CN218498249U - Battery pack limiting battery cabinet and battery bundle - Google Patents

Abstract

The utility model provides a spacing battery cabinet of battery package and battery cluster, include: the battery pack restraint structure comprises a stop block structure, a battery pack restraint structure and a battery cabinet frame; a plurality of battery racks are arranged in the battery cabinet frame, and battery packs are arranged on the battery racks; the battery frame is connected with the sliding block, and the battery pack is connected with the sliding block in a sliding manner; a stop block structure is arranged on one side of the battery frame and is arranged at one end of the sliding block in the extending direction; the battery frame is provided with the battery pack binding structure, and the battery pack binding structure is matched with the stop block structure to limit the periphery of the battery pack. The battery pack is restrained on the battery cabinet by arranging the plurality of battery pack restraining structures on the battery cabinet to be matched with the stop block structure, so that the battery pack is prevented from slipping out and falling off, and the reliability of the battery bundle is improved.

Description

Battery pack limiting battery cabinet and battery bundle

Technical Field

The utility model relates to a battery cabinet structure field specifically, relates to spacing battery cabinet of battery package and battery cluster.

Background

Use a plurality of battery packages to carry out orderly the stacking in the battery cluster, the battery package passes through bolt snap-on the battery cabinet, because of adopting a large amount of bolt fastening battery packages for the time consumes very long in the battery package is fixed in the battery cluster, has arranged very many battery packages in an energy memory, and consequently this makes energy memory fixed mounting time consume very much, and installation cost remains high or not.

Meanwhile, in order to increase the electric quantity of the energy storage device, a mode of increasing the number of stacked battery packs in the battery cluster is adopted under the condition that the height of the battery cluster is not changed. Therefore, the height space in the battery cluster for arranging the battery pack is greatly compressed, so that the conventional scheme of directly fixing the battery pack in the height direction by using bolts cannot be continuously used, and the battery pack cannot be fixed due to the lack of the operation space of a tool after the space is compressed; the battery pack needs to be restrained (fixed) in the battery cluster, so that the battery pack is prevented from slipping off the battery cluster, and the safety problem is avoided.

In addition, a plurality of existing battery packs are placed on a battery cabinet of a battery cluster, the battery packs are in direct contact with the battery cabinet, friction of contact positions is very large, and therefore the battery packs are difficult to push in a small range, and therefore operation of aligning fixing holes and locking bolt holes in the battery packs is also very difficult, and assembly performance of the battery packs is reduced.

To sum up, need to change the mounting means of battery package on the battery cabinet to solve traditional bolt fastening mode installation time long, be difficult to compress and assemble the difficult problem in high space.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims at providing a spacing battery cabinet of battery package and battery cluster.

According to the utility model provides a pair of spacing battery cabinet of battery package, include: the battery pack restraint structure comprises a stop block structure, a battery pack restraint structure and a battery cabinet frame;

the battery cabinet comprises a battery cabinet frame and is characterized in that a plurality of rows and columns of battery racks are arranged in the battery cabinet frame, the battery racks are of rectangular structures, a stop block structure is arranged on one side of each battery rack, and the battery pack binding structures are arranged on the other three sides of each battery rack.

Preferably, the battery pack binding structure includes: the rear baffle structure and the C-shaped side baffle edge;

the battery rack is provided with the rear baffle structure at the opposite side of the side where the baffle structure is located, and the battery rack is provided with the C-shaped side baffle side at the adjacent side of the side where the baffle structure is located.

Preferably, the C-shaped side flange includes: the upper retaining structure, the side retaining structure and the lower retaining structure;

the lower retaining structure is fixedly arranged on the battery frame, one side of the side retaining structure is vertically connected with the lower retaining structure, the other side of the side retaining structure is vertically connected with the upper retaining structure, and the sections of the upper retaining structure, the lower retaining structure and the side retaining structure form a C-shaped section;

the openings of the C-shaped cross sections on the two sides are oppositely arranged.

Preferably, the battery rack is provided with a stop block fixing hole on the edge where the stop block structure is installed, and the stop block structure is matched with the stop block fixing hole through a fastening bolt and is fixedly connected with the battery rack.

Preferably, the lower retaining structure is fixedly provided with a sliding block towards one side of the upper retaining structure.

Preferably, a reinforcing rib is arranged on one side of the battery frame, which faces away from the battery pack binding structure, and the reinforcing rib is used for reinforcing the battery frame structure to prevent the battery frame from deforming and breaking.

Preferably, a battery cluster, comprising: the battery pack is placed on a battery frame of the battery pack limiting battery cabinet;

one side of the battery pack is limited by the stop block structure, and the other three sides of the battery pack are limited by the battery pack binding structure.

Preferably, side flanges are fixedly installed on two sides of the battery pack, and when the battery pack is placed on the battery rack, the side flanges are placed between the sliding block and the upper blocking structure and are allowed to slide relative to the sliding block.

Preferably, the side flange comprises: a limit bottom plate and a limit top plate;

the two sides of the limit bottom plate are connected with the limit top plate in a staggered mode, the limit top plate is higher than the limit bottom plate, and the limit bottom plate and the limit top plate are fixedly installed on one side, facing the side blocking structure, of the battery pack.

Preferably, it is characterized in that: when the battery pack is placed on the battery rack, the limiting bottom plate is placed on the sliding block and is allowed to slide relative to the sliding block;

the distance between the limiting top plate and the upper baffle structure is smaller than the distance between the limiting bottom plate and the upper baffle structure.

Preferably, the slide block is parallel to the lower retaining structure and the extension direction of the length of the slide block is the same as the extension direction of the length of the lower retaining structure.

Preferably, the two ends of the sliding path of the battery pack along the sliding block are respectively provided with the stop block structure and the rear stop structure.

Preferably, in the process that the battery pack slides onto the battery rack, the stop block structure is not installed, the limiting bottom plate slides along the sliding block, the side blocking structures on the two sides limit the battery pack to shift left and right, the upper blocking structure and the lower blocking structure are matched with the side flanges to limit the battery pack to jump up and down, and the rear blocking structure limits the battery pack to continue to slide along the sliding direction entering the battery rack;

and after the battery pack is completely moved onto the battery frame, the stop block structure is installed and matched with the rear stop structure to limit the front and the rear of the battery pack.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. according to the battery pack restraining structure, the battery pack is restrained on the battery cabinet by matching the battery pack restraining structure on the battery cabinet with the stop block structure, so that the battery pack is prevented from slipping out and falling off, and the reliability of the battery bundle is improved;

2. the battery cabinet is provided with a plurality of battery pack binding structures and a plurality of stop block structures, the stop blocks are arranged at the front ends of the battery clusters, the battery packs enter the battery cabinet in a sliding mode, the binding structures are compact, and the occupied space is small, so that more battery packs can be accommodated under the condition that the total height of the battery clusters is not changed, and the space utilization rate of the battery clusters and the integration efficiency of the battery clusters are improved;

3. the battery pack only needs to be provided with the stop block structure, so that the battery pack is prevented from being fixed by a large number of bolts, the mounting speed of the battery pack is high, the mounting efficiency of the battery pack is improved, and the mounting cost of the battery pack is greatly reduced;

4. the battery pack enters the battery cabinet in a sliding mode, and the battery pack can slide into the battery cabinet to be installed by applying very small thrust on the battery pack in the sliding process, so that the assembling speed is increased, and the installation difficulty of the battery pack is reduced;

5. the sliding block is arranged between the battery pack structure and the binding structure, and the battery pack is not in contact with the battery cabinet, so that the surface protection treatment layers of the battery cabinet and the battery pack are intact, the situation that the junction member is rusted to damage the battery cluster structure is avoided, the risk that the battery cluster collapses after long-term use is avoided, and the safety and the reliability of the battery cluster are improved.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic perspective view of a battery cabinet;

FIG. 2 is a schematic view of a battery cabinet mounting block;

FIG. 3 is a schematic diagram of a frame structure of a battery cabinet;

FIG. 4 is a schematic partial front view of a battery pack restraint structure;

FIG. 5 is a schematic top view of a battery pack restraint structure;

FIG. 6 is a schematic view of a side flange mating slide;

FIG. 7 is a schematic view of a side flange structure;

shown in the figure:

Detailed Description

The present invention will be described in detail with reference to specific embodiments. The following examples will assist those skilled in the art in further understanding the present invention, but are not intended to limit the invention in any way. It should be noted that various changes and modifications can be made by one of ordinary skill in the art without departing from the spirit of the invention. All of which belong to the protection scope of the present invention.

In one possible embodiment, as shown in fig. 1 to 3, the battery cabinet 1 includes: the method comprises the following steps: a stopper structure 12, a battery pack binding structure 13 and a battery cabinet frame 15; a plurality of layers of battery racks are arranged in the battery cabinet frame 15, a stop block structure 12 is arranged on one side of each battery rack, and battery pack binding structures 13 are arranged on the other three sides of each battery rack.

The battery rack can be arranged into a rectangular structure, can also be arranged into a square structure or a structure with other shapes, and can be specifically arranged according to the actual use condition, and the embodiment of the application does not limit the structure. In addition, the embodiment of the present application does not limit the specific structure of the battery pack restraining structure 13, as long as the battery pack 2 can be restrained by the stopper structure 12.

In a possible embodiment, the battery pack restraining structures 13 may include three battery pack restraining structures 13, the battery pack restraining structures 13 mounted on two sides of the battery rack adjacent to one side where the stopper structure 12 is mounted limit the battery pack 2 left and right through matching, the battery pack restraining structures 13 themselves may be used for limiting the battery pack 2 up and down, and 3 battery pack restraining structures 13 are matched with the stopper structure 12 to limit the front and back of the battery pack 3; in another possible embodiment, the battery pack restraining structure 13 may be two, wherein one battery pack restraining structure 13 is partially installed on one side of the battery rack adjacent to one side of the mounting stopper structure 12, and partially installed on one end of the battery rack opposite to one side of the mounting stopper structure 12, and is used for circumferentially limiting the battery pack 2 through the cooperation of the battery pack restraining structure 13 and the stopper structure 12; the embodiments of the present application are merely examples, and are not limited thereto.

In one possible embodiment, the battery rack may be provided with a stopper fixing hole 122 on the side where the stopper structure 12 is installed, and the stopper structure 12 is fixedly connected to the battery rack through the fastening bolt 121 cooperating with the stopper fixing hole 122, and in other possible embodiments, the battery rack may also be installed with the stopper structure 12 through other manners, such as clamping, welding, and the like.

In one possible embodiment, as shown in fig. 4 and 5, the battery pack restraining structure 13 may include: backstop structure 131 and C type side flange, battery frame installation dog structure 12 place the opposite side installation backstop structure 131 on limit, battery frame installation dog structure 12 place the adjacent side installation C type side flange on limit. The C-shaped side flange comprises: the battery pack comprises an upper blocking structure 132, a side blocking structure 133 and a lower blocking structure 134, wherein the lower blocking structure 134 is fixedly installed on the battery frame, one side of the side blocking structure 133 is vertically connected with the lower blocking structure 134, the other side of the side blocking structure 133 is vertically connected with the upper blocking structure 132, and the cross sections of the upper blocking structure 132, the lower blocking structure 134 and the side blocking structure 133 form a C-shaped cross section.

In the embodiment of the application, the battery pack 2 is restrained on the battery cabinet 1 by the battery pack restraining structure 13 on the battery cabinet 1 matching with the stop block structure 12, so that the battery pack 2 is prevented from slipping out and falling off, and the reliability of the battery cluster is improved; a plurality of battery pack binding structures 13 and a stopper structure 12 are arranged on a battery cabinet 1, the stopper structure 12 is arranged at the front end of a battery cluster, a battery pack 2 enters the battery cabinet 1 in a sliding mode, the battery pack binding structures 13 are compact, and the occupied space is small, so that more battery packs 2 can be accommodated under the condition that the total height of the battery cluster is not changed, and the space utilization rate of the battery cluster and the integration efficiency of the battery cluster are improved; battery package 2 only needs installation dog structure 12, has avoided using a large amount of bolts to fix, and battery package 2's installation rate is fast, has promoted battery package 2 and has installed efficiency, very big reduction battery package 2's installation cost.

In another possible implementation manner, the battery pack limiting battery cabinet provided in the embodiment of the present application may further include a slider 11; the slider 11 is disposed on the battery pack binding structure 13 and located between the battery pack binding structure 13 and the battery pack 2.

The sliding block 11 is arranged between the battery pack 2 and the battery pack binding structure 13, the sliding block 11 is made of nonmetal materials with small friction coefficient, good wear resistance and good flame resistance, such as PA (polyamide), PA + GB (polyamide mixed glass fiber), PP (polypropylene), PP + GB (polypropylene mixed glass fiber), PVC (polyvinyl chloride), ABS + GB (acrylonitrile (A), butadiene (B) and styrene (S) three-monomer terpolymer mixed glass fiber), POM (polyformaldehyde), PET (polyethylene terephthalate), PBT/PPO (polybutylene terephthalate), and can be molded by machining, injection molding, extrusion and other modes; the sliding blocks 11 are in various forms, and in the embodiment, one of the cases is taken as an example, the sliding blocks 11 are placed on the lower blocking structures 134 of the battery pack binding structures 13, and then the battery packs 2 are placed on the sliding blocks 11, so that the battery packs 2 and the battery pack binding structures 13 are completely separated to avoid direct contact, and when the battery packs 2 are placed at the design positions of the battery clusters, the surface protection structures of the battery cabinets 1 and the battery packs 2 cannot be damaged in the sliding process of the battery packs 2; the slider 11 selects the non-metallic material that coefficient of friction is little, the wearability is good, the fire resistance is good, and battery package 2 exerts very little thrust on the slider and just can slide, improves the speed of battery package 2 assembly and reduces the installation degree of difficulty of battery package 2.

In addition, a reinforcing rib 14 can be further installed on the side of the battery rack opposite to the battery pack binding structure 13, and the specific structure and material of the reinforcing rib 14 are not limited in the embodiment of the application.

In the embodiment of the application, the sliding block 11 is arranged between the battery pack 2 and the battery pack binding structure 13, the battery pack 2 enters the battery cabinet 1 in a sliding mode, and in the sliding process of the battery pack 2, the battery pack 2 can slide into the battery cabinet 1 to be installed by applying very small thrust on the battery pack 2, so that the assembling speed is increased, and the installation difficulty of the battery pack 2 is reduced; in addition, as the battery pack 2 is not in contact with the battery cabinet 1, the surface protection treatment layers of the battery cabinet 1 and the battery pack 2 are intact, the structure of the battery cluster is prevented from being damaged due to rusting of structural members, the risk that the battery cluster collapses after long-term use is avoided, and the safety and the reliability of the battery cluster are improved.

The working principle is as follows:

in the process of placing the battery pack 2 into the battery cabinet 1, the stop block structure 12 is not installed, the limit bottom plate 211 is placed on the sliding block 11, the limit top plate 212 is located between the upper stop structure 132 and the sliding block 11, the battery pack 2 slides towards the interior of the battery cabinet 1 along the sliding block 11, the outer sides of the side flanges 21 abut against the side stop structures 133 on the two sides of the battery rack, the side stop structures 133 on the two sides limit the left and right deviation of the battery pack 2, the side flanges 21 are arranged between the upper stop structure 132 and the lower stop structure 134, so that the battery pack 2 cannot deviate up and down, the battery pack slides towards the interior of the battery cabinet 1 until being blocked by the rear stop structure 131, and therefore the battery pack is limited to continue sliding; after the battery pack 2 completely moves to the battery rack, the stop block structure 12 is installed, the stop block structure 12 is matched with the rear stop structure 131 to limit the front and rear directions of the battery pack 2, and the battery pack 2 cannot slide down due to the fact that the front, the rear, the left, the right, the upper and the lower are limited.

In the embodiment, because the battery pack binding structures 13 are all compactly arranged on the periphery of the bottom of the battery pack 2, the height of the battery pack 2 is only slightly increased by the limiting bottom plate 211 matched with the sliding block 11 and the lower retaining structure 134, the utilization rate of the height space of the battery cabinet 1 is extremely high, and more battery packs 2 can be accommodated under the condition that the total height of the battery cluster is not changed. Meanwhile, the stop block structure 12 is only needed to be installed after the battery pack 2 enters the battery cabinet 1, so that the battery pack 2 is prevented from sliding out, a large number of mounting bolts are not needed to fix the battery pack 2, a large amount of mounting time is saved, and the assembly speed is improved. Because battery package 2 is improved, there is the clearance between 2 bottoms of battery package and the battery frame, and the battery frame itself is the frame construction design, and the middle part is in the fretwork state, has avoided battery package 2 and the battery cabinet 1 direct contact 2 surface protection processing layer damage of battery that lead to avoided battery package 2 to rust because of damaging the structure that exposes and lead to.

An embodiment of the present application further provides a battery cluster, as shown in fig. 1 and fig. 2, a structural member in the battery cluster includes: a plurality of battery package 2 and the spacing battery cabinet 1 of battery package that this application any embodiment provided. In a possible embodiment, the battery cabinet 1 comprises: battery package restraint structure 13, battery cabinet frame 15, dog structure 12, fastening bolt 121, slider 11. The battery packs 2 are stacked in groups in the height direction of the battery clusters and are placed in the battery cabinet 1, and after the battery packs 2 are placed to set positions, the stop block structures 12 are fixed by the fastening bolts 121.

As shown in fig. 3 to 6, a plurality of battery pack binding structures 13 are arranged on the battery cabinet frame 15, the binding structures have various forms, and one of the battery pack binding structures is shown below, the cross section of the battery pack binding structure 13 is C-shaped, and a rear stop structure 131, an upper stop structure 132, a lower stop structure 134, a stop block fixing hole 122 and a side stop structure 133 are arranged on the battery pack binding structure 13; the rear blocking structure 131 is used for limiting the position of the battery pack 2 pushed into the rear end of the battery cabinet 1, the cooperation between the upper blocking structure 132 and the lower blocking structure 134 is used for limiting the position of the battery pack 2 in the vertical direction (limiting the height direction of the battery bundle), and the blocking structures 133 on two sides on the same horizontal plane on the battery rack are oppositely arranged and mutually matched for limiting the position of the battery pack 2 in the horizontal direction (limiting the position of the battery bundle in the horizontal direction).

As shown in fig. 6 and 7, the battery pack 2 is placed on the battery rack, and one side of the battery pack 2 is limited by the stopper structure 12, and the other three sides are limited by the battery pack binding structure 13. The battery pack 2 is fixedly provided with side flanges 21 at both sides, and when the battery pack 2 is placed on the battery rack, the side flanges 21 are placed between the sliding block 11 and the upper stop structure 132 and are allowed to slide relative to the sliding block 11. The side flange 21 includes: a limit bottom plate 211 and a limit top plate 212; spacing roof 212 is connected in dislocation to spacing bottom plate 211 both sides, and spacing bottom plate 211 and spacing roof 212 fixed mounting are in battery package 2 towards side fender structure 133 one side. When the battery pack 2 is placed on the battery rack, the limiting bottom plate 211 is placed on the sliding block 11 and is allowed to slide relative to the sliding block 11, and the distance from the limiting top plate 212 to the upper retaining structure 132 is smaller than the distance from the limiting bottom plate 211 to the upper retaining structure 132.

The battery pack 2 is placed at a setting position in the battery cabinet 1, the stopper structure 12 is placed at a stopper fixing hole 122 arranged on the battery pack binding structure 13 at the front end of the battery pack 2, the stopper structure 12 and the battery pack binding structure 13 are connected into a whole by using a fastening bolt 121, and the rear stopper structure 131 and the assembled stopper structure 12 are used for limiting the front-back direction limit of the battery pack 2 (the front-back direction limit of the battery bundle); the quantity of the fastening bolts 121 for connecting the stop block structure 12 and the battery pack binding structure 13 into a whole is very small, the mode that 1 fastening bolt 121 is matched with 1 stop block structure 12 can be selected, and the stop block structure 12 is designed at the front end of the battery cabinet 1, so that the space is very large, the fixing mode of the sliding block 11 is simple and rapid, and sufficient installation space is provided.

In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present application and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present application.

The foregoing description of the specific embodiments of the invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes or modifications may be made by one skilled in the art within the scope of the appended claims without departing from the essential spirit of the invention. The embodiments and features of the embodiments of the present application may be combined with each other arbitrarily without conflict.

Claims (10)

1. The utility model provides a spacing battery cabinet of battery package which characterized in that includes: a block structure (12), a battery pack binding structure (13) and a battery cabinet frame (15);

the battery cabinet is characterized in that a plurality of layers of battery frames are arranged in the battery cabinet frame (15), a stop block structure (12) is arranged on one side of each battery frame, the battery pack binding structures (13) are arranged on the other three sides of each battery frame, and the battery pack binding structures (13) are matched with the stop block structures (12) to limit the peripheral sides of the battery packs (2).

2. The battery pack-limiting battery cabinet according to claim 1, wherein the battery pack restraint structure (13) comprises: a rear baffle structure (131) and a C-shaped side baffle edge;

the rear baffle structure (131) is installed on the opposite side of the side where the battery frame is installed with the baffle structure (12), and the C-shaped side baffle side is installed on the adjacent side of the side where the battery frame is installed with the baffle structure (12).

3. The battery pack limiting battery cabinet of claim 2, wherein the C-shaped side retaining edge comprises: an upper baffle structure (132), a side baffle structure (133) and a lower baffle structure (134);

the lower retaining structure (134) is fixedly mounted on the battery frame, one side of the side retaining structure (133) is vertically connected with the lower retaining structure (134), the other side of the side retaining structure (133) is vertically connected with the upper retaining structure (132), and the cross sections of the upper retaining structure (132), the lower retaining structure (134) and the side retaining structure (133) form a C-shaped cross section.

4. The battery pack limiting battery cabinet according to claim 1, characterized in that: the battery rack is characterized in that a stop block fixing hole (122) is formed in the edge where the stop block structure (12) is installed, and the stop block structure (12) is matched with the stop block fixing hole (122) through a fastening bolt (121) and is fixedly connected with the battery rack.

5. The battery pack limiting battery cabinet according to any one of claims 1-4, wherein: also comprises a slide block (11);

the sliding block (11) is arranged on the battery pack binding structure (13) and is positioned between the battery pack binding structure (13) and the battery pack (2).

6. The battery pack limiting battery cabinet according to claim 1, characterized in that: and a reinforcing rib (14) is arranged on one side of the battery frame back to the battery pack binding structure (13).

7. A battery cluster, characterized in that, the battery pack limit battery cabinet of any one of claims 1-6 is adopted, further comprising: the battery pack (2) is placed on a battery frame of the battery pack limiting battery cabinet;

one side of the battery pack (2) is limited by the stop block structure (12), and the other three sides of the battery pack are limited by the battery pack binding structure (13).

8. A battery cluster as claimed in claim 7, wherein: the battery pack limiting battery cabinet also comprises a sliding block (11);

the sliding block (11) is arranged on the battery pack binding structure (13) and is positioned between the battery pack binding structure (13) and the battery pack (2);

side flanges (21) are fixedly arranged on two sides of the battery pack (2), and when the battery pack (2) is placed on the battery rack, the side flanges (21) are placed between the sliding block (11) and the upper blocking structure (132) and are allowed to slide relative to the sliding block (11).

9. The battery cluster according to claim 8, characterized in that the side flanges (21) comprise: a limit bottom plate (211) and a limit top plate (212);

spacing bottom plate (211) both sides dislocation connection spacing roof (212), spacing bottom plate (211) with spacing roof (212) fixed mounting is in battery package (2) orientation side fender structure (133) one side.

10. The battery pack limiting battery cabinet according to claim 9, characterized in that: the battery pack binding structure (13) includes: a rear baffle structure (131) and a C-shaped side baffle edge;

the C-shaped side flange comprises: an upper baffle structure (132), a side baffle structure (133) and a lower baffle structure (134);

when the battery pack (2) is placed on the battery rack, the limiting bottom plate (211) is placed on the sliding block (11) and is allowed to slide relative to the sliding block (11);

the distance between the limiting top plate (212) and the upper retaining structure (132) is smaller than the distance between the limiting bottom plate (211) and the upper retaining structure (132).

Images