CN112571337A - Assembly jig and assembly method for 5G power supply lightning protection module - Google Patents

Abstract

The application provides an assembly jig of a 5G power supply lightning protection module, which comprises a base and a locking assembly; a central station and four peripheral stations are limited on the base, and the four peripheral stations are sequentially arranged around the central station and are respectively used for positioning four peripheral parts; the central station comprises a plurality of first arrangement positions and a plurality of second arrangement positions, the first arrangement positions are distributed at intervals along a first direction, a second arrangement position is formed between every two adjacent first arrangement positions, the first arrangement positions are respectively used for limiting a plurality of first sheet bodies, and the second arrangement positions are respectively used for limiting a plurality of second sheet bodies; the locking assembly is used for pushing the corresponding peripheral parts so as to enable each peripheral part, the first sheet bodies and the second sheet bodies to be clamped correspondingly. A method for assembling a 5G power supply lightning protection module is characterized in that a graphite sheet, a spacer, an electrode and a support are assembled through the assembling jig. Use the equipment tool of the 5G power lightning protection module of this application, can prevent graphite flake and spacer equipment off normal, the packaging efficiency is high.

Description

Assembly jig and assembly method for 5G power supply lightning protection module

Technical Field

The application belongs to the technical field of lightning protection equipment, and particularly relates to an assembly jig of a 5G power lightning protection module and an assembly method of the assembly jig.

Background

When the lightning overvoltage, the lightning stroke electromagnetic pulse and the power supply voltage in the circuit are abnormally changed suddenly, the surge (the transient overvoltage exceeding the normal working voltage) often occurs, and the electric system and the electric equipment are damaged. The surge protector is used for suppressing surge on the line and relieving over-current on the line.

The graphite group is an important component of the surge protector and is mainly used for discharging over-current. The graphite assembly generally includes two electrodes disposed opposite to each other, two pillars disposed opposite to each other, a plurality of graphite sheets disposed in parallel between the two electrodes and the two pillars, and a spacer sheet disposed between two adjacent graphite sheets for insulating. At present, the enterprise assembles electrode, pillar, graphite flake and spacer through pure manual mode, but because the quantity of graphite flake and spacer is usually more, difficult range, easy off normal leads to two adjacent graphite flakes to switch on after the off normal easily. Meanwhile, the graphite sheet and the spacer are deviated, so that the screw is not easy to be screwed finally, and the problem of hand hitting can occur. Finally, manual assembly is time consuming and labor intensive and inefficient.

Disclosure of Invention

An object of the embodiment of this application is to provide an equipment tool of 5G power lightning protection module to solve the pure manual equipment graphite group that exists among the prior art and lead to easy off normal and waste time and energy's technical problem.

In order to achieve the purpose, the technical scheme adopted by the application is as follows: the assembly jig for the 5G power supply lightning protection module comprises a base and a locking assembly; a central station and four peripheral stations are limited on the base, and the four peripheral stations are sequentially arranged around four sides of the central station and are respectively used for positioning four peripheral parts; the central station comprises a plurality of first arrangement positions and a plurality of second arrangement positions, the first arrangement positions are distributed at intervals along a first direction, one second arrangement position is formed between every two adjacent first arrangement positions, the first arrangement positions are respectively used for limiting a plurality of first sheet bodies, and the second arrangement positions are respectively used for limiting a plurality of second sheet bodies; the locking assembly is arranged on the base and positioned beside one of the peripheral stations, and the locking assembly is used for pushing the corresponding peripheral parts along a second direction so as to enable each peripheral part, the plurality of first sheet bodies and the plurality of second sheet bodies to be correspondingly clamped along the second direction; wherein the first direction and the second direction are perpendicular to each other.

In a possible embodiment, two of said peripheral stations are spaced apart along said first direction and are intended to position two electrodes, and the other two peripheral stations are spaced apart along said second direction and are intended to position two supports; the first arrangement positions are used for positioning a plurality of graphite sheets respectively, and the second arrangement positions are used for positioning a plurality of septa respectively.

In a possible embodiment, a plurality of ribs distributed at equal intervals along the first direction are convexly arranged on the base, a groove is formed between every two adjacent ribs, the top of each rib is used for supporting the first sheet body, and the groove is used for inserting one end of the second sheet body; the distance between two adjacent convex ribs along the first direction is set to be the sum of the thicknesses of the first sheet body and the second sheet body.

In a possible embodiment, the first section of the rib is trapezoidal, and the first section of the groove is inverted trapezoidal; wherein the first cross section is parallel to the first direction and the first cross section is perpendicular to the second direction.

In a possible embodiment, the width of the bottom wall of the groove in the first direction is greater than the thickness of the second leaf.

In a possible embodiment, three baffles are arranged on the base, the areas between the three baffles and the central station are respectively used for limiting three of the peripheral members, and the area between the locking assembly and the central station is used for limiting a fourth peripheral member.

In a possible embodiment, the three baffle plates are respectively a first baffle plate, a second baffle plate and a third baffle plate, the first baffle plate and the second baffle plate are distributed at intervals along the first direction, and the third baffle plate and the locking assembly are respectively arranged on two sides of the central station along the second direction;

the first baffle or the second baffle is provided with a positioning groove for positioning the peripheral part;

or a positioning bulge used for positioning the peripheral part is arranged on the first baffle plate or the second baffle plate.

In a possible embodiment, the locking assembly comprises a locking member mounted on the base and a pushing member connected with the locking member and used for pushing the peripheral member under the driving of the locking member; the base is provided with a guide part extending along the second direction, and the pushing part slides along the guide part.

In a possible embodiment, the pusher comprises a sliding plate connected to the retaining member and a plurality of feet mounted on the sliding plate for abutment with the peripheral member.

In a possible embodiment, the locking member is a snap-action clamp.

The application provides an equipment tool of 5G power lightning protection module's beneficial effect lies in: the utility model provides an equipment tool of 5G power lightning protection module, setting through base and locking Assembly, and set up central station and four peripheral stations on the base, and central station includes a plurality of first ranks position and a plurality of second ranks position that set up along first direction interval in proper order, thereby make when packing into a plurality of first ranks position with a plurality of first lamellar bodies one-to-one, and pack into a plurality of second lamellar bodies one-to-one after in a plurality of second ranks position, in addition four peripheral stations are to the spacing of four peripheral parts, thereby make a plurality of first lamellar bodies and a plurality of second lamellar bodies all fix a position accurately along first direction and second direction, can not produce the off normal phenomenon, if establish first lamellar body into the graphite flake, establish the second lamellar body into the spacer, then can not produce the short circuit phenomenon because of the off normal between two adjacent graphite flakes. Meanwhile, the first sheet body, the second sheet body and the peripheral pieces cannot deviate, so that screw holes in the four peripheral pieces cannot deviate, screw driving is facilitated, and screw driving through electric screwdriver cannot be dangerous. In addition, this application need not to assemble through manual to the packaging efficiency and the equipment precision of graphite flake, spacer, electrode and pillar have been improved.

The application also provides an assembling method of the 5G power lightning protection module, the 5G power lightning protection module is assembled by using the assembling jig, and the assembling method comprises the following steps:

sequentially loading the three peripheral parts into three peripheral stations;

stacking a plurality of first sheet bodies and a plurality of second sheet bodies at intervals in sequence;

sequentially inserting the arranged first sheet bodies and the second sheet bodies into the corresponding first arrangement positions and second arrangement positions;

placing a fourth enclosure on a fourth enclosure station;

pushing the fourth peripheral part through the locking assembly to enable two ends of the first sheet bodies and two ends of the second sheet bodies to be respectively inserted into the two peripheral parts along the second direction;

the corresponding peripheral member is locked by the fastener.

The application provides a 5G power lightning protection module's assembly method's beneficial effect lies in: according to the assembling method provided by the embodiment of the application, the assembling jig of the 5G power supply lightning protection module is used for assembling the graphite flakes, the spacers, the two electrodes and the two support columns, so that the graphite flakes are prevented from being conducted due to assembling deviation, and the assembling efficiency and the assembling precision of the whole graphite group are improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

Fig. 1 is a schematic perspective view illustrating an assembled fixture of a 5G power lightning protection module and a graphite assembly according to an embodiment of the present application after assembly;

fig. 2 is a schematic top view of an assembly jig of the 5G power lightning protection module in fig. 1;

FIG. 3 is a schematic assembly view of the graphite assembly of FIG. 1;

FIG. 4 is an exploded view of the graphite assembly of FIG. 3;

fig. 5 is a schematic cross-sectional view of an assembly jig and a graphite assembly of the 5G power lightning protection module in fig. 1 along a first cross-section;

FIG. 6 is an enlarged view of a portion of area A of FIG. 5;

fig. 7 is a schematic cross-sectional view of an assembly jig and a graphite assembly of the 5G power lightning protection module in fig. 1 along a second cross-section;

fig. 8 is a schematic view illustrating a state of the assembly jig of the 5G power lightning protection module according to the embodiment of the present application after being installed in the front electrode;

FIG. 9 is a schematic view of the left side column of FIG. 8 after being installed;

fig. 10 is a schematic view of the rear pillar after being installed in fig. 9.

Wherein, in the figures, the respective reference numerals:

10. a base; 11. a central station; 111. a first rank bit; 1111. a rib is protruded; 112. a second arrangement position; 1121. a groove; 12. peripheral stations; 13. a first baffle plate; 14. a second baffle; 141. positioning a groove; 15. a third baffle plate; 16. a guide portion; 20. a locking assembly; 21. a locking member; 211. a push rod; 22. a pusher member; 221. a slide plate; 222. supporting feet; 23. a bolt; 30. a graphite group; 31. a graphite sheet; 32. a spacer; 33. an electrode; 331. positioning the projection; 34. a pillar; 341. a first slot; 342. a second slot; x, a first direction; y, second direction.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, as used herein, refer to an orientation or positional relationship indicated in the drawings that is solely for the purpose of facilitating the description and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be considered as limiting the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1 to 4, an assembly fixture of a 5G power lightning protection module according to an embodiment of the present application will be described. This equipment tool of 5G power lightning protection module mainly used assembles graphite group 30, specifically assemble graphite group 30 among the board-mounted little type big through-flow lightning protection module of 5G power, graphite group 30 mainly includes a plurality of graphite flakes 31, a plurality of septa 32, two electrodes 33 and two pillars 34, a plurality of graphite flakes 31 are along first direction X interval distribution, a plurality of septa 32 fill up in proper order along first direction X and locate between two adjacent graphite flakes 31, two electrodes 33 set up along first direction X interval, two pillars 34 set up along second direction Y interval, first direction X and second direction Y mutually perpendicular, and first direction X specifically is the fore-and-aft direction in figure 3, second direction Y specifically is the left and right directions in figure 3. One of the support posts 34 has a circuit board, the two support posts 34 are provided with a plurality of first slots 341 and a plurality of second slots 342, two ends of each graphite sheet 31 are respectively inserted into the corresponding first slots 341 of the two support posts 34, and two ends of each spacer 32 are respectively inserted into the corresponding second slots 342 of the two support posts 34. Both ends of the electrode 33 positioned on the rear side abut against the rear sides of the two support columns 34, respectively, and both ends of the electrode 33 positioned on the front side abut against the front sides of the two support columns 34, respectively. After the two electrodes 33, the two support columns 34, the graphite sheets 31 and the spacers 32 are assembled as shown in fig. 3, the electrodes 33 and the support columns 34 are locked at corresponding positions by screws, thereby assembling the graphite assembly 30.

In the present embodiment, the first sheet member is a graphite sheet 31, the second sheet member is a separator 32, and the four peripheral sheets are two electrodes 33 and two support columns 34. In other embodiments of the present application, the following first sheet may also be in any other sheet structure, the following second sheet may also be in any other sheet structure, and the four peripheral members may also be in any other peripheral structure that needs to be assembled with the first sheet and the second sheet, which is not limited herein.

Referring to fig. 1 and 2, an assembly fixture of a 5G power lightning protection module includes a base 10 and a locking assembly 20. A central station 11 and four peripheral stations 12 are defined on the base 10, the central station 11 is rectangular, the four peripheral stations 12 are sequentially arranged on four sides of the central station 11 in a surrounding manner, and the four peripheral stations 12 are respectively used for positioning four peripheral parts. The central station 11 includes a plurality of first arrangement positions 111 and a plurality of second arrangement positions 112, the plurality of first arrangement positions 111 are sequentially distributed at intervals along the first direction X, the plurality of second arrangement positions 112 are sequentially distributed at intervals along the first direction X, a second arrangement position 112 is formed between every two adjacent first arrangement positions 111, that is, each first arrangement position 111 and each second arrangement position 112 are sequentially staggered along the first direction X, the plurality of first arrangement positions 111 are respectively used for defining a plurality of first sheet bodies, and the plurality of second arrangement positions 112 are respectively used for defining a plurality of second sheet bodies. The locking assembly 20 is disposed on the base 10 and located beside one of the peripheral stations 12, the locking assembly 20 is specifically disposed beside the peripheral station 12 of the pillar 34 with the circuit board, and the locking assembly 20 is configured to push the corresponding peripheral component along the second direction Y to enable each peripheral component, the plurality of first sheet bodies and the plurality of second sheet bodies to be clamped correspondingly.

Referring to fig. 2, two peripheral stations 12 are spaced apart along a first direction X and are used for positioning two electrodes 33, the other two peripheral stations 12 are spaced apart along a second direction Y and are used for positioning two pillars 34, the central station 11 is disposed in the middle of each peripheral station 12, the first alignment positions 111 are used for positioning a plurality of graphite sheets 31, and the second alignment positions 112 are used for positioning a plurality of spacers 32.

Referring to fig. 8 to 10, when the assembly jig of the 5G power lightning protection module is used, a first peripheral component is first installed in the peripheral station 12 located at the front side, a second peripheral component is then installed in the peripheral station 12 located at the left side, and a third peripheral component is then installed in the peripheral station 12 located at the rear side, wherein the three peripheral components are mutually limited; then, a plurality of first sheet bodies and a plurality of second sheet bodies are sequentially overlapped at intervals, specifically, one second sheet body is inserted between every two adjacent first sheet bodies, then the sheet body assemblies are arranged in the central station 11 together, each first sheet body is correspondingly arranged on each first arrangement position 111, each second sheet body is correspondingly arranged on each second arrangement position 112, at the moment, each first sheet body and each second sheet body form a splicing relation with a second peripheral part along the second direction Y, and therefore the positioning accuracy of each first sheet body and each second sheet body along the first direction X is ensured; and finally, the fourth peripheral part is arranged in the peripheral station 12 on the right side, the locking assembly 20 is driven, the locking assembly 20 pushes the fourth peripheral part along the second direction Y, so that the first sheet bodies and the second sheet bodies form a splicing relation with the fourth peripheral part along the second direction Y, the peripheral parts, the first sheet bodies and the second sheet bodies are mutually clamped along the second direction Y, and the four peripheral parts are locked by fastening pieces outside, so that the assembly of the peripheral parts, the first sheet bodies and the second sheet bodies is completed.

The assembly jig of the 5G power supply lightning protection module in this embodiment is provided with the base 10 and the locking component 20, a central station 11 and four peripheral stations 12 are arranged on the base 10, and the central station 11 comprises a plurality of first arrangement positions 111 and a plurality of second arrangement positions 112 which are arranged at intervals along the first direction X, so that when the first sheets are correspondingly arranged in the first arrangement positions 111 one by one and the second sheets are correspondingly arranged in the second arrangement positions 112 one by one, the limitation of the four peripheral parts by the four peripheral stations 12 is added, thereby positioning the first sheet bodies and the second sheet bodies accurately along the first direction X and the second direction Y without generating deviation, if the first sheet is made of graphite sheet 31 and the second sheet is made of graphite sheet 32, the conductive short-circuit phenomenon between two adjacent graphite sheets 31 due to misalignment does not occur. Meanwhile, the first sheet body, the second sheet body and the peripheral pieces cannot deviate, so that screw holes in the four peripheral pieces cannot deviate, screw driving is facilitated, and screw driving through electric screwdriver cannot be dangerous. In addition, according to the present invention, the assembly efficiency and the assembly accuracy of the graphite sheet 31, the spacer 32, the electrode 33, and the support column 34 are improved without manual assembly.

In an embodiment, referring to fig. 5 and fig. 6, a plurality of ribs 1111 are protruded from the base 10 at equal intervals along the first direction X, each rib 1111 extends along the second direction Y, and the structure of each rib 1111 is the same. Grooves 1121 are formed between two adjacent ribs 1111, the grooves 1121 are arranged at equal intervals along the first direction X, and the grooves 1121 extend along the second direction Y. The rib 1111 is flush at the top and is used to support the first blade, and the groove 1121 is used to insert one end of the second blade. The distance between two adjacent ribs 1111 along the first direction X is set to be the sum of the thicknesses of one first sheet and one second sheet, and the distance between two adjacent grooves 1121 along the first direction X is set to be the sum of the thicknesses of one first sheet and one second sheet.

It should be noted here that the spacer 32 is inserted between the graphite sheets 31, for the purpose of preventing the adjacent two graphite sheets 31 from contacting and conducting, therefore, the external dimension of the spacer 32 is larger than that of the graphite sheet 31, that is, the length of the spacer 32 is larger than that of the graphite sheet 31, and the width of the spacer 32 is larger than that of the graphite sheet 31, so that the assembly of the graphite sheet 31 and the spacer 32 is just suitable by the arrangement of the ribs 1111 and the grooves 1121. During specific installation, the graphite sheets 31 and the spacers 32 are sequentially overlapped at intervals to form a sheet set, then the sheet set is integrally clamped to the central station 11 by hands, the spacers 32 are inserted into the grooves 1121 in a one-to-one correspondence manner, the bottom surfaces of the spacers 32 are abutted to the bottom walls of the grooves 1121, and the bottom surfaces of the graphite sheets 31 are supported on the top surfaces of the ribs 1111 in a one-to-one correspondence manner. In addition, since the positioning of the two electrodes 33 is completed and the interval between the two electrodes 33 along the first direction X is just equal to the sum of the thicknesses of the graphite sheets 31 and the spacers 32, when the graphite sheets 31 and the spacers 32 are correspondingly assembled into the ribs 1111 and the grooves 1121, the positioning of the graphite sheets 31 and the spacers 32 along the first direction X is completed and no misalignment occurs. Finally, because two pillars 34 and graphite flake 31 and spacer 32 all form the grafting along second direction Y, consequently, after locking assembly 20 promoted pillar 34 locking on right side, location has also been accomplished along second direction Y to a plurality of graphite flakes 31 and a plurality of spacer 32, and the top surface of protruding muscle 1111 and the spacing of the diapire of recess 1121 in addition can realize a plurality of graphite flakes 31 and a plurality of spacer 32 along the ascending location of vertical direction, and then prevent that graphite flake 31 and spacer 32 from producing the translocation phenomenon.

In a specific embodiment, referring to fig. 6, the first cross section of the rib 1111 is a trapezoid, and the first cross section of the groove 1121 is an inverted trapezoid, where the inverted trapezoid is a trapezoid with a large top and a small bottom; the first section is parallel to the first direction X, and the first section is perpendicular to the second direction Y. As can be seen from fig. 6, when the ribs 1111 have a trapezoidal shape, the contact surface between the graphite sheet 31 and the ribs 1111 is reduced, thereby reducing the abrasion between the graphite sheet 31 and the ribs 1111; when the recess 1121 is in the shape of an inverted trapezoid, the width of the recess 1121 in the first direction X gradually increases from bottom to top, so that two side surfaces of the spacer 32 do not contact with two side walls of the recess 1121, thereby reducing contact wear between the spacer 32 and the recess 1121, and facilitating guiding the spacer 32 to be rapidly inserted into the recess 1121, thereby improving assembly efficiency. It is understood that in other embodiments of the present application, the first cross section of the rib 1111 may be formed by a plurality of arc lines, and the first cross section of the groove 1121 may be formed by a plurality of arc lines, which are not limited herein.

Preferably, the first cross section of the rib 1111 is an isosceles trapezoid, and the first cross section of the groove 1121 is an inverted isosceles trapezoid, so that the rib 1111 and the groove 1121 are symmetrically arranged along the first direction X, thereby facilitating the assembly of the graphite sheet 31 and the spacer 32.

In a specific embodiment, referring to fig. 6, after the width of the bottom wall of the groove 1121 along the first direction X is greater than the thickness of the second sheet, that is, after the second sheet is inserted into the groove 1121, the second sheet can be properly moved in the groove 1121 along the first direction X to adjust the position, so that when there is an error in the thickness process of the first sheet and the second sheet along the first direction X, or there is an error in the process of the rib 1111 and the groove 1121 along the first direction X, or there is a process error in two peripheral stations 12 along the first direction X, the adjustment can be performed by moving each second sheet along the first direction X. It is understood that, in other embodiments of the present application, the width of the bottom wall of the groove 1121 in the first direction X may also be set to be equal to the back degree of the second sheet, which is not limited herein.

In a specific embodiment, referring to fig. 2, 7 to 10, three baffles are disposed on the base 10, the areas between the three baffles and the central station 11 are respectively used for defining three peripheral members, and the area between the locking assembly 20 and the central station 11 is used for defining a fourth peripheral member. Specifically, the surface of base 10 is parallel and level, and when three peripheral parts were located base 10 respectively, three baffle was used for spacing three peripheral parts respectively, prevented that three peripheral part from moving to the direction of keeping away from central station 11. This application comes to carry on spacingly to three peripheral through the baffle, its simple structure, and the preparation is convenient, and can not produce the damage to peripheral. It is understood that in other embodiments of the present application, the four peripheral members may be limited in other manners, such as a limiting groove or a plurality of positioning pillars, which are not limited herein.

In a specific embodiment, the three baffles are a first baffle 13, a second baffle 14 and a third baffle 15, respectively, the first baffle 13 and the second baffle 14 are distributed at intervals along the first direction X, and the third baffle 15 and the locking assembly 20 are respectively arranged on two sides of the central station 11 along the second direction Y; wherein, the first baffle 13 or the second baffle 14 is provided with a positioning groove 141 for positioning the peripheral component. In practical applications, the first baffle 13 is used for limiting the electrode 33 at the rear side, the second baffle 14 is used for limiting the electrode 33 at the front side, the third baffle 15 is used for limiting the pillar 34 at the left side, and the locking assembly 20 is used for pushing the pillar 34 at the right side. The second baffle 14 is provided with a positioning groove 141, the electrode 33 located at the front side is provided with a positioning protrusion 331, and the positioning protrusion 331 is in concave-convex fit with the positioning groove 141. In the specific installation, the electrode 33 located on the front side may be first mounted on the base 10, the electrode 33 may be first limited in the first direction X and the second direction Y by the second barrier 14, the pillar 34 located on the left side may be mounted on the base 10, the pillar 34 may be limited in the first direction X and the second direction Y by the third barrier 15 and the electrode 33 located on the front side, the electrode 33 located on the rear side may be mounted on the base 10, and the electrode 33 may be limited in the first direction X and the second direction Y by the pillar 34 located on the left side and the first barrier 13. It can be seen that the positioning grooves 141 of the second shutter 14 allow the two electrodes 33 and the one support column 34 to be positioned. It is understood that, in other embodiments of the present application, the positioning groove 141 may be disposed on the first barrier 13 in the order of mounting from the electrode 33 on the first barrier 13, and the positioning protrusion 331 may be disposed on the first barrier 13 and the second barrier 14, and the positioning groove 141 may be disposed on the electrode 33, which is not limited herein.

In a specific embodiment, referring to fig. 1 and 7, the locking assembly 20 includes a locking member 21 and a pushing member 22, the locking member 21 is mounted on the base 10, the pushing member 22 is connected to the locking member 21, and the pushing member 22 is used for pushing the peripheral member along the second direction Y under the driving of the locking member 21; the base 10 is provided with a guide portion 16 extending in the second direction Y, and the pushing member 22 slides along the guide portion 16. In operation, when the right-hand column 34 is loaded onto the base 10, the pusher 22 is driven by the locking member 21, and the pusher 22 slides along the guide 16, thereby pushing the column 34 to slide in the second direction Y to engage with each of the graphite sheets 31 and the spacer 32.

In an embodiment, referring to fig. 1, the pushing member 22 includes a sliding plate 221 and a plurality of supporting legs 222, the sliding plate 221 is connected to the locking member 21, and the plurality of supporting legs 222 are mounted on the sliding plate 221 and are used for abutting against the peripheral member. In operation, the sliding plate 221 slides along the guide portion 16, and the plurality of legs 222 abut against the pillars 34 respectively to push the pillars 34. According to the application, the plurality of top legs 222 are arranged, so that the top legs 222 and the lines on the support column 34 can be staggered, and the top legs 222 are prevented from damaging the lines. The number and position of the top legs 222 may be designed according to the specific structure of the pillar 34, and are not limited herein.

Referring to fig. 7, the guiding portion 16 is a guiding groove formed on the base 10, and the pushing member 22 is guided by the guiding groove in a sliding manner, so that the structure is simple, the processing is convenient, the weight of the base 10 can be reduced, and the carrying of the assembly jig of the 5G power lightning protection module are convenient.

In a specific embodiment, referring to fig. 1, 7 to 10, the locking member 21 is a quick clamp, the quick clamp utilizes the lever principle to realize the linear movement of the push rod 211, the operation is simple, only the handle needs to be manually swung, the labor is saved, and the operation is convenient. It should be understood that in other embodiments of the present application, the locking member 21 may also be a ball screw mechanism or a linear cylinder mechanism, etc., according to the actual design and specific requirements, and is not limited herein.

Referring to fig. 7, the sliding plate 221 and the push rod 211 are locked by the bolt 23.

The application also provides an assembling method of the 5G power lightning protection module, which is to use the assembling jig of the 5G power lightning protection module to assemble, please refer to fig. 1, 8 to 10, and includes the following steps:

sequentially loading three peripheral parts into three peripheral stations 12;

specifically, the electrode 33 located on the front side is first mounted on the base 10, the electrode 33 is limited in the first direction X and the second direction Y by the second shutter 14, the pillar 34 located on the left side is then mounted on the base 10, the pillar 34 is limited in the first direction X and the second direction Y by the third shutter 15 and the electrode 33 located on the front side, the electrode 33 located on the rear side is mounted on the base 10, and the electrode 33 is limited in the first direction X and the second direction Y by the pillar 34 located on the left side and the first shutter 13.

Stacking a plurality of first sheet bodies and a plurality of second sheet bodies at intervals in sequence;

specifically, a plurality of graphite sheets 31 and a plurality of separators 32 are sequentially stacked at intervals in the first direction X.

Sequentially inserting the arranged first sheet bodies and the second sheet bodies into the corresponding first arrangement positions 111 and second arrangement positions 112;

specifically, a sheet set formed by arranging a plurality of graphite sheets 31 and a plurality of spacers 32 is clamped to the central station 11, and the respective spacers 32 are inserted into the respective recesses 1121 in a one-to-one correspondence manner, so that the respective graphite sheets 31 are abutted against the top surfaces of the respective ribs 1111 in a one-to-one correspondence manner.

Placing a fourth enclosure on a fourth enclosure station 12;

specifically, the right-side support column 34 is placed at the right-side peripheral station 12, and the graphite sheets 31 and the partition sheets 32 have ends which are inserted into the right-side support column 34.

Pushing the fourth peripheral member by the locking assembly 20 to insert the two ends of the plurality of first sheet bodies and the two ends of the plurality of second sheet bodies into the two peripheral members, respectively;

specifically, the handle of the locking member 21 is swung to drive the sliding plate 221 to slide along the second direction Y, and push the right pillar 34 to move to the left, so that the left pillar 34, the graphite sheets 31, the spacers 32, and the right pillar 34 are correspondingly abutted along the second direction Y.

The corresponding peripheral member is locked by the fastener.

Specifically, the graphite assembly 30 is assembled by locking both ends of the two electrodes 33 with the two pillars 34 by screws, respectively.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. An assembly jig for a 5G power supply lightning protection module is characterized by comprising a base and a locking assembly; a central station and four peripheral stations are limited on the base, and the four peripheral stations are sequentially arranged around four sides of the central station and are respectively used for positioning four peripheral parts; the central station comprises a plurality of first arrangement positions and a plurality of second arrangement positions, the first arrangement positions are distributed at intervals along a first direction, one second arrangement position is formed between every two adjacent first arrangement positions, the first arrangement positions are respectively used for limiting a plurality of first sheet bodies, and the second arrangement positions are respectively used for limiting a plurality of second sheet bodies; the locking assembly is arranged on the base and positioned beside one of the peripheral stations, and the locking assembly is used for pushing the corresponding peripheral parts along a second direction so as to enable each peripheral part, the plurality of first sheet bodies and the plurality of second sheet bodies to be correspondingly clamped along the second direction; wherein the first direction and the second direction are perpendicular to each other.

2. The assembly fixture for the 5G power lightning protection module according to claim 1, wherein two of the peripheral stations are spaced apart along the first direction and are used for positioning two electrodes, and the other two peripheral stations are spaced apart along the second direction and are used for positioning two pillars; the first arrangement positions are used for positioning a plurality of graphite sheets respectively, and the second arrangement positions are used for positioning a plurality of septa respectively.

3. The assembly jig for the 5G power supply lightning protection module according to claim 1, wherein a plurality of ribs are convexly arranged on the base and are distributed at equal intervals along the first direction, a groove is formed between every two adjacent ribs, the top of each rib is used for supporting the first sheet body, and the groove is used for inserting one end of the second sheet body; the distance between two adjacent convex ribs along the first direction is set to be the sum of the thicknesses of the first sheet body and the second sheet body.

4. The assembly jig for the 5G power lightning protection module according to claim 3, wherein the first cross section of the rib is trapezoidal, and the first cross section of the groove is inverted trapezoidal; wherein the first cross section is parallel to the first direction and the first cross section is perpendicular to the second direction.

5. The assembly fixture of the 5G power lightning protection module of claim 4, wherein the width of the bottom wall of the groove along the first direction is greater than the thickness of the second sheet.

6. The assembly jig for the 5G power lightning protection module according to any one of claims 1 to 5, wherein three baffles are disposed on the base, the areas between the three baffles and the central station are respectively used for defining three of the peripheral members, and the area between the locking assembly and the central station is used for defining a fourth peripheral member.

7. The assembly jig for the 5G power supply lightning protection module according to any one of claims 1 to 5, wherein the locking assembly comprises a locking member mounted on the base and a pushing member connected with the locking member and used for pushing the peripheral member under the driving of the locking member; the base is provided with a guide part extending along the second direction, and the pushing part slides along the guide part.

8. The assembly fixture of a 5G power lightning protection module according to claim 7, wherein the pushing member includes a sliding plate connected to the locking member and a plurality of top legs mounted on the sliding plate for abutting against the peripheral member.

9. The tool of claim 7, wherein the locking member is a quick clamp.

The method for assembling the 5G power lightning protection module is characterized by comprising the following steps of:

sequentially loading the three peripheral parts into three peripheral stations;

stacking a plurality of first sheet bodies and a plurality of second sheet bodies at intervals in sequence;

sequentially inserting the arranged first sheet bodies and the second sheet bodies into the corresponding first arrangement positions and second arrangement positions;

placing a fourth enclosure on a fourth enclosure station;

pushing the fourth peripheral part through the locking assembly to enable two ends of the first sheet bodies and two ends of the second sheet bodies to be respectively inserted into the two peripheral parts along the second direction;

the corresponding peripheral member is locked by the fastener.

Images