CN220317240U - Rectangular cell carrier height lifting mechanism - Google Patents

Abstract

The utility model discloses a rectangular electric core carrier height lifting mechanism, which comprises an electric core outer frame, an inner lining plate and lifting mechanisms, wherein two symmetrical inner lining plates are arranged on opposite side walls in the electric core outer frame, the inner lining plates are connected with the electric core outer frame in a sliding manner in the vertical direction, lifting mechanisms are arranged between the inner lining plates and the inner bottom surface of the electric core outer frame, the upper end and the lower end of each lifting mechanism are fixedly connected with the bottom surface of the inner lining plates and the inner bottom surface of the electric core outer frame respectively, under the action of external force, the lifting mechanisms can adjust the supporting height between the bottom surface of the inner lining plates and the inner bottom surface of the electric core outer frame, the minimum supporting height between the inner lining plates and the inner bottom surface of the electric core outer frame is zero, and at least two lifting mechanisms are arranged between each inner lining plate and the inner bottom surface of the electric core outer frame; according to the utility model, the position of the lining can be freely lifted and adjusted according to the height of the loading battery cell, so that the compatibility of the lining is improved.

Description

Rectangular cell carrier height lifting mechanism

Technical Field

The utility model belongs to the technical field of logistics carriers, and particularly relates to a rectangular electric core carrier height lifting mechanism.

Background

The injection molding electric core frame is a logistics carrier for packaging and transporting electric cores produced in batch, and in order to avoid the electric cores from damaging batteries due to shaking and collision in the transportation process, electric core linings are generally arranged in the injection molding electric core frame and designed according to the shape of the electric cores, and can wrap and support the electric cores, separate and fix the whole row of electric cores, effectively improve transportation safety and reduce electric core loss rate; the ordinary inside lining is fixed state for the frame, and when this moment need compatible another section high difference electric core, just must tear down original inside lining, changes another section high difference inside lining, and this kind of mode is complex operation not only, and the compatibility is poor, prepares multiple different high inside lining and can increase little manufacturing cost moreover, and idle inside lining also has the inconvenience in management and preservation, consequently needs to improve current injection molding electric core frame, improves its high compatibility.

Disclosure of Invention

Aiming at the problems and the technical requirements, the utility model provides a rectangular cell carrier height lifting mechanism which can freely lift and adjust the position of a lining according to the height dimension of a loaded cell and improve the compatibility of the lining.

The technical scheme of the utility model is as follows: the utility model provides a high elevating system of rectangle electric core carrier, includes electric core frame, interior welt and lifting mechanism, is equipped with two symmetrical interior welts on the relative lateral wall in the electric core frame, be equipped with lifting mechanism between interior welt and the electric core frame interior bottom surface at vertical direction sliding connection between interior welt and the electric core frame, fixed connection between lifting mechanism upper and lower extreme and interior welt bottom surface, the electric core frame interior bottom surface respectively, under the exogenic action, lifting mechanism can adjust the supporting height between interior welt bottom surface and the electric core frame interior bottom surface, minimum supporting height between interior welt and the electric core frame interior bottom surface is zero, is equipped with two at least lifting mechanism between every interior welt and the electric core frame interior bottom surface. In the scheme, the lifting mechanism can adjust the distance between the inner lining plate and the inner bottom surface of the outer frame of the battery cell, and the battery cells with different heights can be compatible without replacing the inner lining plate.

Further, the lifting mechanism comprises a bottom plate, a supporting plate and a telescopic supporting column, wherein the supporting plate is fixedly connected with the bottom surface of the inner lining plate, the bottom plate is fixedly connected with the inner bottom surface of the outer frame of the battery cell, the middle parts of the supporting plate and the bottom plate are connected through the telescopic supporting column, and the telescopic supporting column can adjust the supporting distance between the supporting plate and the bottom plate.

Further, the telescopic support column comprises a cylindrical base, a support rod, a bracket and a limiting column, wherein the cylindrical base is vertically connected to the bottom plate, the support rod is fixedly connected to the bottom surface of the support plate, the support rod is correspondingly inserted into the cylindrical base, a row of pawls are arranged on the side surface of the support rod, the pawls are all inclined downwards, and clamping grooves are formed between adjacent pawls; the side on barrel type base upper portion is equipped with the bracket, transversely has seted up the slot hole on the bracket, and the slot hole is the through-hole of upward slope, and the bottom and the draw-in groove position of slot hole correspond, and spacing post passes the slot hole, and spacing post can be followed the slot hole activity, and in the draw-in groove was gone into to the card when spacing post rolled to the bottom, locking bracing piece and barrel type base. In this scheme, the bracing piece is flexible in barrel-type base to be adjusted, after the draw-in groove is gone into to spacing post card, because the pawl is the slant down, under the pressure of top, the pawl can further with spacing post chucking, reach the effect of locking under this height, and because spacing post can roll down and stop in slot hole minimum when not bearing force, namely block in certain draw-in groove, unless the spacing post is stirred to the manual, spacing post can not roll out from the draw-in groove, consequently adjust back high, will remain at this height always, the supporting stability is high.

Furthermore, the lifting mechanism is also provided with X-shaped brackets, opposite flanging is arranged on two sides of the bottom plate and the supporting plate, the two groups of X-shaped brackets are respectively connected to the flanging on two sides, and when the bottom plate and the supporting plate move relatively, the two groups of X-shaped brackets are synchronously telescopic and adjustable. The two opposite X-shaped brackets are arranged, so that the connection between the bottom plate and the supporting plate is more stable, the X-shaped brackets can also assist the telescopic supporting column, and the bottom and the supporting plate are kept balanced as much as possible when the telescopic supporting column is in an adjusting state.

Further, a chute is arranged on the turnup, the X-shaped bracket comprises two equal-length bracket strips, the middle parts of the bracket strips are hinged, one end of each bracket strip is hinged on the turnup of the bottom plate or the supporting plate, and the other end of each bracket strip is connected on the chute of the symmetrical turnup in a sliding manner.

Further, the bottom of the lining plate is provided with a rectangular accommodating groove, the lifting mechanism is arranged in the rectangular accommodating groove, and the overall height of the lifting mechanism at the minimum supporting distance is consistent with the depth of the rectangular accommodating groove. When the support plate is at the lowest position, namely the lifting mechanism is at the minimum support distance, the lifting mechanism can be completely retracted into the rectangular accommodating groove, so that the support height between the inner lining plate and the inner bottom surface of the outer frame of the battery cell is zero.

Furthermore, the interior lining board is an L-shaped board, and a row of concave-convex alternate battery cell accommodating grooves are formed in the inner side surface of the interior lining board.

Compared with the prior art, the utility model has the beneficial effects that: according to the utility model, the supporting position of the lining plate can be adjusted according to different heights of the battery cells, the purpose of compatibility with the battery cells with different heights can be realized without detaching and replacing the lining plate again, and the compatibility is strong; simultaneously adjust easy operation, only need manual spacing post of stirring, make spacing post leave the draw-in groove, just can pull the backup pad, when reaching the supporting distance, loosen spacing post, spacing post just can roll automatically to the draw-in groove in, locks this high distance, and simple swift regulation mode can save the manual work, satisfies quick vanning's demand, improves conveying efficiency.

Drawings

FIG. 1 is a diagram of the overall structure of the present utility model;

FIG. 2 is a mounting block diagram of the interior lining and the lifting mechanism;

FIG. 3 is a schematic view of the lifting mechanism in a retracted state;

FIG. 4 is a schematic view of the lifting mechanism in a raised state;

FIG. 5 is an overall block diagram of a lifting mechanism;

FIG. 6 is an enlarged view of the structure at A in FIG. 5;

FIG. 7 is a schematic diagram illustrating the movement of the limit post to dial upwards;

FIG. 8 is a cross-sectional view of the internal structure of the telescoping support post;

marked in the figure as: the battery cell outer frame 1, the inner lining plate 2, the rectangular accommodating groove 21, the battery cell accommodating groove 22, the lifting mechanism 3, the bottom plate 4, the flanging 41, the sliding groove 42, the supporting plate 5, the telescopic supporting column 6, the barrel-shaped base 61, the supporting rod 62, the pawl 621, the clamping groove 622, the bracket 63, the long hole 631, the limiting column 632 and the X-shaped bracket 7.

Detailed Description

The utility model is further described below with reference to the drawings and examples.

The utility model relates to a rectangular electric core carrier height lifting mechanism, which is shown in fig. 1-8, and comprises an electric core outer frame 1, an inner lining plate 2 and a lifting mechanism 3, wherein two symmetrical inner lining plates 2 are arranged on opposite side walls in the electric core outer frame 1, the inner lining plates 2 are connected with the electric core outer frame 1 in a sliding manner in the vertical direction, and the lifting mechanism 3 is arranged between the inner lining plates 2 and the inner bottom surface of the electric core outer frame 1.

The lifting mechanism 3 comprises a bottom plate 4, a supporting plate 5 and a telescopic supporting column 6, wherein the supporting plate 5 is fixedly connected with the bottom surface of the inner lining plate 2, the bottom plate 4 is fixedly connected with the inner bottom surface of the outer frame of the battery cell, the middle parts of the supporting plate 5 and the bottom plate 4 are connected through the telescopic supporting column 6, and the telescopic supporting column 6 can adjust the supporting distance between the supporting plate 5 and the bottom plate 4. The telescopic support column 6 comprises a cylindrical base 61, a support rod 62, a bracket 63 and a limiting column 632, wherein the cylindrical base 61 is vertically connected to the bottom plate 4, the support rod 62 is fixedly connected to the bottom surface of the support plate 5, the support rod 62 is correspondingly inserted into the cylindrical base 61, a row of pawls 621 are arranged on the side surface of the support rod 62, the pawls 621 incline downwards, and clamping grooves 622 are formed between adjacent pawls 621; the side of barrel type base 61 upper portion is equipped with bracket 63, transversely has offered slot hole 631 on the bracket 63, and slot hole 631 is the through-hole of upward slope, and the bottom and the draw-in groove 622 position of slot hole 631 correspond, and spacing post 632 passes the slot hole, and spacing post 632 can follow slot hole 631 activity, and in spacing post 632 rolled to the bottom, blocked into draw-in groove 622, locked bracing piece 62 and barrel type base 61.

The lifting mechanism 3 is also provided with X-shaped brackets 7, opposite flanges 41 are arranged on two sides of the bottom plate 4 and the supporting plate 5, the two groups of X-shaped brackets 7 are respectively connected to the flanges 41 on two sides, and when the bottom plate 4 and the supporting plate 5 move relatively, the two groups of X-shaped brackets 7 are synchronously telescopic and adjustable. The turnup 41 is provided with a chute 42, the X-shaped bracket 7 comprises two equal-length bracket strips, the middle parts of the bracket strips are hinged, one end of each bracket strip is hinged on the turnup 41 of the bottom plate 4 or the supporting plate 5, and the other end of each bracket strip is connected on the chute 42 of the symmetrical turnup 41 in a sliding manner.

The upper end and the lower end of the lifting mechanism 3 are fixedly connected with the bottom surface of the inner lining plate and the inner bottom surface of the electric core outer frame respectively, under the action of external force, the lifting mechanism 3 can adjust the supporting height between the bottom surface of the inner lining plate and the inner bottom surface of the electric core outer frame, the minimum supporting height between the inner lining plate 2 and the inner bottom surface of the electric core outer frame is zero, and at least two lifting mechanisms 3 are arranged between each inner lining plate 2 and the inner bottom surface of the electric core outer frame. Specifically, the bottom of the lining plate is provided with a rectangular accommodating groove 21, the lifting mechanism 3 is arranged in the rectangular accommodating groove 21, and the overall height of the lifting mechanism 3 at the minimum supporting distance is consistent with the depth of the rectangular accommodating groove 21. When the support plate 5 is at the lowest position, namely the lifting mechanism 3 is at the minimum support distance, the lifting mechanism 3 can be completely retracted into the rectangular accommodating groove 21, so that the support height between the inner lining plate 2 and the inner bottom surface of the cell outer frame is zero; the inner lining plate 2 is an L-shaped plate, and a row of concave-convex alternate cell accommodating grooves 22 are formed in the inner side surface of the inner lining plate 2.

The action process of the utility model:

initial state: the supporting rod 62 is inserted into the bottom of the cylindrical base 61, the limiting post 632 is clamped in the clamping groove 622 at the uppermost end, the supporting plate 5 is at the lowest position, the whole lifting mechanism 3 is completely retracted into the rectangular accommodating groove 21, and the distance between the inner lining plate 2 and the inner bottom surface of the cell outer frame 1 is zero.

Lifting action: the limiting column 632 is shifted upwards obliquely from the lowest end of the long hole 631, the limiting column 632 is separated from the clamping groove, the lining plate 2 is pulled according to the required height of the battery cell, the lining plate 2 drives the supporting plate 5 to be pulled upwards, when the required height is reached, the limiting column 632 is loosened, the limiting column 632 rolls downwards and is clamped into the clamping groove 622 with the corresponding height, the lining plate 2 is loosened, the lining plate 2 and the supporting plate 5 are pressed on the supporting rod 62, at the moment, the pawl 621 corresponding to the clamping groove 622 clamps the limiting column 632, the limiting column 632 is prevented from slipping, and lifting adjustment is completed. If the limiting post 632 is required to be reset, the limiting post 632 is required to be stirred again, the limiting post 632 is loosened after the supporting rod 62 naturally drops to the lowest point, and the limiting post 632 rolls to the lowest point again and is clamped in the clamping groove 622 at the top.

While the utility model has been described with respect to several preferred embodiments, the scope of the utility model is not limited thereto, and any changes and substitutions that would be apparent to one skilled in the art within the scope of the utility model are intended to be included within the scope of the utility model. Therefore, the protection scope of the present utility model should be subject to the protection scope of the claims.

Claims (7)

1. Rectangular electric core carrier height elevating system, its characterized in that: including electric core frame, interior welt and elevating system, be equipped with two symmetrical interior welts on the relative lateral wall in the electric core frame, be equipped with elevating system between interior welt and the electric core frame in vertical direction sliding connection between interior welt and the electric core frame bottom surface, fixed connection between elevating system upper and lower extreme and interior welt bottom surface, the electric core frame bottom surface respectively, under the exogenic action, elevating system can adjust the supporting height between interior welt bottom surface and the electric core frame bottom surface, minimum supporting height between interior welt and the electric core frame bottom surface is zero, is equipped with two at least elevating system between every interior welt and the electric core frame bottom surface.

2. The rectangular cell carrier height lifting mechanism of claim 1, wherein: the lifting mechanism comprises a bottom plate, a supporting plate and a telescopic supporting column, wherein the supporting plate is fixedly connected with the bottom surface of the inner lining plate, the bottom plate is fixedly connected with the inner bottom surface of the outer frame of the battery cell, the middle parts of the supporting plate and the bottom plate are connected through the telescopic supporting column, and the telescopic supporting column can adjust the supporting distance between the supporting plate and the bottom plate.

3. The rectangular cell carrier height lifting mechanism of claim 2, wherein: the telescopic support column comprises a cylindrical base, a support rod, a bracket and a limit column, wherein the cylindrical base is vertically connected to the bottom plate, the support rod is fixedly connected to the bottom surface of the support plate, the support rod is correspondingly inserted into the cylindrical base, a row of pawls are arranged on the side surface of the support rod, the pawls are obliquely downward, and clamping grooves are formed between adjacent pawls; the side on barrel type base upper portion is equipped with the bracket, transversely has seted up the slot hole on the bracket, and the slot hole is the through-hole of upward slope, and the bottom and the draw-in groove position of slot hole correspond, and spacing post passes the slot hole, and spacing post can be followed the slot hole activity, and in the draw-in groove was gone into to the card when spacing post rolled to the bottom, locking bracing piece and barrel type base.

4. The rectangular cell carrier height lifting mechanism of claim 3, wherein: the lifting mechanism is also provided with X-shaped brackets, opposite flanging is arranged on two sides of the bottom plate and the supporting plate, the two groups of X-shaped brackets are respectively connected to the flanging on two sides, and when the bottom plate and the supporting plate move relatively, the two groups of X-shaped brackets are synchronously telescopic and adjustable.

5. The rectangular cell carrier height lifting mechanism of claim 4, wherein: the turnup is provided with a chute, the X-shaped bracket comprises two equal-length bracket strips, the middle parts of the bracket strips are hinged, one end of each bracket strip is hinged on the turnup of the bottom plate or the supporting plate, and the other end of each bracket strip is connected on the chute of the symmetrical turnup in a sliding manner.

6. The rectangular cell carrier height lifting mechanism of claim 5, wherein: the bottom of the inner lining plate is provided with a rectangular accommodating groove, the lifting mechanism is arranged in the rectangular accommodating groove, and the overall height of the lifting mechanism at the minimum supporting distance is consistent with the depth of the rectangular accommodating groove.

7. The rectangular cell carrier height lifting mechanism of claim 6, wherein: the interior welt is L template, and the medial surface of interior welt is equipped with the electric core holding tank that a row of unsmooth alternate.