate of Embodiment 2 of this utility model.

[0026] Figure 5 This is a schematic diagram of the usage state of Embodiment 2 of this utility model.

[0027] In the diagram: 1-soil, 2-structural wall, 21-bottom hole, 3-desiccant, 4-battery pack, 5-structural cover plate, 50-cover, 51-support lug, 511-fixing hole, 52-joint, 53-cover hole, 6-anchor, 7-handle, 71-lifting ring, 8-solar panel, 9-bracket, 10-column, 11-through hole, 12-threading hole. Detailed Implementation

[0028] The technical solutions in the embodiments of this utility model will be clearly and completely described below. Obviously, the described embodiments are only some embodiments of this utility model, and not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art are within the protection scope of this utility model.

[0029] The present invention will now be described in detail with reference to the accompanying drawings and embodiments. It should be noted that, unless otherwise specified, the embodiments and features described herein can be combined with each other.

[0030] Example 1

[0031] like Figure 1 As shown, a structure for storing large-capacity batteries for slope monitoring includes: a structural wall 2 embedded in the soil 1, the top of the structural wall 2 being open and covered with a structural cover plate 5; the structural wall 2 and the structural cover plate 5 are bonded together with a building adhesive to prevent groundwater and rainwater from entering the structure through the joint between the structural cover plate 5 and the structural wall 2; the structural wall 2 and the structural cover plate 5 together form a battery storage compartment;

[0032] The structural cover plate 5 includes a cover portion 50 that matches the top opening of the structural wall 2, a support portion 51 positioned higher than the cover portion 50, and a connecting plate connecting the cover portion 50 and the support portion 51; soil 1 is filled between the connecting plate and the cover portion 50. In this embodiment, the structure for storing large-capacity batteries for slope monitoring is separately buried underground near the column 10.

[0033] The structural wall 2 is a precast reinforced concrete structure or a cast-in-place brick-concrete structure. The distance from the cover 50 to the upper surface of the soil 1 is not less than 30cm, so that the thickness of the soil 1 buried between the connecting plate and the cover 50 can insulate against solar heat, making it difficult for the temperature inside the battery compartment to change with the surface temperature. The structural wall 2 is buried in the soil 1, and the length, width, and height of the structural wall 2 should meet the storage requirements of the battery pack 4; the top of the structural wall 2 is reserved with a wire hole 12 for the entry and exit of the battery pack 4 wires.

[0034] Furthermore, the structural cover plate 5 is a precast reinforced concrete structure, and the thickness of the cover 50 is not less than 5cm, providing sufficient load-bearing capacity and a certain degree of heat insulation.

[0035] Furthermore, the cover 50 has a rectangular shape when viewed from above, and the connecting plate is used to connect the cover 50 and the lug 51. The connecting plate is disposed on opposite sides or four sides of the cover 50. The connecting plate is vertically arranged or inclined, so that the shape between the connecting plate and the cover 50 is rectangular, trapezoidal, or quadrangular. Preferably, the connecting plate is vertically arranged to facilitate the shaping and treatment of the soil 1 outside the connecting plate. At the same time, in order to prevent the soil 1 outside the connecting plate from collapsing and entering the battery compartment after the structural cover 5 is lifted, it is best to harden the soil 1 around the connecting plate, such as by grouting, concrete, or soil rock-forming agent.

[0036] Furthermore, the support ear 51 is provided with a plurality of fixing holes 511, and the fixing holes 511 are provided with anchors 6 for fixing the structural cover plate 5 to the soil 1. The anchors 6 can be fixed elements such as anchor nails that can be inserted into the soil 1 and have relatively large heads.

[0037] Furthermore, the battery pack 4 is symmetrically placed inside the battery housing compartment; the battery housing compartment contains the battery pack 4 and desiccant 3 to ensure the dryness inside the battery housing compartment and prevent the battery pack 4 from getting damp.

[0038] The operation process in this embodiment is as follows:

[0039] Excavate the foundation according to the design; after the foundation is excavated, construct the structural wall 2; trim the upper part of the foundation corresponding to the structural cover plate 5 according to the design, and harden the soil 1; then place the battery pack 4 in the battery housing, and it is best to slightly elevate the battery pack 4 during placement; apply building adhesive to the top of the structural wall 2 and cover it with the structural cover plate 5; finally, fix the structural cover plate 5 with anchor nails in the fixing holes 511 of the support lugs 51.

[0040] When the battery pack 4 malfunctions or requires maintenance, remove the soil 1 from the cover 50, pull out the anchors from the lugs 51 of the structural cover plate 5, and lift the auxiliary parts to open the structural cover plate 5. After maintenance, reapply building adhesive to the top of the structural wall 2, cover the structural cover plate 5, backfill with soil 1, and drive the anchors into the fixing holes 511 of the lugs 51.

[0041] Example 2

[0042] The difference between this embodiment and embodiment 1 is that in this embodiment 2, the structure used for storing large-capacity batteries for slope monitoring also serves as the support structure for column 10.

[0043] like Figures 2 to 5 As shown, the structure for storing large-capacity batteries for slope monitoring also includes a column 10 for installing solar panels 8. The solar panels 8 are installed on the top of the column 10 via a bracket 9. The lower end of the column 10 passes through the structural cover plate 5 and the structural wall 2 and is inserted into the soil 1. The lower end of the column 10 extends downward beyond the bottom of the structural wall 2 by a distance of not less than 30cm to ensure the stability of the column 10.

[0044] Furthermore, the structural cover plate 5 consists of two symmetrically arranged sub-covers, which are in a "Z" shape. The lower side is the cover portion 50, and the opposite sides of the cover portion 50 of the sub-covers have semi-circular notches. After the two sub-covers are joined together, the two semi-circular notches form a cover hole 53. Soil 1 is buried on the upper part of the cover portion 50. The higher side is the support portion 51, which is in contact with the ground. The middle part is a connecting plate, which is preferably vertically arranged. The diameter of the cover hole 53 is 5mm to 50mm larger than the diameter of the column 10. If the diameter of the cover hole 53 is too large, waterproof double-sided tape or other auxiliary treatments can be applied to the column 10. In this embodiment, the "Z" shaped structure of the structural cover plate 5 and the soil filling not only isolates the solar heat through the soil 1, but also stabilizes the column 10 to a certain extent.

[0045] The connecting plate may partially or completely surround the cover 50; such as Figure 2 , Figure 3 As shown, the connecting plate is only set on the long side of the sub-cover. At this time, the connecting plate partially surrounds the cover 50. When it is necessary to lift the structural cover 5, the soil 1 inside the structural cover 5 needs to be cleared first to prevent the soil 1 on the structural cover 5 from slipping into the battery compartment during the lifting process; as Figure 4 As shown, the connecting plate is set on one long side and two short sides of the cover portion 50 of the sub-cover, so that the connecting plate completely surrounds the cover portion 50. Compared with the former, in this case, when the structural cover plate 5 needs to be removed for maintenance of the battery pack 4, the structural cover plate 5 can be lifted together with the soil 1 contained in the structural cover plate 5.

[0046] Furthermore, such as Figures 2 to 3As shown, the seam 52 between the two sub-caps is folded, which provides better waterproofing and dustproofing compared to a vertical seam 52.

[0047] Furthermore, the column 10 is provided with a through hole 11 located in the battery housing compartment. The wires of the battery pack 4 enter the interior of the column 10 through the through hole 11 so that the solar panel 8 can be connected to the battery pack 4.

[0048] Furthermore, the upper surface of the cover 50 is provided with an auxiliary component to facilitate lifting the structural cover 5. This auxiliary component is used to lift the structural cover 5 during battery maintenance. Figure 1 , Figure 2 , Figure 4 , Figure 5 As shown, the auxiliary component can be a handle 7 welded to the cover 50, or a chain or lifting ring 71 welded to the cover 50, with a lifting rope connected to the lifting ring 71; compared to a rigid handle 7, using a chain or lifting rope can avoid obstruction when inserting the column 10 and sealing the column 10 with the cover hole 53 of the cover 50, thus facilitating the sealing operation.

[0049] The operation process in this embodiment is as follows:

[0050] Excavate the foundation according to the design; after the foundation is excavated, insert the column 10 at the bottom of the foundation, and then construct the structural wall 2 with the column 10 as the center. The bottom hole 21 of the structural wall 2 is reserved for the column 10 to pass through; trim the part of the upper part of the foundation corresponding to the structural cover plate 5 according to the design, and harden the soil 1; then place the battery pack 4 in the battery housing, and it is best to slightly raise the battery pack 4 when placing it; apply building adhesive to the top of the structural wall 2 and cover it with the structural cover plate 5, and try to make the column 10 as centered as possible in the cover hole 53, and also apply glue to seal it; finally, fix the structural cover plate 5 with anchor nails in the fixing hole 511 of the support lug 51.

[0051] When the battery pack 4 malfunctions or requires maintenance, remove the soil 1 from the cover 50, pull out the anchors from the lugs 51 of the structural cover plate 5, and lift the auxiliary parts to open the structural cover plate 5. After maintenance, reapply building adhesive to the top of the structural wall 2, cover the structural cover plate 5, backfill with soil 1, and drive the anchors into the fixing holes 511 of the lugs 51.

[0052] In this embodiment, the structure used for storing large-capacity batteries for slope monitoring also serves as a support structure for battery pack storage and columns. This ensures the stability of the solar energy support structure while facilitating the storage and maintenance of the battery pack, thus guaranteeing the normal operation of the monitoring equipment.

[0053] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model shall be within the scope of protection of the pending claims of the present utility model.

Claims

1. A structure for monitoring large capacity battery storage of a slope, characterized by, The application relates to a structure wall (2) embedded in a soil body (1), wherein the top of the structure wall (2) is open and covered by a structure cover plate (5), the structure wall (2) and the structure cover plate (5) are bonded together by a building adhesive, and the structure wall (2) and the structure cover plate (5) form a battery accommodating bin. The structure cover plate (5) comprises a cover part (50) matched with the top opening of the structure wall (2), an ear part (51) higher than the cover part (50), and a connecting plate connecting the cover part (50) and the ear part (51), and the connecting plate and the cover part (50) are filled with the soil body (1). The distance between the cover part (50) and the upper surface of the soil body (1) is not less than 30 cm.

2. The structure for monitoring large capacity battery storage of a slope according to claim 1, wherein: The connecting plate is vertically arranged.

3. The structure for monitoring large capacity battery storage of a slope according to claim 1, wherein: A plurality of fixing holes (511) are formed in the ear part (51), and an anchoring piece (6) for fixing the structure cover plate (5) to the soil body (1) is arranged in the fixing hole (511).

4. The structure for monitoring large capacity battery storage of a slope according to claim 1, wherein: The structure cover plate (5) is composed of two symmetrically arranged sub-covers.

5. The structure for monitoring large capacity battery storage of a slope according to claim 1, wherein: An auxiliary part for conveniently lifting the structure cover plate (5) is arranged on the upper surface of the cover part (50).

6. The structure for monitoring large capacity battery storage of a slope according to claim 1, wherein: The structure cover plate (5) is a reinforced concrete prefabricated structure, and the thickness of the cover part (50) is not less than 5 cm.

7. The structure for monitoring large capacity battery storage of a slope according to claim 1, wherein: A battery pack (4) and a desiccant (3) are arranged in the battery accommodating bin, and the battery pack (4) is symmetrically arranged in the battery accommodating bin.

8. The structure for monitoring large capacity battery storage of a slope according to claim 1, wherein: A stand (10) for mounting a solar panel (8) is further arranged, and the lower end of the stand (10) penetrates the structure cover plate (5) and the structure wall (2) and is inserted into the soil body (1).

9. The structure for monitoring large capacity battery storage of a slope according to claim 1, wherein: A wire passing hole (11) is formed in the stand (10) and located in the battery accommodating bin, and the distance between the lower end of the stand (10) and the bottom of the structure wall (2) is not less than 30 cm.

10. The structure for monitoring large capacity battery storage of a slope according to claim 9, wherein: ​

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