CN216818431U - Nickel-hydrogen cylinder battery electricity core winding mechanism - Google Patents

Abstract

The utility model discloses a nickel-hydrogen cylinder battery electricity core winding mechanism, including the support frame, there is the screw rod in the axle center department of the adjacent both ends inner wall of support frame through bearing swing joint, and threaded connection has first spiral shell section of thick bamboo and second spiral shell section of thick bamboo respectively at the both ends of screw rod lateral wall, installs first mobile station and second mobile station through the bolt on the top outer wall of first spiral shell section of thick bamboo and second spiral shell section of thick bamboo respectively. According to the utility model, the hand wheel drives the screw rod to rotate, the screw rod drives the first screw cylinder and the second screw cylinder which are in threaded connection to be close, the first screw cylinder and the second screw cylinder can drive the first mobile station and the second mobile station to be close, so that the first mobile station and the second mobile station can be effectively adjusted according to different lengths of the battery cells, the nut drives the lead screw to rotate, and the lead screw pushes the clamping plate to clamp and position the battery cells in the fixing seat, so that the battery cells are more convenient to disassemble and fix, and the processing efficiency of winding the battery cells is improved.

Description

Nickel-hydrogen cylinder battery electricity core winding mechanism

Technical Field

The utility model relates to a nickel-hydrogen cylinder battery technique, concretely relates to nickel-hydrogen cylinder battery electricity core winding mechanism.

Background

The nickel-metal hydride battery is a storage battery with good performance. Nickel-metal hydride batteries are classified into high-voltage nickel-metal hydride batteries and low-voltage nickel-metal hydride batteries. The positive active material of the nickel-metal hydride battery is Ni (OH) 2 (named as NiO electrode), the negative active material is metal hydride, also named as hydrogen storage alloy (the electrode is named as hydrogen storage electrode), and the electrolyte is 6mol/L potassium hydroxide solution. Nickel-metal hydride batteries are gaining increasing attention as an important direction for hydrogen energy applications.

For example, in the battery cell winding device with the authorization notice number of CN201270273Y and the authorization notice date of 2009-07-08, pressing devices driven by a driving mechanism to move up and down are mounted on the work tables on both sides of the winding needle, each pressing device comprises a pressing roller and a pressing cover, and the pressing rollers are connected with the pressing covers through springs.

Above-mentioned and in prior art, nickel-hydrogen cylinder battery electricity core winding mechanism can't adjust according to the difference of electric core length, and it is comparatively inconvenient to dismantle after electric core is convoluteed and is accomplished simultaneously, has reduced the machining efficiency that electric core was convoluteed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a nickel-hydrogen cylindrical battery electricity core winding mechanism to solve the above-mentioned weak point among the prior art.

In order to achieve the above object, the present invention provides the following technical solutions: the utility model provides a nickel-hydrogen cylinder battery electricity core winding mechanism, includes the support frame, there is the screw rod axle center department of the adjacent both ends inner wall of support frame through bearing swing joint, and the both ends of screw rod lateral wall threaded connection has first spiral shell section of thick bamboo and second spiral shell section of thick bamboo respectively, install first mobile station and second mobile station through the bolt on the top outer wall of first spiral shell section of thick bamboo and second spiral shell section of thick bamboo respectively, and the center department of the adjacent one side outer wall of first mobile station and second mobile station all has the fixing base that is equidistant structure and distributes through bearing swing joint, the one end welding that the screw rod runs through the support frame has the hand wheel, and has cup jointed the sponge sleeve on the lateral wall of hand wheel.

As this practical preferred embodiment, the constant head tank has all been seted up to the both sides of support frame top outer wall, and the axle center department welding of constant head tank has the guide bar, cup jointed along the gliding locating piece of constant head tank on the lateral wall of guide bar, and be fixed connection between locating piece and first mobile station and the second mobile station.

As the preferred embodiment of this utility model, equal threaded connection has the lead screw on the both sides outer wall of fixing base, and the lead screw is located the outside one end welding of fixing base and has changeed female, the anti-skidding stripe has been seted up on changeing female lateral wall.

As the preferred embodiment of this utility model, the one end that the lead screw is located the fixing base inside has splint through bearing swing joint, and splint are the arc structure, it has the rubber pad to bond on the splint keep away from the opposite side outer wall of lead screw.

As this practical preferred embodiment, the center department of first mobile station one side outer wall has the transmission axostylus axostyle that is the transmission and is connected with the fixing base through bearing swing joint, and the parallel key is connected with the band pulley on the lateral wall of transmission axostylus axostyle, cup jointed the hold-in range on the lateral wall of band pulley.

As the preferred embodiment of this utility model, install the housing that covers the outside at the band pulley through the bolt on one side outer wall of first mobile station, and the center department of housing one side outer wall installs through the bolt and is the motor that the transmission is connected with the transmission axostylus axostyle.

In the above technical scheme, the utility model provides a winding mechanism for a nickel-hydrogen cylindrical battery cell, (1) through the first mobile station and the second mobile station that are arranged, the hand wheel drives the screw rod to rotate, the screw rod drives the first screw cylinder and the second screw cylinder that are in threaded connection to be drawn close together, and the first screw cylinder and the second screw cylinder can drive the first mobile station and the second mobile station to be drawn close together, so that the first mobile station and the second mobile station can effectively adjust according to the difference of the cell length, the structure is novel, the adjustment is convenient, and the winding mechanism is suitable for popularization; (2) through the arranged fixing seat, the rotor drives the lead screw to rotate, and the lead screw pushes the clamping plate to clamp and position the electric core in the fixing seat, so that the electric core is more convenient to disassemble and fix, the processing efficiency of winding the electric core is improved, the structure is reasonable, the operation is convenient, and the practicability is high; (3) through the motor that sets up, the motor drives the transmission axostylus axostyle and rotates, and the transmission axostylus axostyle can drive the fixing base that the equidistance distributes simultaneously under the interact of band pulley and hold-in range and rotate to make electric core carry out coiling processing, fine promotion electric core convolute machining efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present application, and other drawings can be obtained by those skilled in the art according to the drawings.

Fig. 1 is a schematic view of a three-dimensional structure provided in an embodiment of a winding mechanism for a nickel-hydrogen cylindrical battery cell according to the present invention.

Fig. 2 is a schematic view of a transmission structure provided in an embodiment of the winding mechanism for a nickel-hydrogen cylindrical battery cell of the present invention.

Fig. 3 is a schematic diagram of a positioning groove structure provided in an embodiment of the winding mechanism for a nickel-hydrogen cylindrical battery cell of the present invention.

Fig. 4 is a schematic view of a fixing seat structure provided in an embodiment of the winding mechanism for a nickel-hydrogen cylindrical battery cell of the present invention.

Description of reference numerals:

1. a support frame; 2. a screw; 3. a first barrel; 4. a second barrel; 5. a hand wheel; 6. a first mobile station; 7. a second mobile station; 8. a motor; 9. a housing; 10. a drive shaft; 11. a pulley; 12. a synchronous belt; 13. a fixed seat; 14. positioning a groove; 15. a guide bar; 16. positioning blocks; 17. a lead screw; 18. rotating a nut; 19. a splint; 20. and (7) a rubber pad.

Detailed Description

In order to make the technical solutions of the present invention better understood, the present invention will be further described in detail with reference to the accompanying drawings.

As shown in fig. 1-4, the utility model provides a nickel-hydrogen cylindrical battery electric core winding mechanism, including support frame 1, there is screw rod 2 in the axle center department of the adjacent both ends inner wall of support frame 1 through bearing swing joint, and the both ends of the 2 lateral walls of screw rod have first spiral shell section of thick bamboo 3 and second spiral shell section of thick bamboo 4 respectively threaded connection, install first mobile station 6 and second mobile station 7 through the bolt on the top outer wall of first spiral shell section of thick bamboo 3 and second spiral shell section of thick bamboo 4 respectively, and the center department of the adjacent one side outer wall of first mobile station 6 and second mobile station 7 all has fixing base 13 that is equidistant structure and distributes through bearing swing joint, the one end welding that screw rod 2 runs through support frame 1 has hand wheel 5, and cup jointed the sponge sleeve on hand wheel 5's the lateral wall.

Specifically, in this embodiment, the hand wheel 5 drives the screw rod 2 to rotate, the screw rod 2 drives the first screw cylinder 3 and the second screw cylinder 4 which are in threaded connection to be close to each other, and the first screw cylinder 3 and the second screw cylinder 4 can drive the first mobile station 6 and the second mobile station 7 to be close to each other, so that the first mobile station 6 and the second mobile station 7 can be effectively adjusted according to the difference of the lengths of the battery cells.

The utility model provides a nickel-hydrogen cylindrical battery cell winding mechanism, which comprises a support frame 1, the axle center of the inner wall of the adjacent two ends of the support frame 1 is movably connected with a screw 2 through a bearing, the two ends of the outer wall of the screw 2 are respectively in threaded connection with a first screw barrel 3 and a second screw barrel 4, the outer walls of the tops of the first screw barrel 3 and the second screw barrel 4 are respectively provided with a first moving platform 6 and a second moving platform 7 through bolts, the centers of the outer walls of the adjacent sides of the first moving platform 6 and the second moving platform 7 are respectively in threaded connection with fixed seats 13 which are distributed in an equidistant structure through bearings, one end of the screw 2 penetrating through the support frame 1 is welded with a hand wheel 5, the outer wall of the hand wheel 5 is sleeved with a sponge sleeve, the hand wheel 5 drives the screw 2 to rotate, the screw 2 drives the first screw barrel 3 and the second screw barrel 4 which are in threaded connection to be close to each other, and the first screw barrel 3 and the second screw barrel 4 can drive the first moving platform 6 and the second moving platform 7 to be close to each other, so that the first mobile station 6 and the second mobile station 7 can be effectively adjusted according to different cell lengths.

The utility model provides another embodiment, as shown in fig. 1 and 3, constant head tank 14 has all been seted up to the both sides of support frame 1 top outer wall, and the welding of axle center department of constant head tank 14 has guide bar 15, cup joint along the gliding locating piece 16 of constant head tank 14 on the lateral wall of guide bar 15, and be fixed connection between locating piece 16 and first mobile station 6 and the second mobile station 7, locating piece 16 is along the inside of guide bar 15 sliding connection at constant head tank 14, it is firm to make first mobile station 6 and second mobile station 7 can be more stable when removing, the stability when having promoted electric core coiling man-hour simultaneously.

The utility model provides another embodiment, as shown in fig. 1 and 4, equal threaded connection has lead screw 17 on the both sides outer wall of fixing base 13, and lead screw 17 is located the outside one end welding of fixing base 13 and has changeed female 18, has seted up anti-skidding stripe on changeing female 18's the lateral wall, and the setup of protection stripe makes changeing female 18 have fine antiskid nature, makes the operator rotate convenient stability more when changeing female 18.

In another embodiment provided by the present invention, as shown in fig. 1 and fig. 4, the end of the screw 17 inside the fixing base 13 is movably connected to the clamp plate 19 through the bearing, and the clamp plate 19 is of an arc-shaped structure, the rubber pad 20 is bonded on the outer wall of the other side of the clamp plate 19 away from the screw 17, the screw 17 pushes the clamp plate 19 to clamp and position the electric core in the fixing base 13, so that the electric core is more convenient to detach and fix, and the rubber pad 20 plays a good role in protecting the electric core.

The utility model provides a still another embodiment, as shown in fig. 1 and fig. 2, the center department of the outer wall of 6 one sides of first mobile station has the transmission axostylus axostyle 10 that is the transmission and is connected with fixing base 13 through bearing swing joint, and the parallel key is connected with band pulley 11 on the lateral wall of transmission axostylus axostyle 10, synchronous belt 12 has been cup jointed on band pulley 11's the lateral wall, transmission axostylus axostyle 10 can drive the fixing base 13 that the equidistance distributes simultaneously under the interact through band pulley 11 and synchronous belt 12 and rotate, thereby make electric core carry out the coiling processing, fine promotion electric core convolute machining efficiency.

In still another embodiment provided by the present invention, as shown in fig. 1, the housing 9 covering the outside of the belt pulley 11 is installed on the outer wall of one side of the first mobile station 6 through the bolt, and the motor 8 connected with the transmission shaft 10 in a transmission manner is installed at the center of the outer wall of one side of the housing 9 through the bolt, the housing 9 can play a good protection role for the belt pulley 11 in the rotation process, thereby avoiding the situation that the belt pulley 11 is not protected and the operator is injured, and the motor 8 provides a good power support for the rotation of the transmission shaft 10.

The working principle is as follows: an operator firstly adjusts the distance between the first mobile station 6 and the second mobile station 7 according to the difference of the lengths of the electric cores, the hand wheel 5 drives the screw rod 2 to rotate, the screw rod 2 drives the first screw cylinder 3 and the second screw cylinder 4 which are in threaded connection to be drawn close, the first screw cylinder 3 and the second screw cylinder 4 can drive the first mobile station 6 and the second mobile station 7 to be drawn close, so that the first mobile station 6 and the second mobile station 7 can effectively adjust according to the difference of the lengths of the electric cores, then, the operator inserts the two ends of the electric cores into the fixed seats 13 to fix, the screw nut 18 drives the screw rod 17 to rotate, the screw rod 17 pushes the clamping plates 19 to clamp and position the electric cores in the fixed seats 13, so that the electric cores are more convenient to detach and fix, finally, the motor 8 drives the transmission shaft lever 10 to rotate, the transmission shaft lever 10 can simultaneously drive the fixed seats 13 which are distributed equidistantly to rotate under the mutual action of the belt wheels 11 and the synchronous belt 12, therefore, the battery cell is wound, and the winding efficiency of the battery cell is well improved.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the present invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the utility model.

Claims (6)

1. The utility model provides a nickel-hydrogen cylinder battery electric core winding mechanism, includes support frame (1), its characterized in that, there are screw rod (2) in the axle center department of the adjacent both ends inner wall of support frame (1) through bearing swing joint, and the both ends of screw rod (2) lateral wall threaded connection respectively have first spiral shell section of thick bamboo (3) and second spiral shell section of thick bamboo (4), install first removal platform (6) and second removal platform (7) through the bolt on the top outer wall of first spiral shell section of thick bamboo (3) and second spiral shell section of thick bamboo (4) respectively, and the center department of the adjacent one side outer wall of first removal platform (6) and second removal platform (7) all has fixing base (13) that are equidistant structure and distribute through bearing swing joint, the one end welding that screw rod (2) run through support frame (1) has hand wheel (5), and has cup jointed the sponge sleeve on the lateral wall of hand wheel (5).

2. The winding mechanism of the cylindrical nickel-hydrogen battery cell of claim 1, wherein positioning grooves (14) are formed in both sides of the outer wall of the top of the support frame (1), a guide rod (15) is welded at the axis of each positioning groove (14), a positioning block (16) sliding along the positioning groove (14) is sleeved on the outer side wall of each guide rod (15), and the positioning block (16) is fixedly connected with the first mobile station (6) and the second mobile station (7).

3. The winding mechanism of the nickel-hydrogen cylindrical battery cell of claim 1, wherein the outer walls of two sides of the fixed seat (13) are both in threaded connection with a lead screw (17), a rotating nut (18) is welded at one end of the lead screw (17) located outside the fixed seat (13), and anti-skid stripes are arranged on the outer side wall of the rotating nut (18).

4. The winding mechanism of the cylindrical nickel-hydrogen battery cell according to claim 3, wherein one end of the lead screw (17) inside the fixing seat (13) is movably connected with a clamping plate (19) through a bearing, the clamping plate (19) is of an arc-shaped structure, and a rubber pad (20) is bonded on the outer wall of the other side of the clamping plate (19) away from the lead screw (17).

5. The winding mechanism of the nickel-hydrogen cylindrical battery cell of claim 1, wherein the center of the outer wall of one side of the first mobile station (6) is movably connected with a transmission shaft rod (10) in transmission connection with the fixed seat (13) through a bearing, the outer side wall of the transmission shaft rod (10) is connected with a belt pulley (11) through a flat key, and the outer side wall of the belt pulley (11) is sleeved with a synchronous belt (12).

6. The winding mechanism of the nickel-hydrogen cylindrical battery cell of claim 1, wherein the outer wall of one side of the first mobile station (6) is provided with a cover (9) which covers the outside of the belt wheel (11) through a bolt, and the center of the outer wall of one side of the cover (9) is provided with a motor (8) which is in transmission connection with the transmission shaft lever (10) through a bolt.

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