CN219078480U - Automatic heat preservation and feeding equipment for capacitor core package - Google Patents

Abstract

The utility model discloses automatic heat preservation and feeding equipment for a capacitor core package, wherein a gap is opened at the top of an insulation box by a cover opening and closing mechanism after heat preservation is finished, an iron bar in the uppermost material frame in the insulation box is sequentially taken out by an iron bar taking mechanism, and then the gap of the insulation box is closed by the cover opening and closing mechanism, so that the transfer of the iron bar and the heat preservation of the iron bar in the rest material frame are finished. Because primary and secondary car can make the staff once only accomplish the loading of multilayer material frame in the insulation can, and the loading only needs to open and close the insulation can once each time, only needs to come and go insulation can department and get material department once, this kind of operating mode can improve work efficiency by a wide margin, and can reduce the heat loss in the insulation can to reduced manufacturing cost by a wide margin, improved the competitiveness of product.

Description

Automatic heat preservation and feeding equipment for capacitor core package

Technical Field

The utility model relates to the technical field of automatic production equipment of electrolytic capacitors, in particular to automatic heat preservation and feeding equipment of capacitor core bags.

Background

When the electrolytic capacitor is manufactured by formation and the like, anode pins of a plurality of elements are sequentially welded on iron bars in sequence and then are manufactured, the elements welded on the iron bars are required to be heated in an insulation box for a certain time and then can be fed into a pin cutting device for pin cutting, in order to improve the insulation efficiency, the iron bars are sequentially arranged on a material frame in sequence and then are fed into the insulation box, the steps in the traditional production process basically can only realize semi-automation, a plurality of procedures of the semi-automation are required to be manually participated, and if a worker normally puts one or a plurality of material frames filled with the iron bars into the insulation box respectively from a material frame material taking position, and sequentially stacks the material frames.

In the actual working process, the heat preservation box is required to be opened and stacked when one layer of material rack or multiple layers of material racks are placed, then the heat preservation box is closed, and the next repetition is carried out at the back and forth material taking position from the heat preservation box.

Disclosure of Invention

The utility model aims to solve the technical problems of improving the working efficiency and enabling workers to finish the loading of the multi-layer material rack in the heat insulation box at one time.

The technical problems to be solved by the utility model are realized by the following technical scheme:

in order to solve the technical problems, the utility model provides automatic heat preservation and feeding equipment for a capacitor core pack, which is used for preserving heat of a material rack loaded with iron bars, and comprises an insulation box, a switch cover mechanism, a feeding mechanism, an iron bar taking mechanism and a primary-secondary vehicle, wherein a first sliding rail is arranged on the bottom surface of the inside of the insulation box, and a box door is arranged at the front end of the insulation box; the switch cover mechanism is arranged above the heat insulation box; the feeding mechanism is arranged in the heat insulation box and is used for lifting the material rack layer by layer; the iron bar taking mechanism is arranged above the switch cover mechanism and is used for sequentially taking out one iron bar of the uppermost material frame in the insulation box; the primary-secondary car comprises a secondary car and a primary car, the primary car is used for loading the secondary car, the secondary car is used for loading stacked multilayer material racks, a second sliding rail is arranged on the primary car, directional pulleys corresponding to the first sliding rail and the second sliding rail are arranged on the secondary car, and the heights of the first sliding rail and the second sliding rail are consistent.

As a preferred implementation mode of the automatic heat preservation and feeding equipment for the capacitor core package, the lower surface of the mother car is provided with a plurality of universal pulleys.

As a preferred implementation mode of the capacitor core pack automatic heat preservation and feeding equipment provided by the utility model, the iron bar taking mechanism comprises an iron bar clamping arm and a turnover assembly for controlling the iron bar clamping arm to turn over.

As a preferred implementation mode of the automatic heat preservation and feeding equipment for the capacitor core package, a collecting box is arranged on one side of the back face of the heat preservation box and used for collecting empty material frames.

As a preferred embodiment of the automatic heat preservation and feeding equipment for the capacitor core package, a receiving device is arranged on one side, close to the heat preservation box, of the collecting box, the receiving device comprises a receiving fixing plate, a receiving moving plate, a receiving guide rod, a receiving screw rod nut, a receiving motor and a receiving support plate, the receiving guide rod and the receiving screw rod are fixed on the receiving fixing plate, the receiving moving plate is sleeved on the receiving guide rod and the receiving screw rod, the receiving screw rod nut is arranged on the receiving screw rod, the receiving screw rod nut is fixed on the lower surface of the receiving moving plate, and the receiving motor is fixed on the receiving fixing plate and is used for driving the receiving screw rod to rotate.

As a preferred implementation mode of the automatic heat preservation and feeding equipment for the capacitor core package, the switch cover mechanism comprises a sealing cover plate, a cover opening driving device, a fixing block and a sealing door, wherein a discharge hole is formed in the sealing cover plate, the cover opening driving device is fixed on the upper surface of the sealing cover plate, the cover opening driving device drives the fixing block to move, and the sealing door is fixed on the fixing block.

As a preferred implementation mode of the automatic heat preservation and feeding equipment for the capacitor core package, provided by the utility model, a material taking frame opening is formed in the back of the heat preservation box, an oven material taking mechanism is arranged above the collection box, the oven material taking mechanism comprises a material taking fixing plate, a material taking motor, a material taking screw rod, a material taking platform and a material taking rod, the material taking motor is fixed on the material taking fixing plate, the material taking screw rod is connected with the material taking motor, the material taking platform is arranged on the material taking screw rod, and the material taking rod is fixed at one end of the material taking platform.

As a preferred implementation mode of the automatic heat preservation and feeding equipment for the capacitor core package, the bottom surface of the inside of the collecting box is provided with a third sliding rail, and the directional pulley corresponds to the first sliding rail, the second sliding rail and the third sliding rail.

As a preferred implementation mode of the automatic heat preservation and feeding equipment for the capacitor core package, an empty material rack transfer mechanism is arranged above the oven material taking mechanism, the empty material rack transfer mechanism comprises a transfer fixing plate, a transfer motor for driving the transfer fixing plate to move and two transfer arms respectively arranged on two sides of the transfer fixing plate, a telescopic cylinder is fixed on each transfer arm, and a transfer plate is fixed at the tail end of each telescopic cylinder.

As a preferred implementation mode of the automatic heat preservation and feeding equipment for the capacitor core package, the heat preservation box is internally provided with a wind wheel and a plurality of heating pipes.

The utility model has the following beneficial effects:

due to the fact that the primary-secondary trolley is arranged, the secondary trolley can be loaded on the second sliding rail of the primary trolley to be taken from the material rack, after the multi-layer material rack is stacked on the secondary trolley, the primary trolley and the secondary trolley are pushed to come to the front of the box door of the heat insulation box, the box door of the heat insulation box is opened, and due to the fact that the heights of the first sliding rail and the second sliding rail are consistent, the secondary trolley is pushed to the first sliding rail of the heat insulation box after being aligned with the first sliding rail, and therefore loading of the multi-layer material rack in the heat insulation box is completed at one time. After the heat preservation is finished, the opening and closing mechanism opens a notch at the top of the heat preservation box, the iron bar taking mechanism sequentially takes out an iron bar of the uppermost material frame in the heat preservation box, and then the opening and closing mechanism closes the notch of the heat preservation box, so that the transfer of the iron bar and the heat preservation of the iron bar in the rest material frame are finished. Because primary and secondary car can make the staff once only accomplish the loading of multilayer material frame in the insulation can, and the loading only needs to open and close the insulation can once each time, only needs to come and go insulation can department and get material department once, this kind of operating mode can improve work efficiency by a wide margin, and can reduce the heat loss in the insulation can to reduced manufacturing cost by a wide margin, improved the competitiveness of product.

Drawings

For a clearer description of the solution in the present application, a brief description will be given below of the drawings that are needed in the description of the embodiments, it being obvious that the drawings in the following description are some embodiments of the present application, and that other drawings may be obtained from these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of an automatic heat preservation and feeding device for a capacitor core package.

Fig. 2 is a schematic view of the bottom view of the insulated container and the collection box of fig. 1.

Fig. 3 is a schematic structural view of the incubator and the primary-secondary vehicle.

Fig. 4 is a schematic structural view of the hidden incubator of fig. 3.

Fig. 5 is an enlarged view at a in fig. 4.

Fig. 6 is a schematic view of the back structure of fig. 3.

Fig. 7 is a schematic structural view of the iron bar extracting mechanism.

Fig. 8 is an enlarged view at B in fig. 7.

Fig. 9 is a state diagram of fig. 7 after inversion.

Fig. 10 is an enlarged view at C in fig. 9.

Fig. 11 is a schematic diagram of a switch cover structure.

Fig. 12 is a schematic view of the oven take off mechanism.

Fig. 13 is a schematic structural view of the empty rack transfer mechanism.

Fig. 14 is an enlarged view of D in fig. 13.

Fig. 15 is a schematic structural view of the material receiving device.

Fig. 16 is an enlarged view at E in fig. 15.

Reference numerals illustrate:

iron bar 100; a material rack 200;

an incubator 1; a cover opening and closing mechanism 2; a feeding mechanism 3; an iron bar taking mechanism 4; a primary-secondary vehicle 5;

a first slide rail 11; a door 12; a wind wheel 13; a heating tube 14;

a sub-vehicle 51; a parent vehicle 52; a second slide rail 53; a directional pulley 54; a universal pulley 55;

a bar drive 41; an iron bar fixing plate 42; iron bar holding arms 43; a flipping assembly 44;

a first turning shaft 441; a second inversion shaft 442; a flipping plate 443; a turn motor 444;

a collection box 6;

a sealing cover plate 21; a cover opening drive 22; a fixed block 23; a seal door 24;

a door opening drive motor 221; a cover opening gear 222; an open cover conveyor 223;

a material taking frame opening 15; an oven take-off mechanism 7; a material taking fixing plate 71; a take-out motor 72; a material taking screw 73; a take-out platform 74; a take-off lever 75; a slider 76; a chute 77;

an empty material rack transfer mechanism 8; a transfer fixing plate 81; a transfer motor 82; a transfer arm 83; the telescopic cylinder 84 transfers the plate 85;

a receiving device 9; a receiving fixing plate 91; a material receiving moving plate 92; a material receiving guide rod 93; a material receiving screw 94; a receiving screw nut 95; a material receiving motor 96; and a receiving support plate 97.

Detailed Description

In order that those skilled in the art will better understand the present utility model, a technical solution in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present utility model without making any inventive effort, shall fall within the scope of the present utility model.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second", and "a third" may explicitly or implicitly include at least one such feature. In the description of the present utility model, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

The utility model provides automatic heat preservation and feeding equipment for a capacitor core pack, which is used for preserving heat of a material rack loaded with iron bars, and comprises an insulation box, a switch cover mechanism, a feeding mechanism, an iron bar taking mechanism and a primary-secondary vehicle, wherein a first sliding rail is arranged on the bottom surface of the inside of the insulation box, and a box door is arranged at the front end of the insulation box; the switch cover mechanism is arranged above the heat insulation box; the feeding mechanism is arranged in the heat insulation box and is used for lifting the material rack layer by layer; the iron bar taking mechanism is arranged above the switch cover mechanism and is used for sequentially taking out one iron bar of the uppermost material frame in the insulation box; the primary-secondary car comprises a secondary car and a primary car, the primary car is used for loading the secondary car, the secondary car is used for loading stacked multilayer material racks, a second sliding rail is arranged on the primary car, directional pulleys corresponding to the first sliding rail and the second sliding rail are arranged on the secondary car, and the heights of the first sliding rail and the second sliding rail are consistent.

Due to the fact that the primary-secondary trolley is arranged, the secondary trolley can be loaded on the second sliding rail of the primary trolley to be taken from the material rack, after the multi-layer material rack is stacked on the secondary trolley, the primary trolley and the secondary trolley are pushed to come to the front of the box door of the heat insulation box, the box door of the heat insulation box is opened, and due to the fact that the heights of the first sliding rail and the second sliding rail are consistent, the secondary trolley is pushed to the first sliding rail of the heat insulation box after being aligned with the first sliding rail, and therefore loading of the multi-layer material rack in the heat insulation box is completed at one time. After the heat preservation is finished, the opening and closing mechanism opens a notch at the top of the heat preservation box, the iron bar taking mechanism sequentially takes out an iron bar of the uppermost material frame in the heat preservation box, and then the opening and closing mechanism closes the notch of the heat preservation box, so that the transfer of the iron bar and the heat preservation of the iron bar in the rest material frame are finished. Because primary and secondary car can make the staff once only accomplish the loading of multilayer material frame in the insulation can, and the loading only needs to open and close the insulation can once each time, only needs to come and go insulation can department and get material department once, this kind of operating mode can improve work efficiency by a wide margin, and can reduce the heat loss in the insulation can to reduced manufacturing cost by a wide margin, improved the competitiveness of product.

In order to better understand the technical solutions of the present application, the following description will clearly and completely describe the technical solutions in the embodiments of the present application with reference to the accompanying drawings. The present utility model is described in detail below with reference to the drawings and the embodiments, examples of which are illustrated in the accompanying drawings, wherein the same or similar reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present utility model and should not be construed as limiting the utility model.

Example 1

Referring to fig. 1 to 5, the automatic heat preservation and feeding device for capacitor core package provided by the utility model is used for preserving heat of a material rack 200 loaded with iron bars 100, and comprises an insulation box 1, a switch cover mechanism 2, a feeding mechanism 3, an iron bar taking mechanism 4 and a primary-secondary vehicle 5, wherein a first sliding rail 11 is arranged on the bottom surface of the inside of the insulation box 1, and a box door 12 is arranged at the front end of the insulation box 1; the cover opening and closing mechanism 2 is arranged above the heat preservation box 1, the cover opening and closing mechanism 2 and the heat preservation box 1 can be sealed, and the cover opening and closing mechanism 2 can be used for opening and closing the top of the heat preservation box 1; the feeding mechanism 3 is arranged in the heat insulation box 1 and is used for lifting all the material frames 200 layer by layer, when iron bars 100 on each layer of material frames 200 on the topmost layer are taken out, the topmost layer of material frames 200 are taken away, and then all the material frames 200 are lifted by one layer, so that the rest uppermost layer of material frames 200 are lifted to the same height as the original uppermost layer of material frames 200, and subsequent material taking is facilitated; the iron strip taking mechanism 4 is arranged above the switch cover mechanism 2, and one iron strip 100 of the uppermost material rack 200 in the insulation box 1 is sequentially taken out by the iron strip taking mechanism 4 each time so as to send the elements on the iron strip 100 to the next pin cutting process; the sub-car 5 comprises a sub-car 51 and a main car 52 for loading the sub-car 51, the sub-car 51 can be used for loading the stacked multi-layer material rack 200, the main car 52 is provided with a second sliding rail 53 corresponding to the first sliding rail 11, the heights of the first sliding rail 11 and the second sliding rail 53 are consistent, the sub-car 51 is provided with a directional pulley 54, the directional pulley 54 corresponds to the first sliding rail 11 and the second sliding rail 53, and the sub-car 51 can easily slide from the second sliding rail 53 of the main car 52 onto the first sliding rail 11 of the incubator 1.

Further, the lower surface of the parent car 52 is provided with a plurality of universal pulleys 55 so that the parent car 52 can be easily pushed to and from the material taking place and the incubator 1.

Further, a wind wheel 13 and a plurality of heating pipes 14 are arranged in the heat insulation box 1, the wind wheel 13 drives air in the heat insulation box 1 to flow, so that elements on the material rack 200 can be heated uniformly, and the plurality of heating pipes 14 are used for heating.

Example 2

Referring to fig. 1 to 10, as a further optimization scheme of embodiment 1, in this embodiment, the iron bar extracting mechanism 4 includes an iron bar clamping arm 43 and a turning component 44 for controlling the turning of the iron bar clamping arm 43, where the iron bar clamping arm 43 clamps and takes out the iron bar 100, turns 90 ° through the turning component 44, and then sends the iron bar 100 into the corner cutting device through the pick-and-place mechanism. In this embodiment, the iron bar feeding mechanism 4 includes an iron bar driving device 41, an iron bar fixing plate 42, iron bar clamping arms 43 and a turnover assembly 44, the iron bar fixing plate 42 is fixed on the iron bar driving device 41, the iron bar driving device 41 is used for driving the iron bar fixing plate 42 to move back and forth and up and down, two iron bar clamping arms 43 are respectively arranged at two sides of the iron bar fixing plate 42, the turnover assembly 44 includes a first turnover shaft 441, a second turnover shaft 442, a turnover plate 443 and a turnover motor 444, the first turnover shaft 441 is respectively connected with the two iron bar clamping arms 43 in a rotatable manner, the second turnover shaft 442 is respectively fixedly connected with the two iron bar clamping arms 43, and the turnover plate 443 is respectively sleeved on the first turnover shaft 441 and the second turnover shaft 442, and the turnover motor 444 is used for driving the turnover plate 443. Firstly, the iron bar driving device 41 drives the iron bar fixing plate 42 to move to the uncapping mechanism, the two iron bar clamping arms 43 clamp the two ends of the iron bar 100 respectively to clamp the iron bar 100, the iron bar driving device 41 drives the iron bar fixing plate 42 to lift upwards and then translate to the discharge port, at the moment, the turning motor 444 drives the turning plate 443 to move, the turning plate 443 drives the first turning shaft 441 to rotate in situ, the second turning shaft 442 rotates around the first turning shaft 441, and therefore the rotation of the iron bar clamping arms 43 is achieved, and the clamped iron bar 100 is sent to the corner cutting device through the pick-and-place mechanism after being turned 90 degrees.

Example 3

Referring to fig. 1 to 11, as a further optimization scheme of embodiment 1, in this embodiment, a collecting box 6 is disposed on one side of the back surface of the heat insulation box 1, the collecting box 6 is used for collecting an empty material rack 200, and after the empty material rack 200 is fully collected, the empty material rack 200 is sent to a material taking place to load iron bars 100 welded with elements.

Further, the cover opening and closing mechanism 2 comprises a sealing cover plate 21, a cover opening driving device 22, a fixed block 23 and a sealing door 24, wherein a discharge hole is formed in the sealing cover plate 21, the sealing door 24 can be sealed to change the discharge hole, the cover opening driving device 22 is fixed on the upper surface of the sealing cover plate 21, the cover opening driving device 22 drives the fixed block 23 to move, the sealing door 24 is fixed on the fixed block 23, and the cover opening driving device 22 drives the fixed block 23 to move so as to realize movement of the sealing door 24, and further realize opening and closing of the sealing door 24. In this embodiment, the cover opening driving device 22, the fixing block 23 and the sealing door 24 are all two and symmetrically arranged, and the driving directions of the two cover opening driving devices 22 are opposite, so that the sealing door 24 can be close to and far away from each other, and the sealing door 24 can be opened and closed quickly, the cover opening driving device 22 includes a cover opening driving motor 221, at least two cover opening gears 222 connected with the cover opening driving motor 221, and a cover opening conveyor 223 sleeved on the at least two cover opening gears 222, and the fixing block 23 is fixed on the cover opening conveyor 223, and in this embodiment, the cover opening conveyor 223 is a chain. The cover opening driving motor 221 drives the cover opening gear 222 to rotate, thereby driving the chain to rotate, and further driving the fixed block 23 and the sealing door 24 on the chain to move, thereby realizing the opening and closing of the sealing door 24.

Referring to fig. 1 to 12, further, a material taking opening 15 is formed in the back of the insulation box 1, an oven material taking mechanism 7 is disposed above the collection box 6, the oven material taking mechanism 7 includes a material taking fixing plate 71, a material taking motor 72, a material taking screw 73, a material taking platform 74 and a material taking rod 75, the material taking motor 72 is fixed on the material taking fixing plate 71, the material taking screw 73 is connected with the material taking motor 72, the material taking platform 74 is disposed on the material taking screw 73, the material taking rod 75 is fixed at one end of the material taking platform 74, a sliding block 76 is disposed on the material taking fixing plate 71, sliding grooves 77 corresponding to the sliding block 76 are disposed on the material taking platform 74, in this embodiment, the sliding blocks 76 are disposed in two and parallel with each other, and avoidance grooves are formed on the material taking fixing plate 71 on the square of the collection box 6. When the iron bars 100 on the uppermost material rack 200 are taken out, the material taking motor 72 drives the material taking screw 73 to rotate, the material taking platform 74 moves forward under the drive of the material taking screw 73, the material taking rod 75 stretches into the material rack 200 from the material taking rack opening 15, the material taking motor 72 rotates reversely to drive the material taking rod 75 to take out the material rack 200, and then the empty material rack 200 is put down from the avoidance groove through the subsequent empty material rack transfer mechanism 8.

Referring to fig. 1 to 14, further, an empty material rack transfer mechanism 8 is disposed above the oven material taking mechanism 7, the empty material rack transfer mechanism 8 includes a transfer fixing plate 81, a transfer motor 82 driving the transfer fixing plate 81 to move, and two transfer arms 83 respectively disposed at two sides of the transfer fixing plate 81, each of the transfer arms 83 is fixed with a telescopic cylinder 84, a transfer plate 85 is fixed at an end of each telescopic cylinder 84, the transfer motor 82 drives the transfer fixing plate 81 to move, the transfer plate 85 is moved to the bottom of the empty material rack 200, then the telescopic cylinder 84 drives the transfer plate to extend below the empty material rack 200, the transfer motor drives the transfer fixing plate 81 to move upwards again, so that the transfer plate 85 also moves upwards, and the empty material rack 200 is transferred to a designated position after the transfer plate 85 supports the empty material rack 200.

Further, a third sliding rail is arranged on the bottom surface of the inside of the collecting box 6, and the directional pulley 54 corresponds to the first sliding rail 11, the second sliding rail 53 and the third sliding rail 61, so that the primary-secondary vehicle 5 can be matched with the collecting box 6 for use, and a transferring device of the empty material rack 200 is not required to be additionally designed.

Referring to fig. 1 to 16, further, a receiving device 9 is disposed on a side of the collecting box, which is close to the insulation box 1, the receiving device 9 includes a receiving fixing plate 91, a receiving moving plate 92, a receiving guide rod 93, a receiving screw rod 94, a receiving screw rod nut 95, a receiving motor 96 and a receiving support plate 97, the receiving guide rod 93 and the receiving screw rod 94 are fixed on the receiving fixing plate 91, in this embodiment, the receiving guide rods 93 are two, the two receiving guide rods 93 and the receiving screw rod 94 are vertically disposed, the receiving moving plate 92 is vertically movably sleeved on the two receiving guide rods 93 and the receiving screw rod 94, the receiving screw rod nut 95 is disposed on the receiving screw rod 94, the receiving screw rod nut 95 is fixed on the lower surface of the receiving moving plate 92, the receiving screw rod nut 95 can support the receiving moving plate 92, and the receiving motor 96 is fixed on the receiving fixing plate 91 and is used for driving the receiving screw rod 94 to rotate. When the iron bar 100 on the uppermost material rack 200 is completely fetched, the empty material rack 200 is fed into the material receiving support plate 97 of the material receiving device 9, the material receiving motor 96 is started to drive the material receiving screw rod 94 to rotate, and the material receiving screw rod nut 95 drives the moving plate to move up and down under the action of the material receiving screw rod 94 and the moving plate, so that the collection of the empty material rack 200 is realized. In this embodiment, each time an empty material rack 200 is collected, the material receiving motor 96 drives the material receiving moving plate 92 to descend by the height of one empty material rack 200, so that collection of a plurality of empty material racks 200 is completed, when the empty material racks 200 in the collection box 6 are fully collected, all the empty material racks 200 are sent away by the primary-secondary vehicle 5, and then the material receiving motor 96 drives the material receiving moving plate 92 to move to an initial position.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; may be mechanically connected, may be electrically connected or may be in communication with each other; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

It is apparent that the embodiments described above are only some embodiments of the present application, but not all embodiments, the preferred embodiments of the present application are given in the drawings, but not limiting the patent scope of the present application. This application may be embodied in many different forms, but rather, embodiments are provided in order to provide a more thorough understanding of the present disclosure. Although the present application has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing, or equivalents may be substituted for elements thereof. All equivalent structures made by the specification and the drawings of the application are directly or indirectly applied to other related technical fields, and are also within the protection scope of the application.

Claims (10)

1. The utility model provides a condenser core package automation heat preservation and firing equipment, its heat preservation that is used for loading the material frame that has the iron strap, its characterized in that includes:

the bottom surface of the interior of the heat preservation box is provided with a first sliding rail, and the front end of the heat preservation box is provided with a box door;

the switch cover mechanism is arranged above the heat insulation box;

the feeding mechanism is arranged in the heat insulation box and is used for lifting the material rack layer by layer;

the iron strip taking mechanism is arranged above the switch cover mechanism and is used for sequentially taking out one iron strip of the uppermost material frame in the insulation box;

the primary-secondary car comprises a primary car and a secondary car, the secondary car is used for loading the primary car, the primary car is used for loading stacked multilayer material racks, a second sliding rail is arranged on the primary car, directional pulleys corresponding to the first sliding rail and the second sliding rail are arranged on the primary car, and the heights of the first sliding rail and the second sliding rail are consistent.

2. The automated thermal insulation and loading device for capacitor core bags of claim 1, wherein a plurality of universal pulleys are arranged on the lower surface of the mother car.

3. The automated thermal insulation and loading device for capacitor core packs of claim 1, wherein the iron bar take-off mechanism comprises an iron bar clamping arm and a turnover assembly controlling the turnover of the iron bar clamping arm.

4. The automatic heat preservation and loading device for the capacitor core package according to claim 1, wherein a collecting box is arranged on one side of the back surface of the heat preservation box and used for collecting empty material racks.

5. The automatic heat preservation and feeding equipment for the capacitor core package according to claim 4, wherein a receiving device is arranged on one side, close to the heat preservation box, of the collecting box, the receiving device comprises a receiving fixing plate, a receiving moving plate, a receiving guide rod, a receiving screw rod nut, a receiving motor and a receiving support plate, the receiving guide rod and the receiving screw rod are fixed on the receiving fixing plate, the receiving moving plate is sleeved on the receiving guide rod and the receiving screw rod, the receiving screw rod nut is arranged on the receiving screw rod, the receiving screw rod nut is fixed on the lower surface of the receiving moving plate, and the receiving motor is fixed on the receiving fixing plate and used for driving the receiving screw rod to rotate.

6. The automatic heat preservation and feeding equipment for the capacitor core package according to claim 1, wherein the cover opening and closing mechanism comprises a sealing cover plate, a cover opening driving device, a fixing block and a sealing door, a discharge hole is formed in the sealing cover plate, the cover opening driving device is fixed on the upper surface of the sealing cover plate, the cover opening driving device drives the fixing block to move, and the sealing door is fixed on the fixing block.

7. The automatic heat preservation and feeding equipment for the capacitor core package according to claim 4, wherein a material taking frame opening is formed in the back of the heat preservation box, an oven material taking mechanism is arranged above the collection box and comprises a material taking fixing plate, a material taking motor, a material taking screw rod, a material taking platform and a material taking rod, the material taking motor is fixed on the material taking fixing plate, the material taking screw rod is connected with the material taking motor, the material taking platform is arranged on the material taking screw rod, and the material taking rod is fixed at one end of the material taking platform.

8. The automated thermal insulation and loading device for capacitor core packs of claim 7, wherein a third slide rail is provided on the bottom surface of the interior of the collection box, and the directional pulley corresponds to the first slide rail, the second slide rail and the third slide rail.

9. The automatic heat preservation and feeding equipment for the capacitor core package according to claim 7, wherein an empty material rack transfer mechanism is arranged above the oven material taking mechanism, and comprises a transfer fixing plate, a transfer motor for driving the transfer fixing plate to move and two transfer arms respectively arranged on two sides of the transfer fixing plate, a telescopic cylinder is fixed on each transfer arm, and a transfer plate is fixed at the tail end of each telescopic cylinder.

10. The automatic heat preservation and loading device for the capacitor core package according to claim 1, wherein a wind wheel and a plurality of heating pipes are arranged in the heat preservation box.

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