CN115498350B - Engaging member and battery accommodating device - Google Patents

Abstract

The invention discloses a clamping component and a battery accommodating device. The battery accommodating device comprises a body and a clamping member. The clamping component is pivoted in the body. The clamping component comprises two arm parts, two protruding parts and an elastic structure. Two ends of the elastic structure are connected with two arm parts, and one side of each arm part extends to form a protruding part. When the battery is arranged in the accommodating groove of the body, the elastic structure is pressed by the battery, and one end of the battery is clamped between the two protruding parts and the elastic structure. When the user wants to take out the battery, the user can push the two protruding parts to enable the clamping component to rotate relative to the body, so that the elastic structure can jack up the battery, and one end of the battery is not clamped by the clamping component any more. The battery accommodating device can enable a user to easily take out the battery from the accommodating groove.

Description

Engaging member and battery accommodating device

Technical Field

The present invention relates to a locking member and a battery accommodating device, and more particularly, to a locking member for a battery accommodating device and a battery accommodating device including the locking member for user operation.

Background

Related structures for accommodating batteries in electronic devices (such as notebook computers, intelligent home appliance control hubs, intelligent mobile phones, keyboards, mice and the like) are common, and the problem that users cannot take out the batteries easily by hands often exists.

Disclosure of Invention

The invention discloses a clamping component and a battery accommodating device, which are mainly used for solving the problem that related personnel are not easy to take out batteries from related structures for accommodating the batteries in the prior art.

One embodiment of the present invention discloses a locking member for being mounted in a receiving groove of a battery receiving device, the receiving groove being used for receiving at least one battery, the locking member comprising: two arm sections; two protruding parts, one end of each arm part extends to one side to form one protruding part; an elastic structure connected with the other ends of the two arm parts, wherein a part of each protruding part is arranged towards the direction of the elastic structure, and each protruding part and the elastic structure can jointly hold a part of the battery; wherein when the two arm parts move towards each other under the action of external force, the elastic structure is elastically deformed; two first pivoting structures, each arm is provided with one first pivoting structure; the clamping component is pivoted with the two second pivoting structures of the battery accommodating device through the two first pivoting structures, and can rotate relative to the accommodating groove through the two first pivoting structures.

One embodiment of the invention discloses a battery accommodating device for accommodating a battery, the battery accommodating device comprising: the body comprises a containing groove and an avoiding groove, the containing groove is used for containing the battery, the avoiding groove is communicated with the containing groove, and the avoiding groove is formed by inwards concave bottom of the body; an engagement member, comprising: two arm sections; two protruding parts, one end of each arm part extends to one side to form one protruding part; an elastic structure connected with the other ends of the two arm parts, wherein a part of each protruding part is arranged towards the direction of the elastic structure, and each protruding part and the elastic structure can jointly hold a part of the battery; wherein when the two arm parts move towards each other under the action of external force, the elastic structure is elastically deformed; the avoiding groove is used for accommodating the elastic structure; when the elastic structure is arranged in the avoidance groove, the elastic structure does not protrude out of the bottom; two first pivoting structures, each arm is provided with one first pivoting structure; the two second pivoting structures are arranged on the body and are positioned in the accommodating groove, and the two second pivoting structures are mutually pivoted with the two first pivoting structures; the clamping component can rotate relative to the body under the action of external force.

In summary, according to the engaging member and the battery accommodating device of the present invention, the engaging member is pivoted to the body, and the engaging member has the elastic structure, the two arms, the two protrusions, and the like, so that when a person wants to take out the battery engaged in the accommodating groove, the person only needs to push the two protrusions to rotate the engaging member relative to the body, so that the elastic structure can jack up the battery, and the user can easily take out the battery from the accommodating groove without engaging the battery in the accommodating groove.

For a further understanding of the nature and the technical aspects of the present invention, reference should be made to the following detailed description of the invention and the accompanying drawings, which are included to illustrate and not to limit the scope of the invention.

Drawings

Fig. 1 and 2 are schematic views of a battery accommodating apparatus according to the present invention from different viewing angles;

fig. 3 is an exploded view of the body and the engaging member of the battery housing device of the present invention;

fig. 4 is a schematic top view of the battery accommodating apparatus of the present invention;

FIG. 5 is a schematic partial cross-sectional view of a battery receiving device according to the present invention;

FIG. 6 is a schematic view of the engaging member of the present invention;

fig. 7 and 8 are a partially cross-sectional perspective view and a partially cross-sectional schematic view, respectively, of a battery just mounted on the battery housing device of the present invention;

fig. 9 and 10 are a schematic perspective view and a schematic perspective view, respectively, of a battery that is to be engaged and disposed in a battery accommodating device of the present invention;

FIG. 11 is a schematic cross-sectional view of a battery engaging device disposed in a battery receiving device;

FIG. 12 is a schematic side view of the engaging member of the present invention;

fig. 13 is a schematic view of another embodiment of the engaging member of the present invention.

Symbol description

100: battery housing apparatus 1: body

1A: accommodating groove

11: limiting structure

11A: limiting groove

12: second pin joint structure

13: bottom part

1B: avoidance groove

13A: auxiliary groove 131: bottom surface

14: side wall

15: side wall

16: abutment structure 2: engaging member

21: arm portion

211: broad side 22: projection part

221: inclined surface

23: elastic structure

23A: elastic structure

24: first pin joint structure

2A: clamping groove

2AH: depth of

B: battery cell

B1: top surface

D1: first distance

D2: second distance

H1: first vertical distance

H2: second vertical distance

S: gap of

P: gap of

W: horizontal distance

θ: included angle

Detailed Description

In the following description, reference is made to or as illustrated in the accompanying drawings, which are for the purpose of emphasis instead of limiting the description to the specific drawings in which the relevant content is presented for the most part.

Referring to fig. 1 to 6, fig. 1 and 2 are schematic diagrams of different views of the battery accommodating apparatus according to the present invention, fig. 3 is an exploded schematic diagram of a body and a locking member of the battery accommodating apparatus according to the present invention, fig. 4 is a schematic top view of the battery accommodating apparatus according to the present invention, fig. 5 is a schematic partial cross-sectional view of the battery accommodating apparatus according to the present invention, and fig. 6 is a schematic diagram of the locking member according to the present invention.

The battery accommodating apparatus 100 of the present invention is used for accommodating a battery B. The battery accommodating apparatus 100 includes a main body 1 and an engaging member 2. In practical applications, the battery accommodating apparatus 100 may be applied to various electronic devices, and the body 1 of the battery accommodating apparatus 100 may be a part of the electronic device, for example, the body 1 may be a part of a housing of the electronic device; the electronic device may be, for example, a notebook computer, a smart home control HUB (HUB), a keyboard, a mouse, a smart phone, a smart tablet computer, etc., and various electronic devices including a battery.

The body 1 comprises a containing groove 1A, two limiting structures 11, an avoiding groove 1B and two second pivoting structures 12. The accommodating groove 1A is used for accommodating the battery B, the avoiding groove 1B is communicated with the accommodating groove 1A, and the avoiding groove 1B is formed by the concave bottom 13 of the body 1. The accommodating groove 1A is mainly used for accommodating the battery, so the shape and the size of the accommodating groove 1A can be changed according to the shape and the size of the battery, and the shape and the size of the accommodating groove are only one exemplary shape. The shape and the setting position of the avoiding groove 1B for accommodating a part of the engaging member 2 are determined corresponding to the shape of the engaging member 2 and the setting position of the engaging member 1.

The two limiting structures 11 are arranged in the body 1, the two limiting structures 11 are located in the accommodating groove 1A, the two limiting structures 11 are located at the other end of the accommodating groove 1A, each limiting structure 11 and the bottom 13 jointly form a limiting groove 11A, the two limiting grooves 11A are used for accommodating one end of the battery B, and the two limiting structures 11 and the bottom 13 can jointly fix one end of the battery B. In the drawings of the present embodiment, two limiting structures 11 are formed on a side wall 14 of the body 1 at intervals, but the positions where the two limiting structures 11 are disposed on the body 1 are not limited to those shown in the drawings, and all structures that can be used to limit one end of the battery B are within the range where the limiting structures 11 are specifically applicable. The number, shape and size of the limiting structures 11 are not limited to those shown in the present embodiment.

In practical application, in order to facilitate the related personnel to more easily set one end of the battery B between the two limiting structures 11 and the bottom 13 of the body 1, the bottom 13 of the body 1 may further be concavely formed with two auxiliary grooves 13A, and each auxiliary groove 13A is correspondingly located below one of the limiting structures 11. As shown in fig. 7, in the process that one end of the battery B is disposed between the limit structure 11 and the bottom 13 by the design of the two auxiliary grooves 13A, a portion of the battery B may be correspondingly disposed in the auxiliary grooves 13A, so that one end of the battery B will be more easily disposed in the limit groove 11A between the two limit structures 11 and the bottom 13. In the present embodiment, two auxiliary grooves 13A are correspondingly located at two corners of the bottom 13, but not limited thereto, and in different embodiments, two auxiliary grooves 13A shown in the drawings may be mutually communicated to form a single auxiliary groove 13A. The shape and size of each auxiliary groove 13A are not limited to those shown in the drawings.

The two second pivoting structures 12 are disposed on the body 1, and the two second pivoting structures 12 are disposed in the accommodating groove 1A. The two second pivoting structures 12 are located at the other end of the body 1 opposite to the two limiting structures 11. The two second pivoting structures 12 are configured to pivot with the two first pivoting structures 24 of the engaging member 2. In the drawings of the present embodiment, the second pivot structures 12 are exemplified by cylindrical structures, but not limited thereto; in various embodiments, each of the second pivoting structures 12 may be a groove, a perforation, a hemispherical protrusion, etc.

The engaging member 2 is detachably fixed to the body 1. The engaging member 2 includes: two arm portions 21, two protruding portions 22, an elastic structure 23 and two first pivoting structures 24. One end of each arm 21 extends to one side to form one protruding portion 22. The size and shape of each arm 21 may vary depending on the requirements, and is shown in one exemplary form.

The elastic structure 23 is connected to the other end of each arm 21, and a portion of each projection 22 is disposed toward the elastic structure 23. Specifically, each arm 21 may be of a rectangular body structure, both ends of the elastic structure 23 may be a wide side 211 connecting the two arms 21, and the wide side 211 connecting each arm 21 with the elastic structure 23 is formed with a protrusion 22. The elastic structure 23 can be elastically deformed by an external force. The elastic structure 23, which is elastically deformed by the external force, can be restored to a state of no external force when no external force is applied.

Each arm 21 is provided with a first pivot structure 24. Each first pivoting structure 24 is configured to pivot with one of the second pivoting structures 12, and the engaging member 2 can rotate relative to the body 1 through each first pivoting structure 24 and the second pivoting structure 12 that are pivoted with each other. In the drawings of the present embodiment, each first pivot structure 24 is a through hole, and each second pivot structure 12 is a corresponding cylindrical structure, but the shapes and sizes of each first pivot structure 24 and each second pivot structure 12 are not limited to those shown in the drawings. In various embodiments, each of the first pivoting structures 24 may also be a cylindrical structure, and each of the second pivoting structures 12 may be a through hole.

As described above, by the design of the elastic structure 23, when the locking member 2 is mounted in the accommodating groove 1A, the two first pivot structures 24 of the locking member 2 and the two second pivot structures 12 of the body 1 can be more easily locked by a person. Specifically, as shown in fig. 1, 3 to 5, when the user wants to install the engaging member 2 in the accommodating groove 1A, the user can hold the outer sides of the two protruding portions 22 and squeeze the two arm portions 21, at this time, the elastic structure 23 connected with the two arm portions 21 will elastically deform, and the distance between the two arm portions 21 will be shortened, so that the user can relatively easily place the engaging member 2 in the accommodating groove 1A, and can relatively easily engage the two first pivot structures 24 with the two second pivot structures 12. After the user engages the two first pivot structures 24 with the two second pivot structures 12, the user only needs to press the two arm portions 21, and the elastic structure 23 returns to the unpressurized state due to its elastic restoring force, so that the two first pivot structures 24 and the two second pivot structures 12 are firmly connected with each other. In practical application, the width of the accommodating groove 1A may be slightly smaller than the width of the engaging member 2 when the engaging member 2 is pressed by an external force, and when the two first pivoting structures 24 and the two second pivoting structures 12 of the engaging member 2 are pivoted to each other, the elastic structure 23 may be slightly pressed by the body 1, and the elastic restoring force of the elastic structure 23 will enable each first pivoting structure 12 to be better connected with the corresponding second pivoting structure 24.

In contrast, when the person is about to take out the engaging member 2 from the accommodating groove 1A, the person can simply squeeze the two arm portions 21 to move the two arm portions 21 toward each other, so that the two first pivot structures 24 are no longer pivoted to the two second pivot structures 12, and the person can easily take out the engaging member 2 from the accommodating groove 1A.

As shown in fig. 1, 3 to 5, it should be noted that when the engaging member 2 is pivoted to the two second pivoting structures 12 through the two first pivoting structures 24, the elastic structure 23 is correspondingly accommodated in the avoiding groove 1B of the body 1, and the depth of the avoiding groove 1B is not smaller than the thickness of the elastic structure 23, and when the engaging member 2 is pivoted to the body 1, the elastic structure 23 will not protrude out of the bottom surface 131 of the bottom 13, so that when the battery B is engaged in the accommodating groove 1A, the battery B will be stably disposed on the bottom surface 131 of the bottom 13.

In addition, when the engaging member 2 is pivotally disposed in the accommodating groove 1A, a gap P exists between the position of the elastic structure 23 furthest from the two arm portions 21 and the position of the avoiding groove 1B furthest from the sidewall 15 of the accommodating groove 1A, and by the design of the gap P, the user will not interfere with the bottom 13 during the process of mounting the engaging member 2 on the body 1 or during the process of taking out the engaging member 2 from the accommodating groove 1A by the user.

Referring to fig. 6 to 11, in practical application, a side of each protrusion 22 away from the elastic structure 23 may further have an inclined surface 221, and each protrusion 22, arm 21 and elastic structure 23 are jointly formed with an engaging groove 2A, and two engaging grooves 2A of the engaging member 2 are used for holding one end of the battery B. In one specific application, the depth 2AH of each engaging groove 2A (as shown in fig. 8) may be between 0.5 and 1.5 mm, but not limited thereto, and the depth 2AH of the engaging groove 2A may correspondingly vary according to the thickness of the battery B.

As shown in fig. 7 and 8, when the user wants to set the battery B in the accommodating groove 1A, the user may first engage one end of the battery B with the limiting groove 11A disposed between the limiting structure 11 and the bottom 13, and then make the other end of the battery B abut against the inclined surfaces 221 of the two protruding portions 22. As shown in fig. 8 to 10, when the user engages one end of the battery B between the limiting structure 11 and the bottom 13 and the other end of the battery B abuts against the two inclined surfaces 221 of the two protruding portions 22, the user can then press the battery B to move the battery B toward the bottom 13, during which the battery B moves along the two inclined surfaces 221, the engaging member 2 is pushed by the battery B to rotate relative to the body 1, and the battery B gradually enters the two engaging grooves 2A formed by the protruding portions 22, the arm portions 21 and the elastic structure 23.

As shown in fig. 9 and 11, when the battery B pushes against the two protruding portions 22, the engaging member 2 will rotate relative to the body 1, and a portion of the elastic structure 23 will leave the escape groove 1B; when the battery B abuts against the bottom 13, the battery B will simultaneously abut against the elastic structure 23, so that the elastic structure 23 returns to the avoiding groove 1B. In the process that the battery B pushes against the elastic structure 23 and the elastic structure 23 returns to the avoiding groove 1B, the whole clamping member 2 is driven to rotate relative to the body 1 until the two protruding portions 22 are clamped to the top surface B1 of the battery B.

As shown in fig. 11, when the battery B is clamped in the accommodating groove 1A, one side of the battery B will be abutted against the bottom 13 of the body 1, the other side of the battery B will be abutted against by the two limiting structures 11 and the two protruding portions 22, and two ends of the battery B are correspondingly positioned in the limiting groove 11A and the clamping groove 2A, and the battery B is limited by the bottom 13, the two limiting structures 11, the two protruding portions 22 and the elastic structure 23 to be firmly clamped in the accommodating groove 1A.

As shown in fig. 9 to 11, when the user wants to take out the battery B in the engaging accommodating groove 1A, the user only needs to push the two protruding portions 22 in a direction away from the battery B, so that the engaging member 2 rotates relative to the body 1, the elastic structure 23 can jack up the battery B from the bottom 13 of the body 1, and the battery B will be separated from the two engaging grooves 2A during the rotation of the engaging member 2 relative to the body 1.

As shown in fig. 1, 8 to 10, the body 1 may further include two abutting structures 16, the two abutting structures 16 are connected with the body 1, and the two abutting structures 16 are located in the accommodating groove 1A, and the two abutting structures 16 are disposed adjacent to the two arm portions 21. When the engaging member 2 is rotated by a predetermined angle relative to the accommodating groove 1A under the action of an external force, the two arm portions 21 abut against the two abutting structures 16, and the two abutting structures 16 are used for limiting the rotation angle of the engaging member 2 relative to the accommodating groove 1A.

As shown in fig. 9, by the design of the two abutting structures 16, when the two protrusions 22 are pushed against and the two arms 21 abut against the two abutting structures 16, and the elastic structure 23 lifts the battery B, the user may extend his/her finger to the bottom of the battery B through the gap S between the battery B and the side wall 15 of the body 1 to pull the battery B up. As shown in fig. 8 and 9, in a preferred embodiment, the horizontal distance W between each arm 21 and the abutting structure 16 may be 2-5 mm, so that the user can more easily extend the finger to the bottom of the battery B through the gap S.

Referring to fig. 4, 6 and 12, in one preferred embodiment, if the horizontal distance between the two arms 21 is defined as a first distance D1, and the maximum vertical distance between an inner side of the elastic structure 23 and the horizontal connection line between the two arms 21 is defined as a second distance D2, the first distance D1 may be 0.25-4 times the second distance D2; if the vertical distance from the center of each first pivot structure 24 to one end of the arm portion 21 connected thereto is defined as a first vertical distance H1, and the vertical distance from the center of each first pivot structure 24 to the other end of the arm portion 21 connected thereto is defined as a second vertical distance H2, the first vertical distance H1 may be 1.5 to 4.5 times the second vertical distance H2; the inclined surface 221 of each protruding portion 22 has an included angle θ of 45 to 55 degrees with the horizontal line; through the design, a user can set the battery B in the accommodating groove 1A in a clamping manner, or take out the battery B clamped in the accommodating groove 1A from the accommodating groove 1A more easily and quickly.

Fig. 13 is a schematic view of another embodiment of the engaging member of the present invention. The present embodiment is most different from the foregoing embodiments in that: the elastic structure 23A of the engaging member 2 may have a W-like structure instead of an arc-like structure. However, the shape of the elastic structure 23A is not limited to the shape shown in the drawings of the present embodiment and the foregoing embodiments, and the elastic structure 23A can be elastically deformed when the outer sides of the two arm portions 21 are pressed, which falls into the applicable implementation range of the engaging member 2 of the present invention.

The engaging member 2 of the present invention may be manufactured, sold, and implemented separately, but the engaging member 2 is not limited to being manufactured, sold, and implemented together with the main body.

In summary, according to the battery accommodating device of the present invention, due to the design of the engaging member and the like, the user can easily engage and set the battery in the accommodating groove without using other auxiliary tools, and the user can easily take out the battery engaged in the accommodating groove.

The foregoing description is only of the preferred embodiments of the invention and is not intended to limit the scope of the invention, so that all changes which come within the meaning and range of equivalency of the description and drawings are intended to be embraced therein.

Claims (15)

1. A clamping member for being mounted in a receiving groove of a battery receiving device, the receiving groove being for receiving at least one battery, the clamping member comprising:

two arm sections;

two protruding parts, one end of each arm part extends to one side to form one protruding part;

an elastic structure connected to the other ends of the two arm portions, a portion of each of the protruding portions being disposed toward the elastic structure, and each of the protruding portions and the elastic structure being capable of holding a portion of the battery together; wherein the elastic structure is elastically deformed when the two arm portions are moved toward each other by an external force;

and each arm part is provided with one first pivoting structure.

2. The engagement member of claim 1, wherein a portion of each of the protrusions, each of the arms, and a portion of the resilient structure collectively form an engagement groove having a depth of 0.5-1.5 millimeters.

3. The engaging member according to claim 1, wherein each of the protrusions has an inclined surface having an angle of 45-55 degrees with respect to a horizontal line.

4. The snap-in member of claim 1, wherein the resilient structure is an arcuate structure.

5. The engaging member according to claim 4, wherein a horizontal distance between the two arm portions is defined as a first distance, and a maximum vertical distance between an inner side of the elastic structure and a horizontal line connecting the two arm portions is defined as a second distance, and the first distance is 0.25 to 4 times the second distance.

6. The engaging member according to claim 1, wherein a vertical distance from a center of each of the first pivoting structures to one end of the arm portion to which it is connected is defined as a first vertical distance, and a vertical distance from a center of each of the first pivoting structures to the other end of the arm portion to which it is connected is defined as a second vertical distance, the first vertical distance being 1.5 to 4.5 times the second vertical distance.

7. A battery receiving device for receiving a battery, the battery receiving device comprising:

the battery pack comprises a body, a battery holder and a battery holder, wherein the body comprises a containing groove and an avoiding groove, the containing groove is used for containing the battery, the avoiding groove is communicated with the containing groove, and the avoiding groove is formed by inwards concave bottom of the body;

an engagement member comprising:

two arm sections;

two protruding parts, one end of each arm part extends to one side to form one protruding part;

an elastic structure connected to the other ends of the two arm portions, a portion of each of the protruding portions being disposed toward the elastic structure, and each of the protruding portions and the elastic structure being capable of holding a portion of the battery together; wherein the elastic structure is elastically deformed when the two arm portions are moved toward each other by an external force; the avoiding groove is used for accommodating the elastic structure; when the elastic structure is arranged in the avoidance groove, the elastic structure does not protrude out of the bottom;

two first pivoting structures, each arm is provided with one first pivoting structure;

the two second pivoting structures are arranged on the body and are positioned in the accommodating groove, and the two second pivoting structures are mutually pivoted with the two first pivoting structures; the clamping component can rotate relative to the body under the action of external force.

8. The battery receiving device of claim 7, wherein the battery receiving device further comprises two abutment structures connected to the body, the two abutment structures being located in the receiving slots, the two abutment structures being disposed adjacent to the two arms; when the clamping component rotates by a preset angle relative to the accommodating groove under the action of external force, the two arm parts are abutted against the two abutting structures, and the two abutting structures are used for limiting the rotation angle of the clamping component relative to the accommodating groove.

9. The battery receiving device of claim 8, wherein each of the arm portions is horizontally spaced from the abutment structure by a distance of 2-5 mm.

10. The battery housing device according to claim 7, wherein a portion of each of the protruding portions, each of the arm portions, and a portion of the elastic structure together form an engagement groove having a depth of 0.5 to 1.5 mm.

11. The battery receiving device of claim 7, wherein each of the protrusions has an inclined surface having an angle of 45-55 degrees with respect to a horizontal line.

12. The battery receiving device of claim 7, wherein the elastic structure is an arc-shaped structure.

13. The battery receiving device of claim 12, wherein a horizontal distance between the two arm portions is defined as a first distance, and a maximum vertical distance of a horizontal line connecting an inner side of the elastic structure and the two arm portions is defined as a second distance, the first distance being 0.25 to 4 times the second distance.

14. The battery receiving device of claim 7, wherein a vertical distance from a center of each of the first pivoting structures to one end of the arm portion to which it is connected is defined as a first vertical distance, and a vertical distance from a center of each of the first pivoting structures to the other end of the arm portion to which it is connected is defined as a second vertical distance, the first vertical distance being 1.5 to 4.5 times the second vertical distance.

15. The battery accommodating apparatus of claim 7, wherein the battery accommodating apparatus further comprises two limiting structures disposed on the body, the two limiting structures being disposed in the accommodating groove, the two limiting structures being disposed at the other end of the accommodating groove; the two limit structures and the bottom hold one end of the battery together.

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