CN217919902U - New energy automobile inductance tool circulation mechanism - Google Patents

Abstract

The utility model discloses a new energy automobile inductance tool circulation mechanism, including the platen, be equipped with smelting tool feeding cylinder component and smelting tool feed back cylinder component that are opposite setting on the platen, be equipped with smelting tool backward flow conveying assembly between smelting tool feeding cylinder component and the smelting tool feed back cylinder component; a material stirring track, an extension transition track and a tail end track are sequentially arranged along the direction from the smelting tool feeding cylinder assembly to the smelting tool returning cylinder assembly; wherein dial material track, extension transition track and tail end track and arrange in same straight line on, and all with smelting tool backward flow conveying subassembly parallel arrangement, form the station of bending that is used for installing the equipment of bending between extension transition track and the tail end track, dial and install the smelting tool between material track and the smelting tool backward flow conveying subassembly and dial the material subassembly. This scheme can retrieve the smelting tool by oneself and recycle, and whole journey adopts the stability that mechanized energy improve equipment moved simultaneously, guarantees that equipment is in operating condition all the time, improves production efficiency, reduces artificial intensity of labour.

Description

New energy automobile inductance tool circulation mechanism

Technical Field

The utility model relates to a carry technical field, concretely relates to new energy automobile inductance tool circulation mechanism.

Background

With the rapid increase of the development trend of new energy automobiles, the inductor becomes an electronic component with high demand, wherein the magnetic core is an important component of the inductor and is the heart of the inductor, the rectifier and other components in the electrical equipment. Along with the inductance, rectifier element's miniaturization, requirement to the magnetic core is also more and more high, E type magnetic core is bent the E piece and is combined into an organic whole with the magnetic core, because the volume of magnetic core is less, need carry on and carry on the smelting tool and carry the processing, and current processing equipment only can realize semi-automatization, the smelting tool need rely on the workman to retrieve, on placing the smelting tool again conveying equipment, the device still needs artificial participation, not only machining efficiency is low, artificial intensity of labour has still been increased, existing equipment can't satisfy the requirement at high efficiency production.

SUMMERY OF THE UTILITY MODEL

Low, the big defect of intensity of labour of machining efficiency to the existing equipment existence, the utility model relates to a new energy automobile inductance tool circulation mechanism is used for overcoming above-mentioned defect.

A new energy automobile inductance jig circulating mechanism comprises a bedplate, wherein a smelting tool feeding air cylinder assembly and a smelting tool returning air cylinder assembly which are oppositely arranged are arranged on the bedplate; a smelting tool backflow conveying assembly is arranged between the smelting tool feeding air cylinder assembly and the smelting tool return air cylinder assembly; a material stirring track, an extension transition track and a tail end track are sequentially arranged along the direction from the smelting tool feeding air cylinder assembly to the smelting tool returning air cylinder assembly; the material stirring track, the extension transition track and the tail end track are arranged on the same straight line and are all arranged in parallel with the smelting tool backflow conveying assembly; a bending station for installing bending equipment is formed between the extension transition track and the tail end track; a smelting tool material stirring assembly is arranged between the material stirring track and the smelting tool backflow conveying assembly.

As a preferable scheme, the smelting tool feeding cylinder assembly and the smelting tool returning cylinder assembly are symmetrically arranged in structure; the smelting tool feeding cylinder assembly or the smelting tool returning cylinder assembly comprises a first supporting frame arranged on the bedplate; a first mounting plate is arranged on the first support frame; a rodless cylinder is arranged on the first mounting plate; and a cylinder sliding block is arranged on the rodless cylinder.

As a preferred scheme, a second mounting plate is arranged on the cylinder sliding block; a lifting cylinder is arranged on the second mounting plate; an extension plate is arranged at the piston end of the lifting cylinder; the end of the extension plate is provided with a clamping jaw cylinder for clamping a jig.

Preferably, the jig backflow conveying assembly comprises a second support frame arranged on the bedplate; the second support frame is provided with a conveying frame; and a conveying belt is arranged on the conveying frame.

As a preferred scheme, a transmission motor is installed at the bottom of the conveying frame; the transmission motor is connected with the conveying belt through a transmission belt.

As a preferred scheme, the upper surface of the conveying frame is symmetrically provided with conveying belt baffles; and a channel for conveying the smelting tool is formed between the symmetrical baffle plates of the conveying belt.

Preferably, the jig material stirring assembly comprises a third support frame arranged on the bedplate; a third mounting plate is arranged on the third support frame; the material poking track is arranged on the third mounting plate.

As a preferred scheme, a servo motor is installed on the third installation plate; the output end of the servo motor is provided with a screw rod; the third mounting plate is symmetrically provided with first sliding rails; a sliding plate is slidably mounted on the first sliding rail; the slide plate is controlled by the screw.

Preferably, the sliding plate is provided with a fixed cylinder; a kickoff plate is arranged at the piston end of the fixed cylinder; the sliding plate is symmetrically provided with second sliding rails; the kickoff plate is slidably mounted on the second slide rail.

Preferably, the kick-out plate comprises a connecting part and an extending part; the connecting part and the extending part are integrally formed; the connecting part is connected with the piston end of the fixed cylinder; at least two material stirring blocks are uniformly arranged on the extending part at intervals.

The utility model discloses following beneficial effect has: adopt this scheme, at first smelting tool feeding cylinder subassembly takes out the smelting tool from smelting tool backward flow conveying assembly and places on dialling the material track, propelling movement smelting tool forward under the effect of smelting tool dialling the material subassembly, the smelting tool gets into extension transition track along dialling the material track, again by extension transition track enter into the mechanism of bending, after the product is accomplished and is bent the processing back, the smelting tool gets into the tail end track again, after taking out the finished product in the smelting tool, smelting tool feed back cylinder subassembly carries the smelting tool on the tail end track to smelting tool backward flow conveying assembly this moment, smelting tool backward flow conveying assembly carries the smelting tool to smelting tool feeding cylinder subassembly again, form a circulation with this, this scheme can retrieve the circulation use by oneself with the smelting tool, whole journey adopts the mechanization to improve the stability of equipment operation simultaneously, guarantee that equipment is in operating condition all the time, and production efficiency is improved, and artificial intensity of labour is reduced.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a top view of the present invention.

Fig. 3 is the structure schematic diagram of the utility model discloses smelting tool feeding cylinder subassembly.

Fig. 4 is the structure schematic diagram of the tool reflow conveying assembly of the present invention.

Fig. 5 is the structure schematic diagram of the material stirring assembly of the utility model.

Fig. 6 is the structure diagram of the material stirring component of the tool.

Fig. 7 is another view of the tool setting assembly of the present invention.

In the figure: 1-a bedplate; 2-a tool feeding cylinder assembly; 3-a jig backflow conveying assembly; 4-a material poking track; 5-extending the transition track; 6-bending station; 7-tail end track; 8-smelting tool feed back cylinder components; 9-a jig material-pulling component; 201-a first support frame; 202-a first mounting plate; 203-rodless cylinder; 204-cylinder slide block; 205-a second mounting plate; 206-lifting cylinder; 207-extension plate; 208-a jaw cylinder; 301-a second support; 302-a carriage; 303-a conveyor belt; 304-a drive motor; 305-a conveyor belt; 306-conveyor apron; 901-a third support; 902-a third mounting plate; 903-a servo motor; 904-fixed cylinder; 905-a kick-out plate; 906-screw rod; 907-first sliding rail; 908-a sled; 909-second slide; 9051-connecting part; 9052-an extension; 9053-material-pulling block.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic drawings and illustrate the basic structure of the present invention only in a schematic manner, and thus show only the components related to the present invention.

In the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "far", "close", "between", "symmetrical", "parallel", "along", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1

As shown in fig. 1-2, the utility model provides a new energy automobile inductance jig circulating mechanism, which comprises a bedplate 1, wherein a jig feeding cylinder component 2 and a jig returning cylinder component 8 which are oppositely arranged are arranged on the bedplate 1; a smelting tool backflow conveying assembly 3 is arranged between the smelting tool feeding air cylinder assembly 2 and the smelting tool returning air cylinder assembly 8; a material stirring track 4, an extension transition track 5 and a tail end track 7 are sequentially arranged along the direction from the smelting tool feeding cylinder assembly 2 to the smelting tool returning cylinder assembly 8; the material stirring track 4, the extension transition track 5 and the tail end track 7 are arranged on the same straight line and are all arranged in parallel with the smelting tool backflow conveying assembly 3; a bending station 6 for installing bending equipment is formed between the extension transition rail 5 and the tail end rail 7; a smelting tool stirring component 9 is arranged between the stirring track 4 and the smelting tool backflow conveying component 3; adopt this scheme, at first smelting tool feeding cylinder subassembly 2 takes out the smelting tool from smelting tool backward flow conveying assembly 3 and places on dialling material track 4, push forward the smelting tool under the effect of smelting tool dialling material subassembly 9, the smelting tool gets into extension transition track 5 along dialling material track 4, again by extension transition track 5 enter into the mechanism of bending, after the product is accomplished and is bent the processing back, the smelting tool gets into tail end track 7 again, after taking out the finished product in the smelting tool, smelting tool feed back cylinder subassembly 8 carries the smelting tool on tail end track 7 to smelting tool backward flow conveying assembly 3 this moment, smelting tool backward flow conveying assembly 3 carries the smelting tool to smelting tool feeding cylinder subassembly 2 again, form a circulation with this to form, this scheme can retrieve the smelting tool by oneself and recycle, whole journey adopts the mechanization to improve the stability of equipment operation simultaneously, guarantee that equipment is in operating condition all the time, improve production efficiency, reduce artifical intensity of labour.

Example 2

Referring to fig. 3, the present embodiment 2 includes all the technical features of the above embodiments, and the differences are: the smelting tool feeding air cylinder component 2 and the smelting tool returning air cylinder component 8 are symmetrically arranged in structure; the smelting tool feeding cylinder assembly 2 or the smelting tool returning cylinder assembly 8 comprises a first supporting frame 201 installed on the bedplate 1; a first mounting plate 202 is arranged on the first support frame 201; a rodless cylinder 203 is arranged on the first mounting plate 202; the rodless cylinder 203 is provided with a cylinder slide block 204; a second mounting plate 205 is arranged on the cylinder sliding block 204; a lifting cylinder 206 is arranged on the second mounting plate 205; the piston end of the lifting cylinder 206 is provided with an extension plate 207; the tail end of the extension plate 207 is provided with a clamping jaw cylinder 208 for clamping a jig; by adopting the scheme, when the smelting tool returns to one end of the smelting tool feeding air cylinder component 2 under the action of the smelting tool backflow conveying component 3, the rodless air cylinder 203 drives the clamping jaw air cylinder 208 to return to the original position through the air cylinder sliding block 204, at the moment, the piston end of the lifting air cylinder 206 descends to reduce the height of the clamping jaw air cylinder 208, so that the clamping jaw air cylinder 208 can clamp the smelting tool on the smelting tool backflow conveying component 3, at the moment, the piston end of the lifting air cylinder 206 ascends to lift the smelting tool and moves forwards under the action of the rodless air cylinder 203 until the rodless air cylinder 203 and the material stirring rail 4 are on the same straight line, at the moment, the piston end of the lifting air cylinder 206 descends to place the smelting tool on the material stirring rail 4 and loosen the smelting tool, and an action process is completed; the smelting tool return air cylinder assemblies 8 are symmetrically arranged in the structure, so that the action sequence of the smelting tool return air cylinder assemblies 8 is opposite to that of the smelting tool feed air cylinder assemblies 2, the smelting tools on the tail end rail 7 are taken out and placed on the smelting tool backflow conveying assembly 3, and an action process is completed; the process is repeated to realize the continuous feeding of the smelting tool, so that the production efficiency is improved, and the labor intensity of workers is reduced.

Example 3

Referring to fig. 4, the present embodiment 3 includes all the technical features of the above embodiments, and the differences are that: the jig backflow conveying assembly 3 comprises a second supporting frame 301 arranged on the bedplate 1; a conveying frame 302 is arranged on the second supporting frame 301; a conveying belt 303 is arranged on the conveying frame 302; the bottom of the conveying frame 302 is provided with a transmission motor 304; the transmission motor 304 is connected with the conveying belt 303 through a transmission belt 305; the upper surface of the conveying frame 302 is symmetrically provided with a conveying belt baffle 306; the symmetrical conveyer belt baffles 306 form a channel for conveying the tool; adopt this scheme, place the smelting tool behind the passageway that is used for carrying the smelting tool between the conveyer belt baffle 306 of symmetry as smelting tool feed back cylinder subassembly 8, because conveyer belt baffle 306 plays limiting displacement to the smelting tool, consequently, after driving motor 304 drives conveyer belt 303 work, the smelting tool removes along a direction under the drive of conveyer belt 303, the phenomenon of off-position can not appear, has improved the efficiency of carrying, saves time, increases of production.

Example 4

Referring to fig. 5 to 7, the present embodiment 4 includes all the technical features of the above embodiments, except that: the smelting tool stirring assembly 9 comprises a third support frame 901 which is arranged on the bedplate 1; a third mounting plate 902 is arranged on the third support frame 901; the material shifting track 4 is arranged on the third mounting plate 902; a servo motor 903 is mounted on the third mounting plate 902; the output end of the servo motor 903 is provided with a screw 906; the third mounting plate 902 is symmetrically provided with first sliding rails 907; a sliding plate 908 is slidably mounted on the first sliding rail 907; the sliding plate 908 is controlled by the screw 906; a fixed cylinder 904 is arranged on the sliding plate 908; a kickoff plate 905 is arranged at the piston end of the fixed cylinder 904; the sliding plate 908 is symmetrically provided with second sliding rails 909; the kick-out plate 905 is slidably mounted on the second slide rail 909; the kick-out plate 905 comprises a connecting part 9051 and an extending part 9052; the connecting part 9051 and the extending part 9052 are integrally formed; the connecting part 9051 is connected with the piston end of the fixed cylinder 904; at least two material pulling blocks 9053 are uniformly arranged on the extending portion 9052 at intervals, preferably, 5 material pulling blocks 9053 are arranged on the extending portion 9052, a material pulling station is formed between every two adjacent material pulling blocks 9053, and each material pulling station corresponds to one jig, so that 4 jigs can be pulled to move simultaneously, and the moving stability of subsequent jigs is guaranteed; by adopting the structure, a piston rod of a fixed cylinder 904 is pushed out, at the moment, a material shifting block 9053 enters a material shifting rail 4, each smelting tool corresponds to a material shifting station, at the moment, a servo motor 903 drives a sliding plate 908 to move towards the direction of a smelting tool material returning cylinder component 8 through a screw 906, each smelting tool moves forwards by one station under the action of the material shifting block 9053, after the movement is finished, the fixed cylinder 904 retreats to drive a material shifting plate 905, namely, the material shifting block 9053 retreats from the outer side of the material shifting rail 4, at the moment, the servo motor 903 drives the sliding plate 908 to move towards the direction of a smelting tool feeding cylinder component 2 through the screw 906 to move a station, the fixed cylinder 904 pushes out the material shifting block 9053 again, the steps are repeated continuously, the smelting tools are conveyed forwards, the smelting tools arranged at the tail end of the material shifting rail 4 enter a bending mechanism through an extension transition rail 5, the bent smelting tools enter a rail 7, after finished products are taken out, the smelting tools on the tail end rail 7 are taken out and are placed on a smelting tool return conveying component 3, and an action process is finished product is completed; the process is repeated to realize the continuous feeding of the smelting tool, so that the production efficiency is improved, and the labor intensity of workers is reduced.

In the description herein, references to the description of the terms "one embodiment," "certain embodiments," "an illustrative embodiment," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above, it will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, but that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present specification describes embodiments, not every embodiment includes only a single embodiment, and such description is for clarity purposes only, and it is to be understood that all embodiments may be combined as appropriate by one of ordinary skill in the art to form other embodiments as will be apparent to those of skill in the art from the description herein.

Claims (10)

1. The utility model provides a new energy automobile inductance tool circulation mechanism, includes platen, its characterized in that:

the bedplate is provided with a smelting tool feeding cylinder component and a smelting tool returning cylinder component which are oppositely arranged; a smelting tool backflow conveying assembly is arranged between the smelting tool feeding air cylinder assembly and the smelting tool return air cylinder assembly; a material stirring track, an extension transition track and a tail end track are sequentially arranged along the direction from the smelting tool feeding air cylinder assembly to the smelting tool returning air cylinder assembly; the material stirring track, the extension transition track and the tail end track are arranged on the same straight line and are all arranged in parallel with the smelting tool backflow conveying assembly; a bending station for installing bending equipment is formed between the extension transition track and the tail end track; a smelting tool material stirring assembly is arranged between the material stirring track and the smelting tool backflow conveying assembly.

2. The new energy automobile inductance jig circulating mechanism is characterized in that the jig feeding cylinder assembly and the jig returning cylinder assembly are symmetrically arranged in structure; the smelting tool feeding cylinder assembly or the smelting tool returning cylinder assembly comprises a first supporting frame arranged on the bedplate; a first mounting plate is arranged on the first support frame; a rodless cylinder is arranged on the first mounting plate; and a cylinder sliding block is arranged on the rodless cylinder.

3. The new energy automobile inductance jig circulating mechanism is characterized in that a second mounting plate is arranged on the cylinder sliding block; a lifting cylinder is arranged on the second mounting plate; an extension plate is arranged at the piston end of the lifting cylinder; the tail end of the extension plate is provided with a clamping jaw air cylinder used for clamping a jig.

4. The new energy automobile inductance jig circulating mechanism as claimed in claim 1, wherein the jig reflow conveying assembly comprises a second support frame mounted on the platen; the second supporting frame is provided with a conveying frame; and a conveying belt is arranged on the conveying frame.

5. The new energy automobile inductance jig circulating mechanism is characterized in that a transmission motor is mounted at the bottom of the conveying frame; the transmission motor is connected with the conveying belt through a transmission belt.

6. The new energy automobile inductance jig circulating mechanism is characterized in that conveying belt baffles are symmetrically arranged on the upper surface of the conveying frame; and a channel for conveying the smelting tool is formed between the symmetrical baffle plates of the conveying belt.

7. The new energy automobile inductance jig circulating mechanism is characterized in that the jig poking assembly comprises a third support frame arranged on the bedplate; a third mounting plate is arranged on the third support frame; the material poking track is arranged on the third mounting plate.

8. The new energy automobile inductance jig circulating mechanism is characterized in that a servo motor is mounted on the third mounting plate; the output end of the servo motor is provided with a screw rod; the third mounting plate is symmetrically provided with first slide rails; a sliding plate is slidably mounted on the first sliding rail; the sliding plate is controlled by the screw rod.

9. The new energy automobile inductance jig circulating mechanism is characterized in that a fixed cylinder is mounted on the sliding plate; a kickoff plate is arranged at the piston end of the fixed cylinder; the sliding plate is symmetrically provided with second sliding rails; the kickoff plate is slidably mounted on the second slide rail.

10. The new energy automobile inductance jig circulating mechanism according to claim 9, characterized in that the kickoff plate comprises a connecting part and an extending part; the connecting part and the extending part are integrally formed; the connecting part is connected with the piston end of the fixed cylinder; at least two material stirring blocks are uniformly arranged on the extending part at intervals.

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