CN218469601U - High-efficient loading attachment of electricity core preheater and contain its electricity core preheater - Google Patents

Abstract

The application discloses a high-efficiency feeding device of a cell preheating furnace, which comprises a cell incoming line, a cache feeding mechanism, a cache transfer mechanism and a feeding mechanism which are sequentially arranged, wherein the cache transfer mechanism comprises a cache tray and a carrying mechanism, one end of the carrying mechanism is set as a cell cache station, the other end of the carrying mechanism is a cell feeding station, and the carrying mechanism is used for enabling the cache tray to move back and forth between the cell cache station and the cell feeding station; through increasing buffer memory feed mechanism and buffer memory and moving and carrying the mechanism, the electric core comes treating of stockline unloading electric core and treats that the electric core of material loading preheats the subassembly and all does not have idle waiting state, has improved the operating efficiency and the utilization ratio of equipment, has also improved the production efficiency of electric core greatly.

Description

High-efficient loading attachment of electricity core preheater and contain its electricity core preheater

Technical Field

The utility model relates to a lithium cell production and processing equipment technical field, in particular to high-efficient loading attachment of electricity core preheater and contain its electricity core preheater.

Background

At present, contact preheater is used for the naked electric core after the coiling to preheat before the plastic to make naked electric core can be quick reach the plastic effect. Compared with the traditional air circulation type preheating tunnel furnace, the contact type preheating furnace has the characteristics of heating blocks, high efficiency, energy conservation, high cleanliness and the like. Therefore, the contact preheating furnace is widely used for preheating or drying treatment of bare cells and the like.

The traditional contact preheating furnace adopts a structure that a drawer is dragged by the side edge, and the Chinese patent invention with the publication number of CN109442999B discloses a full-automatic preheating furnace. Because the furnace body is about 2 meters high, tray formula board that generates heat has up to ten layers more, especially when high-rise tray formula board that generates heat needs the material loading, the electric core is got from the upper clamp of the electric core incoming material line of low department to material loading manipulator, then rise to high-rise tray formula board that generates heat and place the electric core, it gets electric core to continue to press from both sides on the electric core incoming material line of low department to drop to get, it places the electric core to rise to high-rise tray formula board that generates heat again, because the lift stroke of material loading manipulator is overlength, in addition, because each mechanical structure in the material loading module all occupies certain space, consequently, need certain safe distance in interval between each mechanical structure, so material loading manipulator also has certain horizontal migration stroke, not only cause the electric core that waits to unload of electric core incoming material line to have the idle state, and tray formula board that generates heat also has the material loading and waits for the idle state, the extravagant state of time has been caused, thereby production efficiency is low.

SUMMERY OF THE UTILITY MODEL

For solving above-mentioned technical problem, this application provides a high-efficient loading attachment of electricity core preheater, moves through increasing buffer memory feed mechanism and buffer memory and carries the mechanism, and electricity core comes the waiting of stockline unloading electricity core and waits that the electric core of material loading preheats the subassembly and all does not have idle waiting state, has improved the operating efficiency and the utilization ratio of equipment, has also improved the production efficiency of electricity core greatly.

The application provides a pair of high-efficient loading attachment of electricity core preheater adopts following technical scheme:

a high-efficiency feeding device of a battery cell preheating furnace comprises a battery cell feeding line, a cache feeding mechanism, a cache transferring mechanism and a feeding mechanism which are sequentially arranged, wherein the cache transferring mechanism comprises a cache tray and a carrying mechanism, one end of the carrying mechanism is set as a battery cell cache station, the other end of the carrying mechanism is a battery cell feeding station, and the carrying mechanism is used for enabling the cache tray to move back and forth between the battery cell cache station and the battery cell feeding station; the buffer loading mechanism comprises a mounting rack, a first Y-axis stroke mechanism arranged on the mounting rack, a first Z-axis stroke mechanism arranged on the first Y-axis stroke mechanism and a first battery cell clamping assembly arranged on the first Z-axis stroke mechanism, and the first battery cell clamping assembly is used for transferring a battery cell on a battery cell incoming line to a buffer tray of a battery cell buffer station; the feeding mechanism comprises a feeding fixing frame, a second Z-axis stroke mechanism arranged on the feeding fixing frame and a second battery cell clamping assembly arranged on the second Z-axis stroke mechanism, and the second battery cell clamping assembly is used for clamping a battery cell from a cache tray of a battery cell feeding station so as to feed the battery cell.

Through adopting above-mentioned technical scheme, preheating furnace loading attachment comes stockline, buffer memory feed mechanism, buffer memory to move and carries the overall arrangement that moves mechanism and feed mechanism through electric core, can make each mechanism cooperate to be in operating condition under the inseparable condition always, and the time that the significantly reduced is idle, waits is extravagant, has improved production efficiency and rate of equipment utilization simultaneously.

Preferably, the stroke distance of the first Y-axis stroke mechanism is 900-1100mm, the stroke distance of the first Z-axis stroke mechanism is 60-90mm, and the stroke distance of the second Z-axis stroke mechanism is 1800-2000mm.

By adopting the technical scheme, the stroke distance of the first Z-axis stroke mechanism is 60-90mm, and compared with the lifting stroke of the existing feeding manipulator which is about 2 m, the lifting stroke for grabbing the battery cell from the battery cell incoming line is greatly shortened, the waiting time for the battery cell on the battery cell incoming line is shortened, and even no waiting time exists; second Z axle stroke mechanism will be located electric core material loading on the buffer memory tray of electric core material loading station to every layer electric core preheating assembly be exclusively used in can, need not go electric core and come to press from both sides on the material line and get electric core, thereby buffer memory tray can remove a set of electric core that will load down to electric core buffer memory station to electric core buffer memory after second Z axle stroke mechanism snatchs electric core moreover, therefore the efficiency of electric core material loading has improved greatly.

Preferably, the first Y-axis stroke mechanism includes a Y-axis module and a moving frame fixed to a driving end of the Y-axis module, the first Z-axis stroke mechanism includes an electric cylinder fixed to the moving frame, and the first electric core clamping assembly is fixed to the driving end of the lifting cylinder.

Through adopting above-mentioned technical scheme, first Y axle stroke mechanism below is carried to electric core on the electric core incoming material line, first Z axle stroke mechanism of first Y axle stroke mechanism drive removes directly over the electric core, then descend in order to press from both sides and get electric core by the first electric core centre gripping subassembly of electric cylinder drive, the stroke distance of first Z axle stroke mechanism shortens greatly, press from both sides and shift to on the buffer memory tray of electric core buffer memory station after getting electric core, whether need not wait for electric core material loading to preheat the subassembly, can continue to reset and come to press from both sides and get electric core directly over the material line of electric core, provide buffer memory electric core for electric core material loading mechanism, make material loading mechanism constantly link up the electric core of treating the material loading, make material loading mechanism not idle, the time waste of waiting.

Preferably, the second Z-axis stroke mechanism includes a Z-axis module and a mechanical arm fixed at a driving end of the Z-axis module, the second cell clamping assembly is fixed at a free end of the mechanical arm, and the second cell clamping assembly is located right above the cell loading station.

Through adopting above-mentioned technical scheme, second Z axle stroke mechanism only has the action of going up and down, press from both sides get to be located electric core in the buffer memory tray of electric core material loading station after put on being located the translation to electric core material loading station preheat the subassembly can, consequently, the efficiency of electric core material loading has also improved a lot.

Preferably, the carrying mechanism includes a main driving motor, an X-direction main driving shaft, a first Y-direction linear guide rail, a second Y-direction linear guide rail and a synchronous belt assembly, the synchronous belt assembly includes a first driving synchronous pulley, a second driving synchronous pulley, a first driven synchronous pulley, a second driven synchronous pulley, a first synchronous belt and a second synchronous belt, the first driving synchronous pulley and the second driving synchronous pulley are coaxially connected with the output shaft of the main driving motor through the X-direction main driving shaft, the first driving synchronous pulley and the first driven synchronous pulley are respectively fixed at two ends of the first Y-direction linear guide rail, the second driving synchronous pulley and the second driven synchronous pulley are respectively fixed at two ends of the second Y-direction linear guide rail, the first driving synchronous pulley and the first driven synchronous pulley are sleeved with the first synchronous belt, the second driving synchronous pulley and the second driven synchronous pulley are sleeved with the second synchronous belt, the first Y-direction linear guide rail and the second Y-direction linear guide rail all include a slide rail and a slide block connected with the horizontal moving plate, and the first synchronous belt, the second slide block and the horizontal moving plate are fixedly connected with the buffer connecting piece and the horizontal moving plate.

Through adopting above-mentioned technical scheme, because set up a plurality of electric cores on the buffer memory tray and place the station, buffer memory tray X is bigger to the width, and this carrying mechanism passes through X to the first initiative synchronous pulley of final drive shaft synchro-driven, second initiative synchronous pulley, can make the effect of two Y of buffer memory tray's bottom both ends to the syntropy operation, consequently ensured the operating stability of buffer memory tray, can accomplish smooth operation to improve the operating efficiency.

Preferably, the travel distance of the carrying mechanism is 1400-1500mm.

By adopting the technical scheme, the stroke distance of the carrying mechanism is matched with the size and the safety interval of each mechanical structure in the feeding mechanism, so that the operation safety among the mechanisms can be saved, the stroke distance can be reduced as much as possible, the operation time is saved, and the equipment utilization rate is improved.

The application provides a pair of electricity core preheating furnace, including preheating the furnace body, preheat the furnace body and include furnace body frame and locate the interior electric core of furnace body frame and preheat the station, electric core preheats and sets up a plurality of layers of electric core in the station and preheats the subassembly, a plurality of layers of electric core preheats the subassembly and piles up in proper order along vertical direction and place, every layer the subassembly can be preheated to electric core for furnace body frame is along Y axle direction translation, set up on the furnace body frame and preheat the subassembly with every layer of electric core and move the mechanism of carrying on along the translation of Y axle direction, still include foretell electric core preheating furnace high-efficient loading attachment, when electric core material loading, move and carry the mechanism and preheat the subassembly translation with electric core and carry out the material loading to electric core material loading station.

Through adopting above-mentioned technical scheme, when needs electric core material loading, move and carry mechanism itself and include elevating system and horizontal migration mechanism, move to the position that the subassembly was preheated to the electric core of treating the material loading by elevating system, then preheat the subassembly with the electric core by horizontal migration mechanism and move to electric core material loading station top, at this moment, electric core in the buffer memory tray has been got to second Z axle stroke mechanism clamp, wait for the material loading in the subassembly top is preheated to the electric core of treating the material loading, so electric core buffer memory formula material loading, and the waiting for formula material loading before not, make the efficiency of electric core material loading improve greatly.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the preheating furnace feeding device not only divides the existing battery cell feeding into two parts which are mutually not interfered by clamping a battery cell from a feeding line and feeding the battery cell to a battery cell preheating assembly, but also seamlessly links the feeding line blanking and the battery cell feeding through the buffer transferring mechanism by mutually matching the buffer feeding mechanism, so that each mechanism is always in a working state, the time waste of idle and waiting of the existing mechanism is solved, and the production efficiency and the equipment utilization rate are greatly improved;

2. the carrying mechanism synchronously drives the first driving synchronous belt pulley and the second driving synchronous belt pulley through the X-direction main transmission shaft, so that the effect of double-Y-direction synchronous operation at two ends of the bottom of the cache tray can be realized, the operation stability of the cache tray is ensured through the double-Y-direction linear guide rails, and the smooth operation can be realized, thereby improving the operation efficiency.

Drawings

FIG. 1 is a left side view of a cell preheating furnace;

FIG. 2 isbase:Sub>A cross-sectional view taken along line A-A of FIG. 1;

FIG. 3 is an enlarged schematic view of the structure at A in FIG. 2;

FIG. 4 is an enlarged schematic view of the structure at B in FIG. 2;

fig. 5 is a schematic diagram for embodying a buffer transfer apparatus;

FIG. 6 is a schematic diagram for embodying a carrying mechanism;

in the figure: a cache feed mechanism-10; a mounting frame-11; a first Y-axis stroke mechanism-12; y-axis module-121; a mobile frame-122; a first Z-axis stroke mechanism-13; an electric cylinder-131; a first cell clamping assembly-14; a battery cell feeding mechanism-30; a feeding fixing frame-31; a second Z-axis travel mechanism-32; z-axis module-321; a robotic arm-322; a second cell clamping assembly-33; a buffer transfer device-40; a buffer tray-41; a carrying mechanism-42; a guide rail support frame-421; an X-direction main transmission shaft-422; a horizontal moving frame-423; a furnace frame-510; a battery cell preheating assembly-520; a transfer mechanism-530; caching a feeding station-A1; a battery cell loading station-A2; and a cell preheating station-A3.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

Referring to fig. 2, the application provides an efficient feeding device for a cell preheating furnace, which includes a cell incoming line, a buffer feeding mechanism 10, a buffer transfer mechanism 40 and a cell feeding mechanism 30, which are sequentially arranged, in which the feeding part is divided into a cell buffer feeding part and a cell feeding part, and the buffer transfer device 40 is arranged between the cell buffer feeding part and the cell feeding part, the buffer transfer device 40 includes a buffer tray 41 and a carrying mechanism 42, the starting end of the carrying mechanism 42 is set as a buffer feeding station A1 and a cell feeding station A2, and the carrying mechanism 42 is configured to reciprocate the buffer tray 41 between the buffer feeding station A1 and the cell feeding station A2; the cell cache loading part comprises a cache loading mechanism 10, the cache loading mechanism 10 is arranged on one side of a cache loading station A1, a cell incoming line is arranged right below the cache loading mechanism 10, and the cache loading mechanism 10 is used for transferring the cell of the cell incoming line to a cache tray 41 of the cache loading station A1, so that the cache loading mechanism only needs to supply the cell of the cell incoming line to an initial position of a cache transfer device 40, namely the cache loading station A1; the electricity core material loading part sets up to only including elevating system's electric core material loading mechanism 30, specifically do, locate electricity core material loading station A2's top with electricity core material loading mechanism 30, make electricity core material loading mechanism 30 only need go up and down to get and put the material loading that can accomplish electric core by the electric core that is located electricity core material loading station A2, moreover, electricity core material loading mechanism 30 and cache material loading mechanism 10's operation process mutual noninterference, can incessantly go on simultaneously, carry out staged ingenious design with electric core material loading, the material loading operating efficiency of electric core has wholly been improved.

Referring to fig. 2 and 3, the buffer feeding mechanism 10 includes a mounting frame 11, a first Y-axis stroke mechanism 12 disposed on the mounting frame 11, a first Z-axis stroke mechanism 13 disposed on the first Y-axis stroke mechanism 12, and a first cell clamping assembly 14 disposed on the first Z-axis stroke mechanism 13, where a stroke distance of the first Z-axis stroke mechanism 13 is 60-90mm, and a stroke distance of the first Y-axis stroke mechanism 12 is 900-1100mm. Specifically, the first Y-axis stroke mechanism 12 includes a Y-axis module 121 and a moving frame 122 fixed to a driving end of the Y-axis module 121, the first Z-axis stroke mechanism 13 includes an electric cylinder 131 fixed to the moving frame 122, and the first cell holding assembly 14 is fixed to the driving end of the electric cylinder 131. When the cache feeding operation is executed: after the cells of the incoming material line are in place, the electric cylinder 131 drives the first cell clamping assembly 14 to descend to the position right above the incoming material line of the cells according to instructions, the first cell clamping assembly 14 also grabs a group of cells in a row according to the instructions of the program, the Y-axis module 121 drives the moving frame 122 to drive the electric cylinder 131 and the first cell clamping assembly to translate to the cache loading station A1, then the electric cylinder 131 drives the first cell clamping assembly 14 to descend to the cache tray of the cache loading station A1 according to the instructions, and the first cell clamping assembly also releases the cells according to the instructions and then places the cells on the cache tray 41 of the cache loading station A1, so that the cache loading part of the cells is completed; compared with the prior art that the battery cell of the material line is directly grabbed by a manipulator and then placed on the tray type heating plate, the length of the shortened stroke is shortened no matter the Z-axis stroke or the Y-axis stroke, namely the time is shortened and the efficiency is improved, particularly the Z-axis stroke, the height of the tray type heating plate which is sequentially stacked between the furnace body frames in the whole preheating furnace reaches about 2000mm, when the material is required to be fed to a high layer, the length of the shortened Z-axis stroke is 20 times, and the length of the improved efficiency of grabbing the battery cell from the material line is a little.

Referring to fig. 2 and 4, the cell feeding mechanism 30 includes a feeding fixing frame 31, a second Z-axis stroke mechanism 32 fixed on the feeding fixing frame 31, and a second cell clamping assembly 33 arranged on the second Z-axis stroke mechanism 32, and a stroke distance of the second Z-axis stroke mechanism 32 is 1800 to 2000mm; compare preceding preheater, the electric core feed mechanism 30 of this application only need by second Z axle stroke mechanism 32 go up and down to get put be located buffer memory unloading station A1 the electric core can, second Z axle stroke mechanism 32 chooses for use Z axle module 321 and is fixed in the arm 322 of Z axle module 321 drive end, second electric core centre gripping subassembly 33 is fixed in the free end of arm 322, second electric core centre gripping subassembly 33 is located directly over electric core feed station A2. Specifically, firstly, Z-axis module 321 of second Z-axis stroke mechanism 32 drives mechanical arm 322 to ascend and descend, so that second cell clamping assembly 33 located at the end of mechanical arm 322 is arranged above the cell in cell caching tray 41 of cell loading station A2, second cell clamping assembly 33 clamps the cell according to a program instruction, then caching tray 41 resets itself to caching loading station A1 to carry the cell transferred by caching loading mechanism 10 to cell loading mechanism 30, cell loading mechanism 30 is dedicated to loading the cell on caching tray 41 located at cell loading station A2 onto each layer of tray type heating plate, the cell is not required to be clamped on the cell incoming line, and caching tray 41 can move towards cell caching loading station A1 after second Z-axis stroke mechanism 32 grabs the cell, so as to constantly cache the cell to be loaded for cell loading mechanism 30, thereby efficiency of cell loading is greatly improved.

Referring to fig. 1, 5, and 6, the carrying mechanism 42 includes a guide rail support 421 disposed along the Y direction, and is also a support portion of the whole carrying mechanism 42, the guide rail support 421 is symmetrically provided with a first Y-direction linear guide rail and a second Y-direction linear guide rail, each of the first Y-direction linear guide rail and the second Y-direction linear guide rail includes a slide rail and a slider slidably connected to the slide rail, which is a transportation reference of the whole carrying mechanism 42, a main drive shaft, i.e., an X-direction main drive shaft 422, is disposed perpendicular to the first Y-direction linear guide rail and the second Y-direction linear guide rail, two end portions of the X-direction main drive shaft 422 respectively fix a first driving synchronous pulley and a second driving synchronous pulley, and one end of the X-direction main drive shaft 422 is connected to a drive end of a main drive motor through a coupler, thereby realizing synchronous rotation of the first driving synchronous pulley and the second driving synchronous pulley; still including respectively in first Y to linear guide rail, second Y sets up first driven synchronous pulley to the other end of linear guide rail, second driven synchronous pulley, and first driving synchronous pulley is located to the cover, first synchronous belt between the first driven synchronous pulley, the second driving synchronous pulley is located to the cover, the last second hold-in range of second driven synchronous pulley, first synchronous belt, all set up connecting piece and slider fixed connection on the second synchronous belt, the fixed horizontal migration frame 423 that sets up on the connecting piece, horizontal migration frame 423 is the U type, thereby increase horizontal migration frame 423's the area of accepting, the bottom symmetry of buffer memory tray 41 is fixed in on two horizontal migration frames 423.

Referring to fig. 5, during the charging and discharging processes of the battery cells, a plurality of battery cells are all charged in one row at one time, the battery cell clamping assembly includes a plurality of battery cell clamping jaws arranged side by side, the tray-type heating plate needs to meet a certain transverse size, and in order to facilitate the taking and placing of the battery cells, the buffer tray 41 is required to meet the width specification same as that of the tray-type heating plate, so that the buffer tray 41X has a large width in the direction, more than one receiving point of the buffer tray 41 is required, and the buffer tray 41 needs to be conveyed back and forth, so that multiple receiving points need to be synchronously carried out, so as to ensure that the conveying process of the buffer tray 41 is safe and fast, the carrying mechanism 42 synchronously drives the first driving synchronous pulley and the second driving synchronous pulley through the X-direction main transmission shaft 411, so as to synchronously drive the synchronous belt assembly of the single motor, and cooperate with the structure of the linear guide rail, so as to enable the two ends of the bottom of the buffer tray 41 to operate in the double Y-direction in the same direction, thereby ensuring the operation stability of the buffer tray 41, and enabling the wire-sliding operation, thereby improving the operation efficiency and adapting to adapt to the fast and efficient operation environment of the equipment. The travel distance of the carrying mechanism 42 is 1400-1500mm, and because each mechanical structure occupies a certain space, a certain safety distance is required to be arranged between each two mechanical structures, and the travel distance of the carrying mechanism 42 is 1400-1500mm by combining the safety distance and the action process and speed of the mechanism, so that the operation efficiency can be improved as much as possible under the condition of meeting the operation safety.

Referring to fig. 2, the application provides a battery cell preheating furnace, electric core preheating station A3 in including furnace body frame 510 and locating the furnace body frame, electric core preheating station A3 sets up a plurality of layers of electric core preheating assembly 520 in setting up, a plurality of layers of electric core preheating assembly 520 piles up in proper order along vertical direction and place, every layer of electric core preheating assembly 520 can follow the translation of Y axle direction for furnace body frame 510, set up on the furnace body frame 510 and can preheat the moving mechanism 530 of subassembly 520 along the translation of Y axle direction with every layer of electric core, still include foretell high-efficient loading attachment of electric core preheating furnace, when electric core material loading, move and carry the mechanism and preheat subassembly 520 translation to electric core material loading station with electric core and carry out the material loading.

By adopting the technical scheme, when the cell loading is required, the transferring mechanism 530 comprises a horizontal driving mechanism, a lifting driving mechanism arranged at the driving end of the horizontal driving mechanism and a material shifting clamping piece arranged at the lifting driving end, wherein the material shifting clamping piece is used for being automatically clamped with the two end parts of the cell preheating assembly, the lifting driving mechanism of the transferring mechanism lifts the material shifting clamping piece to the layer position of the cell preheating assembly to be loaded according to a program instruction, after the material shifting clamping piece is clamped with the two end parts of the cell preheating assembly, the cell preheating assembly is moved to the position above the cell loading station A2 from the cell preheating station A3 by the horizontal driving mechanism, at the moment, the second Z-axis stroke mechanism 32 clamps the cell in the buffer tray, and the cell is ready to be loaded above the cell preheating assembly 520, so that the cell is in buffer loading instead of the previous waiting type loading, and the efficiency of the cell loading is greatly improved; the battery cell preheating assembly 520 is a tray type heating plate, after the tray type heating plate is fed, the tray type heating plate is reset to a battery cell preheating station A3 by a horizontal driving mechanism, and the operation is repeated in sequence to realize the feeding operation of the preheating furnace.

The above are preferred embodiments of the present application, and the scope of protection of the present application is not limited thereto, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (7)

1. The efficient feeding device of the battery cell preheating furnace is characterized by comprising a battery cell feeding line, a cache feeding mechanism, a cache transfer mechanism and a feeding mechanism which are sequentially arranged, wherein the cache transfer mechanism comprises a cache tray and a carrying mechanism, one end of the carrying mechanism is set as a battery cell cache station, the other end of the carrying mechanism is a battery cell feeding station, and the carrying mechanism is used for enabling the cache tray to move back and forth between the battery cell cache station and the battery cell feeding station; the buffer loading mechanism comprises a mounting rack, a first Y-axis stroke mechanism arranged on the mounting rack, a first Z-axis stroke mechanism arranged on the first Y-axis stroke mechanism and a first battery cell clamping assembly arranged on the first Z-axis stroke mechanism, and the first battery cell clamping assembly is used for transferring a battery cell on a battery cell incoming line to a buffer tray of a battery cell buffer station; the feeding mechanism comprises a feeding fixing frame, a second Z-axis stroke mechanism arranged on the feeding fixing frame and a second battery cell clamping assembly arranged on the second Z-axis stroke mechanism, and the second battery cell clamping assembly is used for clamping a battery cell from a cache tray of a battery cell feeding station so as to feed the battery cell.

2. The efficient feeding device for the battery cell preheating furnace according to claim 1, wherein the stroke distance of the first Y-axis stroke mechanism is 900-1100mm, the stroke distance of the first Z-axis stroke mechanism is 60-90mm, and the stroke distance of the second Z-axis stroke mechanism is 1800-2000mm.

3. The efficient feeding device for the battery cell preheating furnace according to claim 2, wherein the first Y-axis stroke mechanism comprises a Y-axis module and a moving frame fixed at a driving end of the Y-axis module, the first Z-axis stroke mechanism comprises an electric cylinder fixed on the moving frame, and the first battery cell clamping assembly is fixed at a driving end of the electric cylinder.

4. The efficient feeding device for the battery cell preheating furnace according to claim 3, wherein the second Z-axis stroke mechanism comprises a Z-axis module and a mechanical arm fixed at a driving end of the Z-axis module, the second battery cell clamping assembly is fixed at a free end of the mechanical arm, and the second battery cell clamping assembly is located right above a battery cell feeding station.

5. The efficient feeding device for the battery cell preheating furnace according to claim 1, wherein the carrying mechanism comprises a main driving motor, an X-direction main transmission shaft, a first Y-direction linear guide rail, a second Y-direction linear guide rail, and a synchronous belt assembly, the synchronous belt assembly comprises a first driving synchronous pulley, a second driving synchronous pulley, a first driven synchronous pulley, a second driven synchronous pulley, a first synchronous belt and a second synchronous belt, the first driving synchronous pulley and the second driving synchronous pulley are coaxially connected with an output shaft of the main driving motor through the X-direction main transmission shaft, the first driving synchronous pulley and the first driven synchronous pulley are respectively fixed at two ends of the first Y-direction linear guide rail, the second driving synchronous pulley and the second driven synchronous pulley are respectively fixed at two ends of the second Y-direction linear guide rail, the first driving synchronous pulley and the first driven synchronous pulley are sleeved with the first synchronous belt, the second driving synchronous pulley and the second driven synchronous pulley are sleeved with the second synchronous belt, the first Y-direction linear guide rail and the second Y-direction linear guide rail each comprise a slide rail and a slide block slidably connected with the second slide rail, a horizontal moving rack is provided with a horizontal moving rack, and two horizontal buffer storage trays are respectively provided with a horizontal moving rack, and two buffer storage racks are provided with two horizontal moving buffer storage racks, and two buffer storage racks are provided on the horizontal moving rack.

6. The efficient feeding device for the cell preheating furnace according to claim 5, wherein the stroke distance of the carrying mechanism is 1400-1500mm.

7. The utility model provides an electricity core preheating furnace, includes and preheats the furnace body, preheats the furnace body and includes furnace body frame and locate the interior electric core of furnace body frame and preheat the station, and electric core preheats the station and sets up a plurality of layers of electric core and preheats the subassembly, a plurality of layers of electric core and pile up in proper order along vertical direction and place, every layer the subassembly is preheated to the electricity core can for furnace body frame is along the translation of Y axle direction, furnace body frame is last to set up and to carry the mechanism with the electric core that preheats the subassembly along the translation of Y axle direction, its characterized in that still includes above-mentioned claim 1-6 any electricity core preheating furnace high efficiency loading attachment, when electric core material loading, it preheats the subassembly translation to electric core material loading station with the electricity core and carries out the material loading to move the mechanism.

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