CN219801149U - Battery mounting assembly and electronic equipment - Google Patents

Abstract

The utility model discloses a battery mounting assembly, which comprises an upper sliding block, a lower sliding block and an elastic piece, wherein the upper sliding block and the lower sliding block are in sliding connection, the upper end of the upper sliding block is provided with a first clamping groove, and the lower end of the lower sliding block is provided with a second clamping groove which is consistent with the extending direction of the first clamping groove; the elastic piece is arranged between the upper sliding block and the lower sliding block, the upper sliding block and the lower sliding block can be clamped into the sliding groove on the battery after being pressed to move oppositely, and can slide along the sliding groove to adjust the position until the position of the elastic piece corresponds to a locking position on the shell, and after the upper sliding block and the lower sliding block are released, the upper sliding block and the lower sliding block are reset under the action of elastic force and are abutted against the sliding groove to realize positioning. According to the utility model, the battery mounting assembly with the adjustable position is used for replacing the locking lug in the prior art, so that different electronic equipment can be compatible with a shared battery, the cost waste caused by repeated design and die opening of the shared battery is avoided, and the manufacturing cost is reduced. The utility model also discloses electronic equipment.

Description

Battery mounting assembly and electronic equipment

Technical Field

The present utility model relates to the field of electronic devices, and in particular, to a battery mounting assembly compatible with battery mounting of various specifications and an electronic device.

Background

Referring to fig. 1, in a conventional mounting method of a battery 100 ' used in an electronic device, a locking lug 110 ' is generally disposed on a housing of the battery 100 ', a position dedicated for mounting the battery 100 ' is reserved on a housing 200 ' of the electronic device, and a fixing structure for connecting the locking lug is disposed at the position.

However, with the rapid development of consumer electronics, it is often impossible to use the same battery between electronic devices produced by different manufacturers or between updated electronic devices and old electronic devices. For example, due to the difference in configuration between different manufacturers, the arrangement of the locking lugs 110 'of the battery 100' is different from the arrangement of the fixing structure on the housing, or some newly-pushed electronic devices are adjusted due to the battery mounting positions thereof, so that the positions of the locking lugs of the old battery are not matched with the fixing structure of the new electronic device. Therefore, the battery 100 ' may interfere with the component 210 ' on the case 200 ' during installation, and thus, the battery 100 ' may not be installed (see fig. 1), so that the battery 100 ' may not be compatible for use between different electronic devices. Therefore, the battery needs to be redesigned to change the position of the locking lug, and the mold opening production needs to be restarted, so that high design and mold cost are caused, waste is caused, and the cost is increased.

Accordingly, it is necessary to provide a battery mounting assembly and an electronic device that are compatible with battery mounting of various specifications to solve the above problems.

Disclosure of Invention

The utility model aims to provide a battery mounting assembly which can be compatible with battery mounting of various specifications.

Another object of the present utility model is to provide an electronic device compatible with battery installations of various specifications.

In order to achieve the above purpose, the technical scheme of the utility model is as follows: providing a battery mounting assembly, which comprises an upper sliding block, a lower sliding block and an elastic piece; the upper end face of the upper sliding block is provided with a first clamping groove penetrating through the two transverse ends of the upper sliding block, and the lower end face of the upper sliding block is convexly provided with a first positioning column; the upper end of the lower sliding block is provided with a positioning hole extending along the thickness direction of the lower sliding block, and the lower end surface of the lower sliding block is provided with a second clamping groove penetrating through the two transverse ends of the lower sliding block; the upper sliding block is connected in the positioning hole in a sliding way through the first positioning column, and enables the first clamping groove and the second clamping groove to be opposite up and down and have the same extending direction; the elastic piece is arranged between the upper sliding block and the lower sliding block, the upper sliding block and the lower sliding block can deform when being stressed and move in opposite directions, and the upper sliding block and the lower sliding block can move away under the action of the elastic force of the elastic piece when the force of the upper sliding block and the force of the lower sliding block are lost.

Preferably, the upper end face of the lower slider is further provided with a second positioning column in a protruding mode, and the elastic piece is sleeved outside the second positioning column.

Preferably, the second positioning column is arranged in the middle of the lower slider, and the positioning hole is arranged around the second positioning column.

Preferably, the lower slider is further provided with a connecting hole extending along the thickness direction thereof in a penetrating manner, and the connecting hole is used for being connected with the locking part.

Preferably, the first positioning column is cylindrical, square or/and rectangular, and the shape of the positioning hole corresponds to the shape of the first positioning column.

Correspondingly, the utility model also provides electronic equipment, which comprises a shell, an electromagnetic and the battery mounting assembly; the shell is provided with a locking part, and one side wall of the battery is provided with a chute penetrating through two ends of the side wall; the upper sliding block and the lower sliding block of the battery installation assembly are provided with a first position close to each other and a second position far away from each other, when the upper sliding block and the lower sliding block are stressed to move to the first position, the upper sliding block and the lower sliding block can be slidably clamped into the sliding groove from the end part of the battery and can slide along the sliding groove, and when the upper sliding block and the lower sliding block lose force, the upper sliding block and the lower sliding block can move to the second position under the action of the elastic force of the elastic piece and abut against the sliding groove, and the lower sliding block can be detachably connected to the locking part.

Preferably, an upper clamping block protruding downwards is arranged on the upper wall of the sliding groove, a lower clamping block protruding downwards towards the upper clamping block is arranged on the lower wall of the sliding groove, and after the upper sliding block is clamped into the sliding groove, the upper clamping block is clamped into the first clamping groove, and the lower clamping block is clamped into the second clamping groove.

Preferably, the width of the upper clamping block corresponds to the width of the first clamping groove, or/and the width of the lower clamping block corresponds to the width of the second clamping groove.

Preferably, a positioning groove is concavely formed in the upper wall or/and the lower wall of the sliding groove, and the upper sliding block and the lower sliding block are clamped into the positioning groove to be positioned when moving to the second position after losing force.

Preferably, the lower slider is further provided with a connecting hole extending along the thickness direction thereof in a penetrating manner, and the locking piece penetrates through the connecting hole and is locked at the locking part to fix the battery.

Compared with the prior art, the battery mounting assembly is provided with the upper slider, the lower slider and the elastic piece arranged between the upper slider and the lower slider in a sliding connection manner, the upper end face of the upper slider is provided with the first clamping groove penetrating through the two transverse ends of the upper slider, and the lower end face of the lower slider is provided with the second clamping groove consistent with the extending direction of the first clamping groove 111, so that after the upper slider and the lower slider are forced to move oppositely, the upper slider and the lower slider can slide into the sliding groove on the battery from the end part of the battery and slide along the sliding groove, the battery mounting assembly slides along the battery to adjust the position of the battery until the battery mounting assembly corresponds to the locking position on the shell, at the moment, the force applied to the upper slider and the lower slider is removed, the upper slider and the lower slider can move in opposite directions under the action of the elastic force of the elastic piece and abut against the sliding groove, the positioning of the battery mounting assembly is realized, and the lower slider is connected to the locking position on the shell to realize the mounting of the battery. According to the utility model, the position of the battery mounting assembly can be adjusted according to the positions of different locking parts on the shell, firstly, the battery mounting assembly is simple and flexible to move and adjust, more convenient to use, and secondly, the compatibility is strong, so that different electronic equipment can be compatible with a shared battery, the cost waste caused by repeated design and die opening of the shared battery is avoided, and the manufacturing cost is reduced.

Correspondingly, the electronic equipment with the battery mounting assembly has the same technical effects.

Drawings

Fig. 1 is a schematic view of a structure of a battery installation in the related art.

Fig. 2 is a schematic structural view of the battery mounting assembly of the present utility model.

Fig. 3 is an exploded view of fig. 2.

Fig. 4 is a schematic structural view of the lower slider in fig. 3.

Fig. 5 is a schematic view showing a state in which the battery mounting assembly of the present utility model is in a first position.

Fig. 6 is a schematic view showing a state in which the battery mounting assembly of the present utility model is in the second position.

Fig. 7 is a schematic view showing a state in which the battery mounting assembly of the present utility model is attached to a battery.

Fig. 8 is an enlarged partial schematic view of fig. 7.

Fig. 9 is a schematic view of the battery mounting assembly of fig. 8 in a first position.

Fig. 10 is a schematic view of the battery mounting assembly of fig. 8 in a second position.

Detailed Description

Embodiments of the present utility model will now be described with reference to the drawings, wherein like reference numerals represent like elements throughout. It should be noted that, the description of the azimuth direction, such as the azimuth or the positional relationship indicated by the upper, lower, left, right, front, rear, etc. related to the present utility model is based on the azimuth or the positional relationship shown in the drawings, only for convenience of describing the technical solution of the present utility model and/or simplifying the description, and does not indicate or imply that the device or element referred to must have a specific azimuth, be configured and operated in a specific azimuth, and therefore should not be construed as limiting the present utility model. First, second, etc. are described solely for distinguishing between technical features and should not be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of technical features indicated.

Referring to fig. 2-10, the battery mounting assembly 100 according to the present utility model is used for connecting a battery 200 to a housing of an electronic device 1. The battery 200 of the present utility model includes, but is not limited to, a cell phone battery, a PC computer battery, a server battery, an automobile battery, an earphone battery, a VR battery, and the like.

Referring first to fig. 2 to 8, the battery mounting assembly 100 of the present utility model includes an upper slider 110, a lower slider 120, and an elastic member 130. The upper end surface of the upper slider 110 is provided with a first engaging groove 111 penetrating through two lateral ends thereof, and the lower end surface thereof is convexly provided with a first positioning column 112. The lower end surface of the lower slider 120 is provided with a second engaging groove 121 penetrating through two lateral ends thereof, the upper end of the lower slider is provided with a positioning hole 122 extending along the thickness direction thereof, and the shape of the positioning hole 122 corresponds to the shape of the first positioning column 112. The upper slider 110 is slidably connected to the positioning hole 122 through the first positioning column 112, and the first engaging groove 111 and the second engaging groove 121 are vertically opposite and have the same extending direction. The elastic member 130 is mounted between the upper slider 110 and the lower slider 120, when the upper slider 110 and the lower slider 120 are forced to move, the elastic member 130 is extruded to deform, and when the upper slider 110 and the lower slider 120 lose force, the elastic member 130 moves away from the upper slider.

In the present utility model, the elastic member 130 is preferably an elastic silica gel, but not limited thereto, and other elastic members may be selected.

Referring to fig. 3-4, a second positioning column 123 is further protruding from the upper end surface of the lower slider 120, and the elastic member 130 is sleeved outside the second positioning column 123, so as to position the elastic member 130. More specifically, the second positioning post 123 is disposed at a substantially middle portion of the lower slider 120, and the positioning hole 122 is disposed around the second positioning post 123, so that the elastic member 130 is more balanced in stress when driving the upper slider 110 and the lower slider 120. Of course, the second positioning post 123 and the positioning hole 122 are not limited to the arrangement in the present embodiment.

With continued reference to fig. 3 to 4, in the present utility model, the lower slider 120 is further provided with a connection hole 124 extending along the thickness direction thereof, the connection hole 124 is provided at one end far from the second positioning post 123, and the connection hole 124 is used for fixing the lower slider 120 to the mounting portion, so as to fix the battery mounting assembly 100.

In an embodiment of the utility model, as shown in fig. 2-3, the upper slider 110 has a plate-like structure, and the upper slider 110 preferably has a rectangular structure, the top surface of the upper slider 110 is provided with a first engaging groove 111 extending along the length direction thereof, and the first engaging groove 111 penetrates through two end walls of the upper slider 110; the bottom surface of the upper slider 110 is convexly provided with a first positioning column 112, and one end in the width direction thereof is provided with a first positioning column 112 in a cylindrical shape, and the other end in the width direction thereof is provided with a first positioning column 112 in a rectangular shape, that is, the four corners of the upper slider 110 are provided with the first positioning columns 112, and the first positioning columns 112 in different shapes can realize better positioning after the upper slider 110 is mounted. Of course, the first positioning column 112 is not limited to the structural arrangement in the present embodiment, but may be arranged in other shapes, for example, in a square shape or the like. And all the first positioning posts 112 may also be provided in the same shape.

Referring to fig. 3 to fig. 4 again, in an embodiment of the present utility model, the lower slider 120 is also in a plate-shaped structure, and a first connection end 120a and a second connection end 120b are respectively formed at two opposite ends of the lower slider, and the width of the first connection end 120a is slightly greater than that of the upper slider 110. A second positioning post 123 is disposed at a substantially middle portion of the first connection end 120a of the lower slider 120, an outer diameter of the second positioning post 123 corresponds to an inner diameter of the elastic member 130, and a height of the second positioning post 123 is smaller than a height of the elastic member 130. The end portion of the first connecting end 120a of the lower slider 120 is provided with two circular positioning holes 122, the approximately middle portion of the lower slider 120 is provided with two rectangular positioning holes 122, and four positioning holes 122 are arranged around the second positioning post 123. The second engaging groove 121 is disposed on the bottom surface of the first connecting end 120a, and the extending direction of the second engaging groove 121 is perpendicular to the connecting line between the first end and the second end.

More specifically, the connection hole 124 is provided at the second connection end 120b of the lower slider 120. In addition, the top surface of the second connecting end 120b is further provided with two wing-shaped side walls 125 in a protruding manner, the two wing-shaped side walls 125 extend along the connecting line between the first end and the second end, and are symmetrically arranged, and the shape of the wing-shaped side walls 125 is not particularly limited, for example, in an embodiment, the wing-shaped side walls 125 are obliquely arranged. The airfoil sidewall 125 is a reinforcing rib of the lower slider 120, which serves to increase the strength of the lower slider 120.

As shown in fig. 5 to 6, the widths of the first engaging groove 111 of the upper slider 110 and the second engaging groove 121 of the lower slider 120 may be the same or different, and are not particularly limited herein. In one embodiment, the width of the first engagement groove 111 is smaller than the width of the second engagement groove 121.

As shown in fig. 2 to 6, when the battery mounting assembly 100 is assembled, the elastic member 130 is sleeved outside the second positioning post 123 of the lower slider 120, and the elastic member 130 is higher than the second positioning post 123, so that the elastic member 130 can be compressed and deformed downwards when being pressed. When the upper slider 110 is connected to the lower slider 120, the upper slider 110 is located above the first connection end 120a of the lower slider 120 and moves vertically downward, so that the cylindrical first positioning column 112 of the upper slider 110 is slidably connected to the circular positioning hole 122 of the lower slider 120, and the rectangular first positioning column 112 of the upper slider 110 is slidably connected to the rectangular positioning hole 122 of the lower slider 120, so that the upper slider 110 is supported on the first connection end 120a of the lower slider 120, and at this time, the elastic member 130 is pressed between the upper slider 110 and the lower slider 120, as shown in fig. 5-6. The first engagement groove 111 and the second engagement groove 121 are vertically opposed to each other and extend in the same direction.

When the upper slider 110 and the lower slider 120 are pressed, the two move towards each other to press the elastic member 130 to deform, and the state of the upper slider 110 and the lower slider 120 in the first position is shown in fig. 5. When the upper and lower sliders 110, 120 lose the external force, the elastic force of the elastic member 130 restoring the deformation can drive the upper and lower sliders 110, 120 to move away from each other, and the upper and lower sliders 110, 120 move to the second position as shown in fig. 6.

As shown below in conjunction with fig. 2-10, the present utility model also provides an electronic device 1 that includes a housing (not shown), a battery 200, and a battery mounting assembly 100 as described above. The housing is provided with a locking portion, a side wall of the battery 200 is provided with a chute 210 penetrating through two ends of the side wall, and the battery mounting assembly 100 is connected in the chute 210. The specific structure of the battery mounting assembly 100 is as described above, and a description thereof will not be repeated.

Referring to fig. 5-10, the upper slider 110 and the lower slider 120 of the battery mounting assembly 100 have a first position (see fig. 5) close to each other and a second position (see fig. 6) far away from each other, when the upper slider 110 and the lower slider 120 are forced to move to the first position, they can slide into the sliding slot 210 from the end of the battery 200 and slide along the sliding slot 210 (see fig. 7-9), and when the upper slider 110 and the lower slider 120 lose force, they can move to the second position and abut against the sliding slot 210 (see fig. 10) under the action of the elastic force of the elastic member 130, and the lower slider 120 can be detachably connected to the locking portion of the housing.

Referring to fig. 8, an upper clamping block 213 protruding downward is protruding from the upper wall 211 of the sliding chute 210, and a lower clamping block 214 protruding upward from the upper clamping block 213 is protruding from the lower wall 212 of the sliding chute 210, that is, the upper clamping block 213 and the lower clamping block 214 protrude toward each other. After the upper slider 110 and the lower slider 120 are locked in the sliding groove 210, specifically, a portion of the first connecting end 120a of the lower slider 120 and a corresponding portion of the upper slider 110 are locked in the sliding groove 210, the upper clamping block 213 is locked in the first locking groove 111, and the lower clamping block 214 is locked in the second locking groove 121.

As shown in fig. 9-10, the width of the upper clamping block 213 corresponds to the width of the first clamping groove 111, and/or the width of the lower clamping block 214 corresponds to the width of the second clamping groove 121. In one embodiment of the present utility model, the width of the upper clamping block 213 corresponds to the width of the first clamping groove 111, and the width of the lower clamping block 214 is smaller than the width of the second clamping groove 121. Thus, after the upper clamping block 213 is clamped into the first clamping groove 111, the upper clamping block 213 can only slide along the axial direction of the first clamping groove 111 and cannot move along the direction perpendicular to the axial direction of the first clamping groove 111, so as to position the entire battery mounting assembly 100, prevent the entire battery mounting assembly 100 from sliding relative to the battery 200 in the axial direction perpendicular to the chute 210 and the first clamping groove 111, and prevent the battery 200 from shaking after being mounted.

Referring to fig. 7-8 again, the upper wall 211 or/and the lower wall 212 of the sliding slot 210 are further provided with a positioning slot 215 in a concave manner, when the upper slider 110 and the lower slider 120 move into the positioning slot 215, the upper slider 110 and the lower slider 120 are released from being pressed to move to the second position under the action of elastic force, and at this time, the upper slider 110 and the lower slider 120 are clamped into the positioning slot 215 to be positioned, so as to prevent the whole battery mounting assembly 100 from continuously sliding along the axial direction of the sliding slot 210 and the first clamping slot 111, and the purpose is to prevent the battery 200 from shaking after being mounted.

In a specific embodiment, the upper wall 211 and the lower wall 212 of the chute 210 are both concavely provided with the positioning groove 215, so that when the battery installation assembly 100 slides to the position corresponding to the positioning groove 215, the upper slider 110 and the lower slider 120 which are pressed are released, and the upper slider 110 and the lower slider 120 respectively move up and down under the action of the elastic member 130 and are clamped in the positioning groove 215, thereby realizing better positioning effect.

With continued reference to fig. 7-8, after the battery mounting assembly 100 moves into the positioning slot 215 and is positioned, the battery 200 is mounted and fixed by using the locking member passing through the connecting hole 124 and being locked to the locking portion on the housing.

In the present utility model, the locking member is preferably a screw, but not limited thereto, and other fixing members may be selected.

In summary, in the battery mounting assembly 100 of the present utility model, the upper slider 110, the lower slider 120 and the elastic member 130 disposed therebetween are slidably connected, and the upper end surface of the upper slider 110 is provided with the first engaging groove 111 penetrating through the two lateral ends thereof, and the lower end surface of the lower slider 120 is provided with the second engaging groove 121 corresponding to the extending direction of the first engaging groove 111, so that when the upper slider 110 and the lower slider 120 are forced to move toward each other to the first position, the upper slider 110 and the lower slider 120 can slide into the sliding groove 210 on the battery 200 from the end portion and slide along the sliding groove 210, and the battery mounting assembly 100 slides along the extending direction of the sliding groove 210 of the battery 200 to adjust the position until the locking position corresponds to the locking position on the housing, and at this time, the force applied to the upper slider 110 and the lower slider 120 can be moved in opposite directions and against the sliding groove 210 under the elastic force of the elastic member 130, thereby realizing the positioning of the battery mounting assembly 100, and then connecting the lower slider 120 to the locking position on the housing to realize the mounting of the battery 200. The utility model can adjust the position of the battery mounting assembly 100 according to the positions of different locking parts on the shell, has simple and flexible movement and adjustment, more convenient use and strong compatibility, ensures that different electronic devices 1 can be compatible with the shared battery 200, avoids the cost waste caused by repeated design and die opening of the shared battery 200, and reduces the manufacturing cost.

Correspondingly, the electronic device 1 having the battery mounting assembly 100 according to the present utility model also has the same technical effects.

The structure of the other parts of the electronic device 1 according to the present utility model is a conventional structure known to those skilled in the art, and will not be described in detail here.

The foregoing description of the preferred embodiments of the present utility model is not intended to limit the scope of the claims, which follow, as defined in the claims.

Claims (10)

1. A battery mounting assembly, comprising:

the upper sliding block is provided with a first clamping groove penetrating through the two transverse ends of the upper sliding block, and the lower end face of the upper sliding block is convexly provided with a first positioning column;

the upper end of the lower sliding block is provided with a positioning hole extending along the thickness direction of the lower sliding block, and the lower end surface of the lower sliding block is provided with a second clamping groove penetrating through the two transverse ends of the lower sliding block; the upper sliding block is connected in the positioning hole in a sliding way through the first positioning column, and enables the first clamping groove and the second clamping groove to be opposite up and down and have the same extending direction;

the elastic piece is arranged between the upper sliding block and the lower sliding block, the upper sliding block and the lower sliding block can deform when being stressed to move oppositely, and the upper sliding block and the lower sliding block can move away under the action of the elastic force of the elastic piece when the force of the upper sliding block and the lower sliding block is lost.

2. The battery mounting assembly of claim 1, wherein the upper end surface of the lower slider is further provided with a second positioning post in a protruding manner, and the elastic member is sleeved outside the second positioning post.

3. The battery mounting assembly of claim 2 wherein said second locating post is disposed in a central portion of said lower slider, said locating hole being disposed about said second locating post.

4. A battery mounting assembly according to any one of claims 1 to 3, wherein the lower slider is further provided with a connecting hole extending therethrough in a thickness direction thereof, the connecting hole being adapted to be connected to the locking portion.

5. The battery mounting assembly of claim 1 wherein the first positioning post is cylindrical, square or/and rectangular, and the shape of the positioning hole corresponds to the shape of the first positioning post.

6. An electronic device, includes the casing, be equipped with the locking position on the casing, its characterized in that still includes:

the battery, a side wall of the said battery has slide grooves penetrating the both ends of the side wall;

the battery mounting assembly of any of claims 1-5, wherein the upper and lower sliders have a first position that is closer to and a second position that is farther from, the upper and lower sliders being slidably engaged into and slidable along the slide grooves from the ends of the battery when the upper and lower sliders are forced to move to the first position, the upper and lower sliders being movable to the second position against the slide grooves by the elastic force of the elastic member when the upper and lower sliders are not forced, and the lower sliders being detachably connected to the locking portion.

7. The electronic device of claim 6, wherein an upper clamping block protruding downward is protruding on an upper wall of the sliding groove, a lower clamping block protruding downward is protruding on a lower wall of the sliding groove, and after the upper sliding block and the lower sliding block are clamped into the sliding groove, the upper clamping block is clamped into the first clamping groove, and the lower clamping block is clamped into the second clamping groove.

8. The electronic device of claim 7, wherein a width of the upper clip corresponds to a width of the first clip groove, or/and a width of the lower clip corresponds to a width of the second clip groove.

9. The electronic device of claim 6, wherein a positioning groove is further concavely formed in the upper wall or/and the lower wall of the chute, and the upper slider and the lower slider are locked in the positioning groove to be positioned when moving to the second position after losing force.

10. The electronic device of claim 6, wherein the lower slider is further provided with a connecting hole extending in a thickness direction thereof, and the battery is fixed by passing through the connecting hole by a locking member and locking the locking member to the locking portion.