CN114122610A - Man-machine interaction equipment and battery fixing mechanism thereof - Google Patents

Abstract

The invention discloses a man-machine interaction device and a battery fixing mechanism thereof, wherein the battery fixing mechanism comprises: the battery pack comprises a shell provided with a battery compartment, a first electrode assembly and a second electrode assembly, wherein a limiting assembly and a moving assembly for pushing the limiting assembly to move between a first position and a second position are arranged in the shell; the limiting component reaches a second position before the telescopic end of the second electrode component; the limiting assembly at the first position avoids the telescopic path of the second electrode assembly; the stop assembly in the second position impedes compression of the second electrode assembly. When the battery fixing mechanism provided by the invention is used, when the battery fixing mechanism is impacted, dropped or suddenly stopped in a fast moving state, the condition that the battery is disconnected and powered off can be effectively avoided, and the reliability of the electrical connection of the battery is improved; meanwhile, the battery is simple in disassembly and assembly process and convenient to use.

Description

Man-machine interaction equipment and battery fixing mechanism thereof

Technical Field

The invention relates to the technical field of game equipment, in particular to a battery fixing mechanism. In addition, the invention also relates to a man-machine interaction device comprising the battery fixing mechanism.

Background

In order to assemble and clamp the battery conveniently in the gamepad, the negative pole sheetmetal of battery can be designed into telescopic elastic structure, when the handle drops, receives the striking or when stopping suddenly among the quick travel process, the battery can strike the negative pole sheetmetal to move to the direction of negative pole sheetmetal, compress the elastic structure of negative pole, and positive pole shell fragment is fixed and sets up, therefore the in-process of battery compression negative pole sheetmetal can cause anodal shell fragment and the anodal disconnection of battery.

In summary, how to avoid the problem of battery power failure at the moment of rapid movement to sudden stop is a problem to be solved urgently by those skilled in the art.

Disclosure of Invention

In view of this, an object of the present invention is to provide a battery fixing mechanism, which facilitates the assembly and disassembly of a battery, and in the using process, when the battery fixing mechanism is impacted or dropped, the moving component pushes the limiting component to move, so that the limiting component reaches the second position before the second electrode assembly, thereby shortening the telescopic stroke of the second electrode assembly, effectively limiting the moving stroke of the battery, and avoiding the occurrence of sudden disconnection or power failure.

Another object of the present invention is to provide a human-computer interaction device comprising the above battery fixing mechanism.

In order to achieve the above purpose, the invention provides the following technical scheme:

a battery securing mechanism comprising: a case provided with a battery compartment, a first electrode assembly, and a second electrode assembly; one end of each of the first electrode assembly and the second electrode assembly is connected with the shell, and the other end of each of the first electrode assembly and the second electrode assembly is elastically telescopic along the axial direction of the battery bin;

the battery compartment is provided with a battery compartment, a battery compartment is arranged in the battery compartment, the battery compartment is provided with a first electrode assembly and a second electrode assembly, the first electrode assembly is arranged in the battery compartment, the second electrode assembly is arranged in the battery compartment, the battery compartment is provided with a first end and a second end, the first end is connected with the battery compartment, the second end is connected with the battery compartment, and the second end is connected with the battery compartment;

the limiting assembly in the first position avoids a telescopic path of the second electrode assembly; the second position is located on a telescoping path of the second electrode assembly, the restraining assembly in the second position obstructs compression of the second electrode assembly, and the restraining assembly reaches the second position before the second electrode assembly is compressed to the second position;

the limiting assembly is located at the second position, and in the battery installation state, the continuous compressible quantity of the second electrode assembly is smaller than or equal to the current compressible quantity of the first electrode assembly, and the continuous compressible quantity of the first electrode assembly is smaller than or equal to the current compressible quantity of the second electrode assembly.

Optionally, the limiting assembly includes a stopper movably disposed in a direction perpendicular to the extension direction of the second electrode assembly, and the moving assembly includes a slider abutting against the stopper and an elastic portion having one end connected to the slider and the other end connected to the housing;

the elastic part is arranged in a telescopic manner along the telescopic direction of the second electrode assembly.

Optionally, a surface of the slider contacting the stopper is a first inclined surface arranged obliquely, and the stopper is provided with a second inclined surface matched with the first inclined surface.

Optionally, an included angle between the first inclined surface and the expansion direction of the elastic portion is less than or equal to 45 °.

Optionally, the sliding device further comprises a bracket fixedly arranged on the shell, the bracket is provided with a sliding groove, and the sliding block is provided with a sliding convex part matched with the sliding groove.

Optionally, the second electrode assembly comprises a second electrode cap for abutting against a second electrode of the battery and a second electrode spring connecting the second electrode cap and the case;

the elastic part is a slider spring, and the elastic coefficient of the second electrode spring is greater than that of the slider spring.

Optionally, the first electrode assembly comprises a first electrode cap for abutting against a first electrode of the battery and a first electrode spring connecting the first electrode cap with the case;

a first side wall is arranged at one axial end of the battery bin of the shell, a second side wall is arranged at the other axial end of the shell, the first electrode cap movably penetrates through the first side wall, and the second electrode cap movably penetrates through the second side wall;

in the battery mounted state, the second electrode spring urges the battery to the first side wall.

Optionally, the first electrode cap is provided with a first rib, and the first rib is used for limiting the length of the first electrode cap extending from the first side wall; the second electrode cap is provided with a second retaining edge, and the second retaining edge is used for limiting the length of the second electrode cap extending out of the second side wall.

Optionally, a support portion is disposed on one side of the stopper facing the housing, one end of the support portion abuts against the housing, and the other end of the support portion abuts against the stopper;

the supporting part is arranged opposite to the moving assembly; when the slide block does not push the stop block to move, the support part pushes the stop block to the first position.

A human-computer interaction device comprises the battery fixing mechanism.

In the process of using the battery fixing mechanism provided by the invention, when a battery needs to be installed, the limiting assembly moves to the first position, so that the electrode of the battery compresses the second electrode assembly, the battery is placed, and the first electrode assembly and the second electrode assembly are both in a compressed state.

After the battery is placed in the battery, when the battery fixing mechanism is impacted or falls, the battery moves towards the direction of the second electrode assembly quickly to compress the second electrode assembly, the elastic telescopic end of the moving assembly stretches, and the limiting assembly is pushed to move to a second position before the second electrode assembly in the stretching process to prevent the second electrode assembly from being compressed continuously; when the battery rapidly moves towards the direction of the first electrode assembly to compress the first electrode assembly, because the continuous compression amount of the first electrode assembly of the second electrode is smaller than or equal to the current compression amount of the second electrode assembly, the second electrode assembly extends towards the direction of the first electrode assembly in the process that the first electrode assembly is compressed by the battery, so that the second electrode of the battery is always in contact with the second electrode assembly, and the disconnection and power failure of the second electrode are avoided.

In conclusion, when the battery fixing mechanism provided by the invention is impacted, dropped or suddenly stopped in a fast moving state in the using process, the condition that the battery is disconnected and powered down can be effectively avoided, and the reliability of the electrical connection of the battery is improved; meanwhile, the battery is simple in disassembly and assembly process and convenient to use.

In addition, the invention also provides human-computer interaction equipment comprising the battery fixing mechanism.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is an external view of a battery fixing mechanism provided in the present application when an upper cover is opened;

FIG. 2 is a schematic view of the battery fixing mechanism of FIG. 1 from another angle;

fig. 3 is a schematic view of an inner side structure of a battery compartment of the battery fixing mechanism provided in the present application;

FIG. 4 is a schematic view of the inner side of the battery compartment at another angle of the battery fixing mechanism in FIG. 3;

FIG. 5 is a schematic cross-sectional view of a battery just prior to insertion into the battery securing mechanism provided herein;

FIG. 6 is a schematic cross-sectional view of a battery compressing a second electrode assembly of the battery securing mechanism provided herein;

FIG. 7 is a schematic cross-sectional view of the cell in FIG. 6 with the second electrode assembly further compressed;

FIG. 8 is a schematic cross-sectional view of a battery after insertion into a battery securing mechanism provided herein;

FIG. 9 is a cross-sectional view of the battery securing mechanism of FIG. 8 after engaging the upper cover;

FIG. 10 is a schematic cross-sectional view of a battery securing mechanism provided in accordance with the present invention when the battery securing mechanism is not subjected to an impact;

FIG. 11 is a schematic cross-sectional view illustrating the position of the slider moving when the battery fixing mechanism provided by the present invention is impacted;

FIG. 12 is a schematic cross-sectional view of a compressed second electrode assembly of the cell based on FIG. 11;

FIG. 13 is a schematic cross-sectional view of the battery securing mechanism in the state shown in FIG. 12;

FIG. 14 is an exploded view of the battery securing mechanism provided herein;

fig. 15 is an exploded view of another angle of the battery securing mechanism provided herein.

In fig. 1-15:

1 is an upper cover, 2 is a housing, 21 is a first side wall, 22 is a second side wall, 23 is a guide rail, 3 is a battery, 4 is a first electrode cap, 41 is a first rib, 5 is a second electrode cap, 51 is a second rib, 6 is a first electrode spring, 7 is a second electrode spring, 8 is a stopper, 81 is a second inclined surface, 82 is a guide groove, 9 is a support portion, 10 is a bracket, 101 is a protrusion, 102 is a slide groove, 11 is a slide block, 111 is a first inclined surface, 112 is a slide protrusion, 12 is an elastic portion, and 13 is a screw.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The core of the invention is to provide a battery fixing mechanism which is convenient for disassembling and assembling the battery, and in the using process, when the battery fixing mechanism is impacted or dropped, the moving assembly pushes the limiting assembly to move, so that the limiting assembly reaches the second position before the second electrode assembly, thereby shortening the telescopic stroke of the second electrode assembly, effectively limiting the moving stroke of the battery and avoiding the situation of sudden disconnection and power failure. Another core of the invention is to provide a human-computer interaction device comprising the battery fixing mechanism.

It should be noted that, in the battery mounted state, the amount of the second electrode assembly that can be compressed further is as follows: the limiting assembly is located at the second position, and the battery can continuously move for a distance when moving from the normal installation state to the direction of the second electrode assembly; the current compression of the first electrode assembly is: a difference between a length of the first electrode assembly before the battery is not mounted and a length of the first electrode assembly in a state where the battery is mounted; the amount of continued compression of the first electrode assembly is: a distance that the battery can continue to move when moving from the normal mounting state to the direction of the first electrode assembly; the current compression of the second electrode assembly is: the difference between the length of the second electrode assembly before the battery is not mounted and the length of the second electrode assembly in the mounted state of the battery.

The first electrode and the second electrode mentioned in the present document are two electrodes of a battery, and the first electrode may be a positive electrode, the second electrode may be a negative electrode, or the first electrode may be a negative electrode, and the second electrode may be a positive electrode. The first electrode assembly and the second electrode assembly referred to in this document are electrode assemblies for contacting the first electrode and the second electrode, respectively, in the battery fixing mechanism.

Please refer to fig. 1 to fig. 15.

This specific embodiment discloses a battery fixing mechanism, includes: a case 2 provided with a battery compartment, a first electrode assembly, and a second electrode assembly; one end of each of the first electrode assembly and the second electrode assembly is connected with the shell 2, and the other end of each of the first electrode assembly and the second electrode assembly can elastically stretch and retract along the axial direction of the battery bin;

the shell 2 is internally provided with a limiting component and a moving component, the limiting component, the moving component and the second electrode component are positioned on the same side of the battery compartment, the moving component is used for pushing the limiting component to move between a first position and a second position, one end of the moving component is connected with the shell 2, and the other end of the moving component is abutted against the limiting component and can elastically stretch out and draw back; the limiting component reaches a second position before the telescopic end of the second electrode component;

the limiting assembly at the first position avoids the telescopic path of the second electrode assembly; the second position is located on the telescopic path of the second electrode assembly, the limiting assembly located at the second position blocks the compression of the second electrode assembly, and the limiting assembly arrives before the second electrode assembly is compressed to the second position; and in the second position, the limit component is positioned at the second position, and in the installation state of the battery 3, the continuous compressible quantity of the second electrode component is less than or equal to the current compressible quantity of the first electrode component, and the continuous compressible quantity of the first electrode component is less than or equal to the current compressible quantity of the second electrode component.

In the specific setting process, the limiting component and the moving component may be disposed on one side of the battery fixing mechanism for contacting with the positive electrode of the battery 3, or disposed on one side of the battery fixing mechanism for contacting with the negative electrode of the battery 3, and are specifically determined according to actual conditions, which is not described herein.

The moving direction of the limiting component from the first position to the second position can be perpendicular to the telescopic direction of the second electrode component, and also can not be perpendicular to the telescopic direction of the second electrode component, and the continuous compression amount of the second electrode component can be shortened only by ensuring that the limiting component moves to the second position. Preferably, the first position and the second position can be arranged along a direction perpendicular to the expansion and contraction direction of the second electrode assembly, and the limiting assembly moves along the direction perpendicular to the expansion and contraction direction of the second electrode assembly.

In the process of using the battery fixing mechanism provided by the embodiment, when the battery 3 needs to be installed, the limiting assembly moves to the first position, so that the electrode of the battery 3 compresses the second electrode assembly, and the battery 3 is placed, and at this time, the first electrode assembly and the second electrode assembly are both in a compressed state.

After the battery 3 is put in, when the battery fixing mechanism is impacted or falls and stops suddenly, the battery 3 moves towards the direction of the second electrode assembly quickly to compress the second electrode assembly, the elastic telescopic end of the movable assembly stretches, and the limiting assembly is pushed to move to a second position before the second electrode assembly in the stretching process to prevent the second electrode assembly from being compressed continuously; when the battery 3 is rapidly moved towards the direction of the first electrode assembly to compress the first electrode assembly, because the continuous compression amount of the first electrode assembly of the second electrode is smaller than or equal to the current compression amount of the second electrode assembly, the second electrode assembly extends towards the direction of the first electrode assembly in the process that the first electrode assembly is compressed by the battery 3, so that the second electrode of the battery 3 is always in contact with the second electrode assembly, and the disconnection and power failure of the second electrode are avoided.

In summary, in the process of using the battery fixing mechanism provided in the embodiment, when the battery fixing mechanism is impacted, dropped or suddenly stopped in a fast moving state, the situation that the battery 3 is disconnected and powered down can be effectively avoided, and the reliability of the electrical connection of the battery 3 is improved; meanwhile, the battery 3 is simple in disassembly and assembly process and convenient to use.

In a specific embodiment, the elastic force of the second electrode assembly is always greater than that of the first electrode assembly, and after the battery 3 is loaded into the battery compartment, the first electrode of the battery 3 is in contact with the case 2 under the elastic pressure of the second electrode assembly, as shown in fig. 9, in which state the battery 3 can move within the battery compartment relative to the battery compartment only in the direction of the second electrode assembly when the battery 3 is struck or dropped.

Of course, the elastic force of the second electrode assembly may be always smaller than that of the first electrode assembly, and after the battery 3 is loaded into the battery compartment, the second electrode of the battery 3 is moved to a position where it contacts the case 2 by the elastic force of the first electrode assembly, and in this state, when the battery 3 is bumped or dropped, the battery 3 may move only in the direction of the first electrode assembly with respect to the battery compartment.

In addition, after the battery 3 is placed in the battery compartment, the two ends of the battery 3 are not in contact with the shell 2, the elastic force provided by the first electrode assembly to the battery 3 is equal to the elastic force provided by the second electrode assembly to the battery 3, and the elastic force is opposite to the direction provided by the second electrode assembly, and in this state, when the battery 3 is impacted or dropped, the battery 3 can move in the direction of the first electrode assembly or the direction of the second electrode assembly relative to the battery compartment.

In a specific embodiment, the limiting assembly may include a stopper 8 movably disposed along a direction perpendicular to the extension and contraction direction of the second electrode assembly, and the moving assembly includes a slider 11 abutting against the stopper 8 and an elastic portion 12 having one end connected to the slider 11 and the other end connected to the case 2; the elastic part 12 is telescopically arranged in the expansion and contraction direction of the second electrode assembly.

Preferably, the elastic portion 12 is a slider spring, one end of which is connected to the slider 11 and the other end is connected to the housing 2.

The surface of the slide block 11 contacting the stopper 8 is a first inclined surface 111 disposed obliquely, and the stopper 8 is provided with a second inclined surface 81 engaged with the first inclined surface 111.

In the using process, under the normal using state of the battery fixing mechanism, the stop block 8 is positioned at the first position, and the second electrode assembly can be normally stretched; when the battery fixing mechanism is impacted or suddenly stops in a fast motion state, the sliding block 11 can extrude the sliding block spring under the action of inertia in the process that the battery 3 moves towards the second electrode assembly, and the sliding block 11 is in contact with the stop block 8 through the first inclined surface 111 and the second inclined surface 81, so that the sliding block 11 can push the stop block 8 to move upwards until the stop block 8 moves to the second position, and the stop block 8 can reach the second position before the telescopic end of the second limiting assembly, so that the compression stroke of the second electrode assembly is limited, the situation that the second electrode assembly is compressed excessively to separate the first electrode assembly from the first electrode of the battery 3 is avoided, and the disconnection and power failure of the battery 3 can be effectively avoided.

In this embodiment, in order to allow the stopper 8 to smoothly reach the second position prior to the second position-limiting assembly, the following aspects can be considered in combination: first, the elastic coefficient of the elastic part 12 may be set to be much smaller than that of the second electrode spring 7, and the compression distance of the elastic part 12 by the slider 11 is greater than that of the second electrode spring 7 when the battery fixing mechanism is suddenly stopped in an impact or a rapid movement state; in addition, by adjusting the angle between the first inclined surface 111 and the extending and contracting direction of the elastic portion 12, for example, the angle between the first inclined surface 111 and the extending and contracting direction of the elastic portion 12 may be set to be greater than 45 °, and in the case where the compression distance of the elastic portion 12 is the same, the stopper 8 may be displaced more than in the case where the angle between the first inclined surface 111 and the extending and contracting direction of the elastic portion 12 is smaller than 45 °; or the mass of the sliding block 11 can be increased, so that the sliding block 11 has larger inertia; the friction force between the slide block 11 and the shell 2 can be reduced, so that the slide block 11 has higher acceleration when being impacted; the method is determined according to actual conditions.

Preferably, the angle between the first inclined surface 111 and the expansion direction of the elastic portion 12 is less than or equal to 45 °.

In order to enable the stopper 8 to reach the second position before the telescopic end of the second electrode assembly, the included angle between the first inclined surface 111 and the telescopic direction of the elastic part 12 can be increased or the elastic coefficient of the slider spring can be reduced, and the specific arrangement condition needs to be determined according to actual conditions, and generally, the second electrode assembly comprises a second electrode cap 5 for abutting against the second electrode of the battery 3 and a second electrode spring 7 for connecting the second electrode cap 5 and the shell 2; the elastic coefficient of the second electrode spring 7 is larger than that of the slider spring. And the second electrode spring 7 has a large elastic coefficient in order to fix the battery 3, and the slider 11 has a small elastic coefficient in order to be moved quickly when an impact is applied thereto, and the second electrode spring 7 has an elastic coefficient much larger than that of the slider spring.

In a specific embodiment, as shown in fig. 14 and 15, in order to limit the direction of the stopper 8 moving between the first position and the second position, a guide rail 23 is convexly provided inside the battery compartment, the stopper 8 is provided with a guide groove 82 engaged with the guide rail 23, and the stopper 8 is slidable along the guide rail 23 to the first position and the second position. Of course, the guide rail 23 may be provided on the stopper 8, and the guide groove 82 matched with the guide rail 23 may be provided on the inner wall of the battery compartment, which is determined according to the actual situation.

The sliding block device further comprises a support 10 fixedly arranged on the shell 2, the support 10 is provided with a sliding groove 102, and the sliding block 11 is provided with a sliding convex part 112 matched with the sliding groove 102; during use, the sliding direction of the sliding chute 102 can be limited by the cooperation of the sliding chute 102 and the sliding protrusion 112.

The bracket 10 is fixedly connected to the housing 2 through a screw 13, a protrusion 101 is disposed at one end of the bracket 10 facing the second electrode assembly, a through hole is disposed on the stopper 8, and the second electrode spring 7 penetrates through the through hole and is sleeved on the protrusion 101.

In the using process, the second electrode spring 7 penetrates through the through hole of the limiting assembly to be connected with the support 10, and when the limiting assembly is located at the first position, as shown in fig. 5-9, the second electrode cap 5 can enter the through hole, so that the second electrode assembly has enough expansion and contraction amount, and the battery 3 is conveniently placed in the through hole.

Preferably, the protrusion 101 is located in a through hole of the stopper 8.

In one embodiment, a support portion 9 is provided on a side of the stopper 8 facing the upper cover 1, one end of the support portion 9 is in contact with the housing 2, and the other end is in contact with the stopper 8; in the using process, when the battery fixing mechanism is not impacted, as shown in fig. 10, the supporting part 9 can play a certain supporting role, so that the limiting component is prevented from randomly shaking in the battery bin; in addition, as shown in fig. 13, when the battery fixing mechanism is impacted, the moving assembly pushes the stopper 8 to move to the second position, the supporting portion 9 is squeezed, the supporting portion 9 can play a role in buffering, and collision of the limiting assembly in the moving process is avoided.

The supporting portion 9 is a reset sponge or an elastic component, a magnetic component, etc., of course, the supporting portion 9 may also be made of other materials meeting the requirements, and is determined according to the actual situation.

In a particular embodiment, the first electrode assembly comprises a first electrode cap 4 for abutment with a first electrode of the battery 3 and a first electrode spring 6 connecting the first electrode cap 4 with the casing 2.

As shown in fig. 8, one end of the housing 2 in the axial direction of the battery compartment is provided with a first sidewall 21, the other end is provided with a second sidewall 22, the first electrode cap 4 movably penetrates through the first sidewall 21, and the first electrode cap 4 is provided with a first rib 41 which can limit the distance that the first electrode cap 4 extends from the first sidewall 21; the second electrode cap 5 movably penetrates through the second side wall 22, and the second electrode cap 5 is provided with a second stop edge 51 which can limit the distance that the second electrode cap 5 extends out of the second side wall 22; in general, the length of the second electrode cap 5 protruding relative to the second sidewall 22 is much longer than the length of the first electrode cap 4 protruding relative to the first sidewall 21; in the mounted state of the battery 3, the second electrode spring 7 pushes the battery 3 to the first side wall 21, and the battery 3 can move toward only one end of the second electrode assembly during the rapid movement of the battery fixing mechanism.

Besides the battery fixing mechanism, the present invention further provides a human-computer interaction device including the battery fixing mechanism disclosed in the above embodiments, and the structure of other parts of the human-computer interaction device refers to the prior art, which is not described herein again.

The human-computer interaction device in the above specific embodiment may be a game handle including a battery fixing mechanism, a mouse, or other products, and is specifically determined according to actual conditions.

The first and second electrode springs 6 and 7, the first and second electrode caps 4 and 5, the first and second sidewalls 21 and 22, and the first and second slopes 111 and 81 mentioned in this document are only for distinguishing the difference of positions and are not in sequence.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. Any combination of all embodiments provided by the present invention is within the scope of the present invention, and will not be described herein.

The man-machine interaction device and the battery fixing mechanism thereof provided by the invention are described in detail above. The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims (10)

1. A battery securing mechanism comprising: a case (2) provided with a battery compartment, a first electrode assembly, and a second electrode assembly; one end of each of the first electrode assembly and the second electrode assembly is connected with the shell (2), and the other end of each of the first electrode assembly and the second electrode assembly can elastically stretch and retract along the axial direction of the battery bin;

a limiting component and a moving component are arranged in the shell (2), the limiting component, the moving component and the second electrode component are all located on the same side of the battery compartment, the moving component is used for pushing the limiting component to move between a first position and a second position, one end of the moving component is connected with the shell (2), and the other end of the moving component is abutted to the limiting component and can elastically stretch out and draw back;

the limiting assembly in the first position avoids a telescopic path of the second electrode assembly; the second position is located on a telescoping path of the second electrode assembly, the restraining assembly in the second position obstructs compression of the second electrode assembly, and the restraining assembly reaches the second position before the second electrode assembly is compressed to the second position;

the limiting assembly is located at the second position, and in the installation state of the battery (3), the continuous compressible amount of the second electrode assembly is smaller than or equal to the current compressible amount of the first electrode assembly, and the continuous compressible amount of the first electrode assembly is smaller than or equal to the current compressible amount of the second electrode assembly.

2. The battery fixing mechanism according to claim 1, wherein the limiting assembly comprises a stopper (8) movably arranged in a direction perpendicular to the extension and contraction direction of the second electrode assembly, and the moving assembly comprises a slider (11) abutting against the stopper (8) and an elastic part (12) having one end connected with the slider (11) and the other end connected with the housing (2);

the elastic part (12) is arranged in a telescopic manner along the telescopic direction of the second electrode assembly.

3. The battery fixing mechanism according to claim 2, wherein the surface of the slider (11) contacting the stopper (8) is a first inclined surface (111) provided obliquely, and the stopper (8) is provided with a second inclined surface (81) engaging with the first inclined surface (111).

4. The battery fixing mechanism according to claim 3, wherein an angle between the first slope (111) and a direction of extension and contraction of the elastic portion (12) is less than or equal to 45 °.

5. The battery fixing mechanism according to claim 2, further comprising a bracket (10) fixed to the housing (2), wherein the bracket (10) is provided with a sliding groove (102), and the slider (11) is provided with a sliding protrusion (112) engaged with the sliding groove (102).

6. A battery fixation mechanism according to claim 2, wherein the second electrode assembly comprises a second electrode cap (5) for abutment with a second electrode of the battery (3) and a second electrode spring (7) connecting the second electrode cap (5) and the case (2);

the elastic part (12) is a slider spring, and the elastic coefficient of the second electrode spring (7) is greater than that of the slider spring.

7. A battery fixation mechanism according to claim 1, wherein the first electrode assembly comprises a first electrode cap (4) for abutment with a first electrode of the battery (3) and a first electrode spring (6) connecting the first electrode cap (4) with the housing (2);

a first side wall (21) is arranged at one axial end of the battery bin of the shell (2), a second side wall (22) is arranged at the other axial end of the battery bin, the first electrode cap (4) movably penetrates through the first side wall (21), and the second electrode cap (5) movably penetrates through the second side wall (22);

the second electrode spring (7) urges the battery (3) to the first side wall (21) in the mounted state of the battery (3).

8. The battery fixing mechanism according to claim 7, wherein the first electrode cap (4) is provided with a first rib (41), the first rib (41) being used to limit the length of the first electrode cap (4) protruding from the first side wall (23); the second electrode cap (5) is provided with a second rib (51), and the second rib (51) is used for limiting the length of the second electrode cap (5) extending out of the second side wall (24).

9. The battery fixing mechanism according to any one of claims 2 to 8, wherein a support portion (9) is provided on a side of the stopper (8) facing the housing (2), one end of the support portion (9) abuts against the housing (2), and the other end abuts against the stopper (8);

the supporting part (9) is arranged opposite to the moving component; when the sliding block (11) does not push the stop block (8) to move, the supporting part (9) pushes the stop block (8) to the first position.

10. A human-computer interaction device, characterized in that it comprises a battery holding mechanism according to any one of claims 1 to 9.

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