CN110444708B - Reverse sliding pressing buckle mechanism, battery converter, battery and electric drive vehicle - Google Patents

Abstract

The reverse sliding pressing buckle mechanism, the battery converter, the battery and the electric drive vehicle aim at enabling the clamping hook to move upwards to be connected with the clamping groove on the battery shell. The technical key points are as follows: the clamping structure comprises a shell, a pressing plate, a clamping hook and a lifting mechanism, wherein the pressing plate is arranged on a top plate of the shell, the clamping hook and the lifting mechanism are arranged in the shell, the pressing plate drives the clamping hook to move up and down through the lifting mechanism, and when the pressing plate is pressed down, the lifting mechanism drives the clamping hook to move upwards, and an avoidance groove for accommodating the extension of the clamping hook is vertically formed in the shell. The lifting mechanism comprises a driving rack, a driven rack and a reversing gear, the driving rack is arranged on the pressing plate, the driven rack is arranged on the shell in a sliding mode, the reversing gear is meshed with the driving rack and the driven rack, and the clamping hook is arranged on the driven rack. According to the invention, the clamping hook is driven to move upwards by the lifting mechanism driven by the pressing plate to be connected with the clamping groove, and the clamping hook is reset to be separated from the bayonet by pressing the pressing plate again, so that the battery converter can be conveniently plugged and unplugged.

Description

Reverse sliding pressing buckle mechanism, battery converter, battery and electric drive vehicle

Technical field:

the invention relates to the technical field of connection of a battery and a battery converter in an electric bicycle, in particular to a reverse sliding pressing buckle mechanism, a battery converter, a battery and an electric drive vehicle.

The background technology is as follows:

the mechanical connection mode between the battery and the battery converter used by the existing electric bicycle mainly adopts a screw fixing mode to connect the battery and the battery converter, so that the battery converter is not easy to be inserted and pulled by a user by hands, and the user experience is affected. In order to solve the problem, the company develops a structure capable of conveniently plugging and unplugging the battery converter, and mainly adopts a mode that a clamping groove is formed in a battery shell, a clamping hook capable of moving up and down is arranged on the battery converter, and the clamping groove is clamped when the clamping hook moves down, so that the mechanical connection between a battery and the battery converter is realized. The setting of this kind of structure makes the user directly press the part that drives the pothook and remove on the battery converter just can bare-handed take off battery converter from the battery, and its convenient operation is swift, labour saving and time saving has improved user's experience effect greatly. Because of the diversification of battery products designed by the company, the clamping grooves arranged on the shell of some batteries need to be moved upwards to be matched with the clamping hooks, and obviously, the mode of enabling the clamping hooks to move downwards to be matched with the clamping grooves in the structure is not suitable for the mechanical connection between the batteries and the battery converter.

The invention comprises the following steps:

the present invention provides a reverse sliding pressing buckle mechanism, a battery converter, a battery and an electric drive vehicle, which can connect a clamping hook with a clamping groove arranged on a battery shell when the clamping hook moves upwards.

The invention relates to a reverse sliding pressing buckle mechanism for a battery converter, which adopts the following technical scheme: the lifting mechanism drives the clamping hook to move upwards when the pressing plate is pressed down, and an avoidance groove for accommodating the extension of the clamping hook is vertically formed in the shell.

Preferably, the lifting mechanism comprises a driving rack, a driven rack and a reversing gear, the driving rack is arranged on the pressing plate, the driven rack is arranged on the shell in a vertical sliding mode, the reversing gear is respectively in meshed transmission with the driving rack and the driven rack, the reversing gear is arranged in the shell through a fixing shaft, the clamping hook is arranged on the driven rack, when the pressing plate is not pressed, the lower end of the driving rack 5 is meshed with the reversing gear, and the upper end of the reversing gear is meshed with the reversing gear.

Preferably, a reset spring which can make the pressing plate spring upwards is arranged between the pressing plate and the shell.

Preferably, a cover body is arranged on the shell, and the avoidance groove is formed in the cover body.

Preferably, the hooks are arranged in two, the lifting mechanisms are arranged in two groups, the two hooks are symmetrically arranged on the shell, and the two groups of lifting mechanisms are symmetrically arranged in the shell.

Preferably, the left end and the right end of the pressing plate extend outwards to form clamping shoulders, and the clamping shoulders are lower than the top surface of the pressing plate and are positioned below the top plate of the shell.

Preferably, a fixed chute is vertically arranged on the driven rack, and a fixed screw penetrates through the vertical fixed chute to fix the driven rack on the shell.

Preferably, limit baffles are arranged on the shell beside the left side and the right side of the reversing gear.

Preferably, an abutment plate is arranged on the shell, and the back of the reversing gear abuts against the abutment plate so as to enable the driven rack to be meshed with the reversing gear.

Preferably, a guide groove with an open bottom end is formed in the side wall of the shell, and a guide convex plate extends out of one side of the driving rack, which faces the shell, and is inserted into the guide groove.

Preferably, a reset plate with a horizontally arranged top surface is arranged in the shell, and the reset spring is arranged between the pressing plate and the reset plate.

Preferably, the cross section of the driven rack is in an inverted L shape, the rack of the driven rack is arranged on a vertical plate forming the inverted L shape, the fixed chute is arranged on a horizontal plate forming the inverted L shape, and the clamping hook is arranged on the side surface of the vertical plate facing the cover body.

Preferably, an upper connecting column is arranged on the bottom surface of the pressing plate, a lower connecting column is arranged on the upper surface of the reset plate, and the upper end and the lower end of the reset spring are respectively fixed on the upper connecting column and the lower connecting column.

Preferably, the reset plate is in an inverted L shape, and a vertical plate forming the inverted L shape is connected with the shell.

Preferably, two return springs are arranged and symmetrically arranged on the composite plate.

The invention relates to a battery converter, which adopts the following technical scheme: the battery converter comprises the reverse sliding pressing buckle mechanism for the battery converter.

The battery shell of the invention adopts the technical scheme that: and the battery shell is provided with a clamping groove matched with the clamping hook in the reverse sliding pressing clamping mechanism.

The battery of the invention adopts the technical scheme that: the battery comprises the battery shell, and the battery is connected with external equipment through the battery converter.

The invention relates to an electric drive vehicle, which adopts the following technical scheme: the battery comprises the battery.

The beneficial effects of the invention are as follows:

the invention sets up the clamp plate on the top of the body, set up the lifting gearing in the body, the lifting gearing includes driving rack and driven rack that locates on clamp plate and slides and locates on body, there are reversing gears that intermesh with both driving rack and driven rack, make the direction of movement of driving rack and driven rack opposite forever through reversing gears, and the hook is located on driven rack, so, when pressing the clamp plate, the hook will move and align with the draw-in groove that the body of the battery is offered along with the driven rack is horizontal, after the contact pin of the battery converter inserts the jack of the battery, the hook can enter into the draw-in groove, at this moment unclamp the clamp plate again, the clamp plate is raised back under the action of the reset spring and driven hook moves downward, make the hook catch the edge of the draw-in groove, in order to realize the mechanical connection between battery converter and battery; the clamping hook can be separated from the clamping groove by pressing the pressing plate again and pulling out the battery converter, so that the battery converter is completely separated from the battery, and the aim of connecting the clamping hook with the clamping groove arranged on the shell of the battery when the clamping hook moves upwards is fulfilled.

According to the invention, the battery converter and the outer shell of the battery are more conveniently and quickly connected by adopting the structure, and the mechanical connection between the battery converter and the outer shell of the battery is established by the clamping hooks, so that the battery converter and the battery can be quickly connected by hands without tools, and the operation of a user is convenient.

Description of the drawings:

FIG. 1 is an exploded view of the present invention;

fig. 2 is a front view of the internal structure of the housing;

FIG. 3 is an isometric view of the internal structure of the housing;

FIG. 4 is an isometric view of the housing itself;

FIG. 5 is an assembled view of the present invention;

FIG. 6 is an isometric view of a platen;

FIG. 7 is a block diagram of a driven rack;

fig. 8 is a schematic structural view of a battery;

in the figure, 1 is a shell, 2 is a pressing plate, 3 is a clamping hook, 4 is an avoidance groove, 5 is a driving rack, 6 is a driven rack, 7 is a reversing gear, 8 is a fixed shaft, 9 is a reset spring, 10 is a cover body, 11 is a clamping shoulder, 12 is a fixed chute, 13 is a fixing screw, 14 is a limit baffle, 15 is an abutting plate, 16 is a reset plate, 17 is an upper connecting column, 18 is a lower connecting column, 19 is a containing opening, 20 is a cover body connecting column, 21 is a reinforcing beam, 22 is a guide groove, 23 is a guide convex plate, 24 is a driven rack connecting column, 25 is a battery shell, 61 is a horizontal plate, 62 is a vertical plate, and 162 is a vertical plate.

The specific embodiment is as follows:

the battery converter in this embodiment mainly includes a housing 1, a cover 10, a pressing plate 2, two hooks 3 and two sets of lifting mechanisms, as shown in fig. 1, 2, 3 and 5, where the pressing plate 2 is horizontally disposed on a top plate of the housing 1, as shown in fig. 1 and 4, a receiving opening 19 for receiving the pressing plate 2 is formed in the top plate of the housing 1, so that the pressing plate 2 can move up and down on the housing 1. As shown in fig. 1, 2 and 3, two sets of lifting mechanisms are symmetrically arranged in the shell 1, two hooks 3 are respectively arranged on the two lifting mechanisms, the pressing plate 2 drives the hooks 3 to move up and down through the lifting mechanisms, and when the pressing plate 2 is pressed down, the pressing plate 2 drives the hooks 3 to move up through the lifting mechanisms, as shown in fig. 1 and 5, the cover body 10 is buckled on the shell 1, and an avoidance groove 4 for allowing the hooks 3 to extend out is vertically formed in the cover body 10.

As shown in fig. 1, 2, 3 and 4, a cover connecting post 20 extending horizontally towards the cover 10 is provided in the housing 1, the cover connecting post 20 is provided with a screw hole, and a screw hole is provided on the cover 10 at a position opposite to the cover connecting post 20, so that the cover 10 is fastened to the housing 1 by a screw.

As shown in fig. 1, 2 and 3, the lifting mechanism in this embodiment includes a driving rack 5, a driven rack 6 and a reversing gear 7, where the driving rack 5 and the reversing gear 7 are vertically arranged in parallel, the top end of the driving rack 5 is fixed on the bottom surface of the pressing plate 2, one end of a fixed shaft 8 of the reversing gear 7 is fixed on the side wall of the housing 1, the other end faces the cover 10, the driven rack 6 is arranged on the housing 1 in a sliding manner up and down, the reversing gear 7 is respectively meshed with the driving rack 5 and the driven rack 6, the hook 3 is arranged on the driven rack 6, the pressing plate 2 is in an initial state of the fastening mechanism when not pressed, and in the initial state, the lower end of the driving rack 5 in this embodiment is meshed with the reversing gear 7, and the upper end of the reversing gear 7 is meshed with the reversing gear 7. In this embodiment, since the reversing gear 7 is disposed between the driving rack 5 and the driven rack 6, the moving directions of the driving rack 5 and the driven rack 6 are always opposite, so that it is ensured that the hook 3 moves upward along with the driven rack 6 after the pressing plate 2 is pressed, and it is ensured that the pressing plate 2 moves downward after the pressing plate 2 is released by the reset spring 9 after the pressing plate 2 is lifted and reset.

As shown in fig. 1 and 4, the back of the driving rack 5 is propped against the stiffening beam 21, the top end of the stiffening beam 21 is integrated with the pressing plate 2, the stiffening beam 21 increases the stability of the driving rack 5, as shown in fig. 6, a guide convex plate 23 is arranged on the surface of the stiffening beam 21 adjacent to the shell 1, as shown in fig. 1 and 4, a guide groove 22 with an open bottom end is arranged on the side wall of the shell 1, the guide groove 22 is formed by two vertically arranged plate bodies, the guide convex plate 23 is inserted into the guide groove 22, so that the stiffening beam 21 is limited and guided by the guide groove 22, the stiffening beam 21 runs more stably, and further, the driving rack 5 is prevented from shaking to influence the meshing transmission of the reversing gear 7.

As shown in fig. 7, the cross section of the driven rack 6 is in an inverted L shape, the horizontal plate 61 forming the inverted L shape is provided with the fixed chute 12, the rack of the driven rack 6 is provided on the vertical plate 62 forming the inverted L shape, and the hook 3 is provided on the side surface of the vertical plate 62 facing the cover 10. As shown in fig. 1 and 4, the housing 1 is provided with an abutment plate 15, the abutment plate 15 is formed by three plate bodies parallel to each other and perpendicular to the side wall of the housing 1, the inner side end of the plate body is made into a whole with the side wall of the housing 1, the plate body in the middle position is provided with a driven rack connecting post 24, the driven rack connecting post 24 is provided with a screw hole, and as shown in fig. 2, the horizontal plate 61 of the driven rack 6 is fixed on the abutment plate 15 by connecting the fixed screw 13 through the fixed chute 12 and the driven rack connecting post 24. As shown in fig. 1 and 4, since the fixed shaft 8 of the reversing gear 7 has a certain length, the driven rack 6 needs to be in the same plane as the reversing gear 7 when the driven rack 6 is meshed with the reversing gear 7, and thus the driven rack 6 can be arranged in a direction approaching the cover 10 by the abutment plate 15 to be in contact with the reversing gear 7. If the horizontal plate 61 of the driven rack 6 is directly contacted with the housing 1 without the abutting plate 15, the fixing screw 13 is directly screwed on the side wall of the housing 1, so that the surface of the housing 1 is increased in damage, and the housing 1 is worn when the driven rack 6 moves up and down; if the driven rack 6 is fixed by directly providing the driven rack connecting post 24 and the fixing screw 13 without providing the abutting plate 15, the driven rack 6 is not necessarily stable enough in the front-rear direction. If the driven rack 6 is unstable and shakes back and forth, the smooth operation of the meshing transmission with the reversing gear 7 is affected, and finally the lifting mechanism cannot drive the clamping hook 3 to move up and down.

As shown in fig. 1, 2 and 4, the casing 1 is provided with a limit baffle 14 beside the left and right sides of the reversing gear 7, the limit baffle 14 on one side of the reversing gear 7 is located below the reversing gear 7 so as not to affect the meshing transmission between the driven rack 6 and the reversing gear 7, and the limit baffle 14 on the other side is arranged above the driven rack 6, so that the two limit baffles 14 are located at the upper and lower ends of the left and right sides of the driven rack 6 respectively, and can effectively prevent the left and right shaking of the upper and lower ends of the driven rack 6 and ensure smooth meshing transmission between the driven rack 6 and the reversing gear 7.

As shown in fig. 1, 2 and 3, a return spring 9 is disposed between the pressing plate 2 and the housing 1 in this embodiment, specifically, a horizontal return plate 16 is disposed in the housing 1, as shown in fig. 1 and 3, the return plate 16 may be an inverted L-shaped, a vertical plate 162 forming an inverted L-shape is connected with the housing 1 by means of screws or adhesion, as shown in fig. 1 and 2, a lower connecting post 18 is disposed on the upper surface of the vertical plate 162 forming an inverted L-shape, an upper connecting post 17 is disposed on the bottom surface of the pressing plate 2, and the upper and lower ends of the return spring 9 are respectively fixed on the upper and lower connecting posts 17 and 18, so that when the pressing of the pressing plate 2 is released, the pressing plate 2 is sprung upward under the action of the return spring 9 to return. Two return springs 9 are symmetrically arranged on the vertical plate 162.

As shown in fig. 1 and 6, the left and right ends of the pressing plate 2 in the present embodiment extend outwards to form a shoulder 11, and the shoulder 11 is lower than the top surface of the pressing plate 2 and is located below the top plate of the housing 1, so that the pressing plate 2 is disposed on the top of the housing 1, and the pressing plate 2 is prevented from being separated from the housing 1 when rebound and rising under the action of the return spring 9.

The working process comprises the following steps:

when the battery converter is installed, as shown in fig. 1, 2 and 3, the pressing plate 2 is pressed down, the driving rack 5 moves downwards along with the pressing plate 2 to drive the reversing gear 7 to rotate, then the reversing gear 7 drives the driven rack 6 to move upwards, the clamping hook 3 on the driven rack 6 moves upwards along with the reversing gear 6 to be horizontally aligned with a clamping groove formed in the shell of the battery, meanwhile, the shell 1 is pushed to move towards the shell of the battery, so that a contact pin arranged on the battery converter is matched with a jack formed in the shell of the battery, the battery converter is electrically connected with the battery, the battery converter is contacted with the shell of the battery, the clamping hook 3 is inserted into the clamping groove, then the pressing plate 2 is released, the pressing plate 2 is sprung upwards to reset under the action of the reset spring 9, the driving rack 5 moves backwards along with the pressing plate 2 to rotate reversely to enable the driven rack 6 to descend, and finally the clamping hook 3 descends to hook the edge of the clamping groove;

when the battery converter is pulled out, as shown in fig. 1, 2 and 3, the pressing plate 2 is pressed down, the driven rack 6 is driven to move upwards by the driving rack 5 through the reversing gear 7, so that the clamping hook 3 moves upwards again to be opposite to the bayonet, the battery converter is pulled out outwards at the same time, the clamping hook 3 comes out from the bayonet, the pressing plate 2 is loosened, the pressing plate 2 is reset to drive the clamping hook 3 to descend to restore to the initial state, and the separation of the battery converter and the battery is completed.

The battery converter in the present embodiment includes the battery converter with the above-described structure using the reverse sliding pressing buckle mechanism.

The battery case in this embodiment is provided with a clamping groove matched with the clamping hook in the reverse sliding pressing clamping mechanism.

The battery in the embodiment comprises the battery shell, and the battery is connected with external equipment through the battery converter.

The electric drive vehicle in the present embodiment includes the above-described battery.

Claims (16)

1. The utility model provides a reverse slip presses buckle mechanism for battery converter which characterized in that: including casing (1), clamp plate (2), pothook (3), elevating system, reset spring (9) and reset plate (16), on the roof of casing (1) was located to clamp plate (2), in pothook (3) and elevating system located casing (1), clamp plate (2) were passed through elevating system drive pothook (3) and were reciprocated, when pressing clamp plate (2) down, elevating system drive pothook (3) upwards moved, dodge groove (4) that hold pothook (3) stretched out were seted up to vertical on casing (1), between clamp plate (2) and reset plate (16) were located to reset spring (9) to can make clamp plate (2) rebound upwards, when clamp plate (2) upwards moved, elevating system drive pothook (3) downwardly move.

2. The reverse slide pressing buckle mechanism for a battery converter according to claim 1, wherein: the lifting mechanism comprises a driving rack (5), a driven rack (6) and a reversing gear (7), wherein the driving rack (5) is arranged on the pressing plate (2), the driven rack (6) is arranged on the shell (1) in a vertical sliding mode, the reversing gear (7) is respectively in meshed transmission with the driving rack (5) and the driven rack (6), the reversing gear (7) is arranged in the shell (1) through a fixing shaft (8) of the reversing gear, and the clamping hook (3) is arranged on the driven rack (6).

3. The reverse slide pressing buckle mechanism for a battery converter according to claim 1, wherein: the return spring (9) is arranged between the pressing plate (2) and the shell (1).

4. The reverse slide pressing buckle mechanism for a battery converter according to claim 1, wherein: the shell (1) is provided with a cover body (10), and the avoidance groove (4) is formed in the cover body (10).

5. The reverse slide pressing buckle mechanism for a battery converter according to claim 1, wherein: the left end and the right end of the pressing plate (2) extend outwards to form clamping shoulders (11), and the clamping shoulders (11) are lower than the top surface of the pressing plate (2) and are positioned below the top plate of the shell (1).

6. The reverse slide pressing buckle mechanism for a battery converter according to claim 1, wherein: the battery converter is with reverse slip pressing buckle mechanism includes two at least elevating system and two at least pothooks (3), two pothooks (3) symmetry set up on casing (1), two elevating system symmetry sets up in casing (1).

7. The reverse slide pressing buckle mechanism for a battery converter according to claim 2, wherein: a fixed chute (12) is vertically formed in the driven rack (6), and a fixed screw (13) penetrates through the fixed chute (12) to fix the driven rack (6) on the shell (1).

8. The reverse slide pressing buckle mechanism for a battery converter according to claim 2, wherein: limit baffles (14) are arranged on the shell (1) beside the left side and the right side of the reversing gear (7).

9. The reverse slide pressing buckle mechanism for a battery converter according to claim 2, wherein: an abutting plate (15) is arranged on the shell (1), and the back of the reversing gear (7) abuts against the abutting plate (15) so that the driven rack (6) and the reversing gear (7) are meshed with each other.

10. The reverse slide pressing buckle mechanism for a battery converter according to claim 2, wherein: the side wall of the shell (1) is provided with a guide groove (22) with an open bottom end, and a guide convex plate (23) extends out of one side of the driving rack (5) towards the shell (1) and is inserted into the guide groove (22).

11. The reverse slide pressing buckle mechanism for a battery converter according to claim 7, wherein: the cross section of driven rack (6) is in an inverted L shape, fixed chute (12) is arranged on horizontal plate (61) forming the inverted L shape, rack of driven rack (6) is arranged on vertical plate (62) forming the inverted L shape, and hook (3) is arranged on the side of vertical plate (62) facing to cover body (10).

12. The reverse slide pressing buckle mechanism for a battery converter according to claim 1, wherein: the bottom surface of clamp plate (2) is equipped with spliced pole (17), the upper surface of reset plate (16) is equipped with down spliced pole (18), upper and lower both ends of reset spring (9) are fixed respectively on upper spliced pole (17) and lower spliced pole (18).

13. A battery converter, characterized by: a reverse sliding press buckle mechanism for a battery converter according to any one of claims 1 to 12.

14. A battery housing, characterized in that: the battery shell is provided with a clamping groove matched with a clamping hook (3) in the reverse sliding pressing clamping mechanism for the battery converter according to any one of claims 1 to 12.

15. A battery, characterized in that: comprising a battery housing (25) according to claim 14, the battery being connected to an external device via a battery converter according to claim 14.

16. An electrically driven vehicle, characterized in that: comprising the battery of claim 15.