CN116237803B - Incomplete roll processing apparatus of bimetal disc - Google Patents

Abstract

The application relates to the field of temperature controller production, in particular to a bimetal disc stub roll processing device which comprises a guiding-out mechanism and a cutting mechanism which are arranged at one output end of a forming machine body, wherein the guiding-out mechanism is connected with the cutting mechanism and is communicated with the output end of the forming machine body, one side of the forming machine body is provided with a collecting mechanism corresponding to the output end of the guiding-out mechanism, and the cutting mechanism is provided with an adjusting mechanism for adjusting the output direction of the guiding-out mechanism. The application can facilitate the processing of the processed coiled material raw material, so as to achieve the purpose of reducing the occupation of the coiled material raw material on the position of the workbench.

Description

Incomplete roll processing apparatus of bimetal disc

Technical Field

The application relates to the field of temperature controller production, in particular to a bimetal disc incomplete roll treatment device.

Background

The kick temperature controller is one of the temperature controllers, and is physically deformed inside a switch according to the temperature change of the working environment, so that certain special effects are generated, and a series of automatic control elements for on-off actions are generated.

The conventional double-metal disc of the kick temperature controller needs to be formed into a concave-convex shape to be used as a thermosensitive element of the temperature controller. The core material of the bimetal disc is a bimetal disc formed by two or more alloy layers with different expansion coefficients through a high-precision compounding technology. After being pressed by accurate bending, the steel has the jump performance. When the temperature rises and reaches the action temperature of the bimetallic strip in operation, the concave-convex surface suddenly turns over, the original convex surface is changed into the concave surface, the concave surface is changed into the convex surface, when the temperature drops to a certain temperature, the concave-convex surface of the bimetallic strip turns over again to return to the normal state, the contact of the snap-action temperature controller is switched on or off by utilizing the characteristic, and the temperature rising and cooling action temperature point of the bimetallic strip can be controlled through molding.

The existing bimetal disc is a coiled material raw material before processing and forming, and finally forms the bimetal disc after processing processes such as feeding, preheating, forming, ageing, detecting and sorting in an automatic disc forming machine. However, the coil stock at present falls directly to the workstation after the processing of disc automatic molding machine, in order to reduce the occupation of coil stock to workstation position, need regularly to carry out the rolling clearance to the coil stock after processing, lead to the increase of human cost.

Disclosure of Invention

In order to facilitate the processing of the processed coiled material raw material and achieve the purpose of reducing the occupation of the coiled material raw material to the position of a workbench, the application provides a double-metal disc residual coil processing device.

The application provides a double-metal disc incomplete roll treatment device which adopts the following technical scheme:

the utility model provides a incomplete roll of bimetal disc processing apparatus, includes and sets up in export mechanism and the cutting mechanism of make-up machine body output one end, export the mechanism and be connected and be linked together with the output of make-up machine body with the cutting mechanism, one side of make-up machine body is provided with export the corresponding collection mechanism of mechanism output, be provided with the adjustment mechanism who is used for adjusting export mechanism output direction on the cutting mechanism.

Through adopting above-mentioned technical scheme, export the mechanism and can lead the coiled material raw materials after processing to cut mechanism department and cut, coiled material raw materials after cutting is transferred to the collection mechanism in again along export mechanism and is stored and collect, reaches the purpose that reduces coiled material raw materials and occupy the workstation position, in addition, through adjustment mechanism's setting, can be convenient for carry out nimble adjustment to export the output direction of mechanism to be convenient for improve the continuity to garbage collection, and then promote the efficiency to bimetal disc shaping processing effectively.

Preferably, the cutting mechanism comprises a mounting assembly and a cutting assembly, the mounting assembly is connected with the output end of the forming machine body, and the cutting assembly is arranged on the mounting assembly, and the output end of the cutting assembly corresponds to the output end of the forming machine body.

Preferably, the guiding mechanism comprises a connecting component and a discharging component, the connecting component is arranged on one side of the mounting component, and the discharging component is movably connected with the mounting component through the connecting component.

Through adopting above-mentioned technical scheme, the coiled material raw materials after the subassembly of unloading can be with the coiled material raw materials after processing guide to cutting assembly department steadily, and the rethread cutting assembly's output cuts coiled material raw materials fast for in the minor segment coiled material raw materials after cutting can continue to steadily follow the subassembly of unloading and lead to send collection mechanism, reach the purpose of conveniently collecting the waste material.

Preferably, the adjusting mechanism comprises a lifting assembly and an abutting assembly, the lifting assembly is arranged on the cutting mechanism, the output end of the lifting assembly is connected with the guiding mechanism, and the guiding mechanism is connected with the output end of the forming machine body through the abutting assembly.

Through adopting above-mentioned technical scheme, lifting unit can adjust export the output direction of mechanism to through changing the removal direction of coiled material raw materials after cutting, reach the purpose that improves garbage collection continuity, in addition, through setting up adjacent subassembly, can make further direction to the coiled material raw materials after cutting, thereby realize effectively promoting garbage collection stability.

Preferably, the adjacent assembly comprises a connecting bar and a blanking plate, the blanking plate is rotationally connected with the output end of the forming machine body, and the connecting bar is rotationally connected with the movable side of the blanking plate and is rotationally connected with the guiding-out mechanism.

Preferably, the lifting assembly comprises a movable block and a lifting air cylinder, the movable block is slidably connected to one side of the material guiding mechanism, and the lifting air cylinder is arranged on the cutting mechanism and the output end of the lifting air cylinder is connected with the movable block.

Through adopting above-mentioned technical scheme, the lifting cylinder can be adjusted the height of movable block for guiding mechanism can carry out the adjustment of position under the drive of movable block, thereby reaches the purpose of nimble change export mechanism output direction.

Preferably, the collecting mechanism comprises an aggregate component and an induction component, the aggregate component is arranged on one side of the forming machine body and corresponds to the output end of the guiding mechanism, and the induction component is arranged in the aggregate component and is electrically connected with the lifting component.

Through adopting above-mentioned technical scheme, collection subassembly can store the waste material of follow export mechanism output and collect, and through the setting of response subassembly, can be according to the pressure variation of received with electric signal transmission to lifting unit department to change the direction of export mechanism output through lifting unit, thereby improved the continuity that collection subassembly was collected the waste material and was stored.

Preferably, the aggregate assembly comprises a bottom frame and a charging basket, wherein the charging basket is provided with a plurality of charging baskets, the bottom frame is arranged on one side of the forming machine body, and the charging basket is arranged on the bottom frame and correspondingly arranged below the guiding-out mechanism and the blanking plate.

Through adopting above-mentioned technical scheme, set up a plurality of storage barrels, can be convenient for store the waste material of follow export of export mechanism's different output direction, reach the purpose that promotes the storage continuity effectively.

Preferably, the collecting mechanism further comprises a uniform discharging assembly, the uniform discharging assembly is arranged on the underframe and connected with the charging barrels, and the uniform discharging assembly is electrically connected with the sensing assembly.

Through adopting above-mentioned technical scheme, even put the subassembly and can be after receiving the signal of telecommunication of response subassembly, adjust the inclination of storage bucket in a flexible way to a plurality of storage buckets can store the waste material more evenly.

Preferably, the cutting assembly comprises a cutter and a cutting cylinder, the cutting cylinder is arranged on the mounting assembly, and the cutter is arranged at the output end of the cutting cylinder and corresponds to the guiding-out mechanism in position.

Through adopting above-mentioned technical scheme, cutting cylinder drive cutter cuts coiled material raw materials fast, and the short section waste material that is enough through cutting then directly falls to export mechanism department to finally send into the subassembly that gathers materials through export mechanism's output and store and collect.

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

1. during operation, the export mechanism can guide the processed coiled material raw materials to the cutting mechanism for cutting, the cut coiled material raw materials are transferred into the collecting mechanism along the export mechanism for storage and collection, the purpose of reducing occupation of the coiled material raw materials to the position of the workbench is achieved, in addition, the output direction of the export mechanism can be flexibly adjusted through the arrangement of the adjusting mechanism, so that the continuity of garbage collection is conveniently improved, the efficiency of forming and processing the bimetallic disc is effectively improved, and the export mechanism has a large popularization effect in industry;

2. through setting up the lifting unit, can adjust the output direction of deriving the mechanism to through changing the removal direction of coiled material raw materials after cutting, reach the purpose that improves the garbage collection continuity, in addition, through setting up the adjacent subassembly, can carry out further direction to the coiled material raw materials after cutting, thereby realize the effective promotion to garbage collection stability;

3. through setting up the subassembly that gathers materials, can store the waste material of gathering out the output of mechanism, and through setting up of response subassembly, can be according to the pressure variation that receives with the electric signal transmission to lifting unit department to change the direction of gathering out the mechanism output through lifting unit, thereby improved the continuity that gathers materials the subassembly and collect the waste material and store;

4. through setting up even putting the subassembly, can be after receiving the signal of telecommunication of response subassembly, adjust the inclination of storage bucket in a flexible way to a plurality of storage buckets can store the waste material more evenly.

Drawings

FIG. 1 is a schematic view showing the overall structure of a forming machine body and a stub roll processing device according to an embodiment of the present application;

FIG. 2 is a schematic diagram of the overall structure of a stub roll processing apparatus according to an embodiment of the present application;

FIG. 3 is an enlarged view of portion A of FIG. 2;

FIG. 4 is a schematic view of a barrel and sensing assembly according to an embodiment of the present application;

FIG. 5 is a schematic diagram of a discharging assembly and a lifting assembly according to an embodiment of the present application;

fig. 6 is a schematic view of the overall structure of the mounting assembly according to the embodiment of the present application.

Reference numerals illustrate:

1. a molding machine body; 2. a lead-out mechanism; 21. a connection assembly; 22. a discharge assembly; 3. a cutting mechanism; 31. a mounting assembly; 311. an extension plate; 312. a bottom plate; 32. a cutting assembly; 321. a cutter; 322. a cutting cylinder; 323. a fixed cover; 324. an L-shaped auxiliary plate; 325. a pushing cylinder; 4. a collection mechanism; 41. an aggregate assembly; 411. a chassis; 412. a charging barrel; 42. an induction assembly; 421. a pressure sensor; 422. a contact plate; 43. uniformly placing the components; 431. a supporting plate; 432. the connecting cylinder; 5. an adjusting mechanism; 51. a lifting assembly; 511. a movable block; 512. a lifting cylinder; 52. an abutment assembly; 521. a connecting strip; 522. and (5) blanking plates.

Detailed Description

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

Examples:

the embodiment of the application discloses a device for processing a residual roll of a bimetal disc, which comprises a guiding-out mechanism 2 and a cutting mechanism 3, referring to fig. 1 and 2, wherein the cutting mechanism 3 is arranged at one side of an output end of a forming machine body 1, the guiding-out mechanism 2 is arranged at one side of the cutting mechanism 3 and corresponds to the output end of the forming machine body 1, and meanwhile, one side of the guiding-out mechanism 2 is communicated with the output end of the cutting mechanism 3. The collecting mechanism 4 is provided on the output side of the molding machine body 1, and the collecting mechanism 4 is entirely located below the discharging mechanism 2.

During operation, coiled material raw materials enter from the input end of the forming machine body 1, are output from the output end after being preheated, formed, aged, detected, sorted and other processing processes of the forming machine body 1, enter into the cutting mechanism 3 for rapid cutting under the guiding of the guiding-out mechanism 2, form waste materials after cutting, and finally fall into the collecting mechanism 4 for collecting and storing under the guiding of the guiding-out mechanism 2.

Referring to fig. 1 and 2, in the present embodiment, the cutting mechanism 3 includes a mounting assembly 31 and a cutting assembly 32. Wherein, the mounting component 31 is fixed on the output side of the forming machine body 1, and the cutting component 32 is mounted on the mounting component 31 and connected with the guiding-out mechanism 2.

Meanwhile, referring to fig. 1 and 3, in the present embodiment, the guiding mechanism 2 includes a connecting assembly 21 and a discharging assembly 22. The discharging assembly 22 is integrally located below the output end of the cutting assembly 32, and is connected with the mounting assembly 31 through the connecting assembly 21. In operation, the web material is fed from the output end of the former body 1 and conveyed along the direction of extension of the discharge assembly 22 to the output end side of the cutting assembly 32, and then slit through the output end of the cutting assembly 32.

Referring to fig. 2 and 4, in the present embodiment, the collection mechanism 4 includes a collection assembly 41 and a sensing assembly 42. The aggregate assembly 41 is provided at one side of the molding machine body 1, and the sensing assembly 42 is installed inside the aggregate assembly 41. In order to flexibly adjust the output direction of the discharging assembly 22, an adjusting mechanism 5 electrically connected to the sensing assembly 42 is installed on one side of the mounting assembly 31, and an output end of the adjusting mechanism 5 is connected to the bottom of the discharging assembly 22.

Referring to fig. 3 and 5, in the present embodiment, the adjusting mechanism 5 includes a lifting assembly 51 and an abutting assembly 52. The lifting assembly 51 is integrally disposed on a side wall of the mounting assembly 31, and two ends of the adjacent assembly 52 are respectively rotatably connected with the unloading assembly 22 and an output end of the forming machine body 1.

During operation, the waste material from the unloading assembly 22 is collected by the material collecting assembly 41, and when the waste material is accumulated to a certain amount, the sensing assembly 42 can sense the pressure change at the bottom of the material collecting assembly 41 and transmit an electric signal to the lifting assembly 51, and the lifting assembly 51 can adjust the output direction of the material collecting assembly 22 through the output end after obtaining the signal, so that people can conveniently transfer and clean the waste material in the material collecting assembly 41, the storing and collecting work of the waste material can be uninterrupted, and the production efficiency of enterprises is greatly improved.

Referring to fig. 3 and 6, in the present embodiment, the mounting assembly 31 includes an extension plate 311 and a bottom plate 312. Wherein, the cross section of the extension plate 311 is a right trapezoid, and the bottom plate 312 is installed on one side of the extension plate 311 far away from the hypotenuse of one side of the molding machine body 1. Meanwhile, the cutting assembly 32 includes a cutter 321 and a cutting cylinder 322. In order to adapt to the conveying direction of the coil stock, the cutter cylinder 322 is integrally mounted on the bottom plate 312, and the cutter 321 is mounted at the output end of the cutter cylinder 322 and integrally faces one side of the coil stock.

In order to facilitate the cutting of the coil stock by the cutting cylinder 322, a fixed cover 323 is attached to the extension plate 311 at a position corresponding to the cutting cylinder 322, the whole fixed cover 323 covers the outside of the cutting cylinder 322, and an L-shaped auxiliary plate 324 is attached to one side of the fixed cover 323, wherein the whole L-shaped auxiliary plate 324 is located above the cutter 321 and the inner arm can be abutted against the coil stock.

Referring to fig. 2 and 3, in the present embodiment, the connection assembly 21 includes a rotation shaft, one end of which is rotatably connected to the side wall of the extension plate 311 and is integrally located below the output end of the cutting cylinder 322. Meanwhile, in this embodiment, the discharging component 22 includes two arc blocks and a side plate, the two arc blocks are respectively fixed at two sides of the rotating shaft and the arc faces the direction close to the cutter 321, and the side plate is located at the position where the arc blocks are far away from the cutter 321.

In addition, in the present embodiment, the lifting assembly 51 includes a movable block 511 and a lifting cylinder 512. Wherein, lift cylinder 512 is installed in the lateral wall of extension board 311, and movable block 511 sliding connection is in the bottom of one of them arc piece, and the bottom of movable block 511 is connected with lift cylinder 512's output.

Referring to fig. 1 and 2, in the present embodiment, the aggregate assembly 41 includes a chassis 411 and a bowl 412. Wherein, the chassis 411 is integrally located at one side of the molding machine body 1, and two charging barrels 412 are provided, the two charging barrels 412 are both mounted on the chassis 411, and openings of the two charging barrels 412 respectively correspond to positions of the two arc blocks.

When the movable block 511 is used, the movable block 511 can slide at the bottom of the arc blocks under the driving of the lifting cylinder 512, so that the two arc blocks integrally move with the rotary shaft as the center, and the purpose of adjusting the output position of waste materials can be achieved by flexibly changing the position of the discharging assembly 22, so that the waste materials can fall into one of the charging barrels 412 when the other charging barrel 412 is full, and the purpose of continuously collecting the waste materials is achieved.

Referring to fig. 2 and 4, in order to better promote the uniformity of the placement of the waste material in the bucket 412, a uniform placement assembly 43 is disposed between the chassis 411 and the bucket 412, and in this embodiment, the uniform placement assembly 43 includes a pallet 431 and a connecting cylinder 432. The whole support plate 431 is rotatably connected with the inner side of the bottom frame 411 through a connecting shaft, a connecting cylinder 432 is mounted on the bottom frame 411, and the output end of the connecting cylinder is connected with the bottom of one movable side of the support plate 431, so that the purpose of driving the whole support plate 431 to overturn and swing is achieved.

In addition, in the present embodiment, the sensing component 42 includes a pressure sensor 421 and a contact plate 422, the pressure sensor 421 is mounted on the bottom wall of the bucket 412, the contact plate 422 is mounted on the top of the pressure sensor 421, and the pressure sensor 421 is electrically connected to the lifting cylinder 512. In operation, the pressure sensor 421 is used to sense the weight change of the waste material on the interference plate, so as to transmit the electric signal to the lifting cylinder 512, thereby achieving the purpose of controlling the falling direction of the waste material.

In addition, referring to fig. 2 and 4, in order to monitor the uniformity of placing the waste material inside the charging basket 412 in real time, grooves are formed in two opposite inner sidewalls of the charging basket 412, and the sensing assemblies 42 are mounted in the grooves, and meanwhile, the pressure sensor 421 in the grooves is electrically connected with the connecting cylinder 432.

During operation, when the waste material on one side of the charging basket 412 is too much, the pressure sensor 421 in the groove on one side senses the pressure change, i.e. transmits the electric signal to the connecting cylinder 432, and the connecting cylinder 432 drives the supporting plate 431 to move at this moment, so that the uniformity of stacking the waste material in the charging basket 412 is effectively improved, and more waste material is conveniently stored through the charging basket 412.

Referring to fig. 2 and 3, in the present embodiment, the abutment assembly 52 includes a connecting bar 521 and a blanking plate 522. Wherein, the blanking plate 522 articulates the bottom side of guide board in shaping machine body 1 output department, and the one end of connecting strip 521 articulates in one side of blanking plate 522, and simultaneously, the other end of connecting strip 521 articulates with the lateral wall that is close to shaping machine body 1 one side arc piece mutually, and in this embodiment, connecting strip 521 is the telescopic link, blanking plate 522 is the telescopic link.

When the lifting cylinder 512 adjusts the position of the arc-shaped block, the blanking plate 522 can rotate under the drive of the connecting strip 521, and the blanking plate 522 after overturning can limit the waste materials output from the arc-shaped block on one side close to the forming machine body 1, so that the aim of improving the stability of waste material collection is fulfilled.

In addition, referring to fig. 2 and 4, in order to facilitate the adjustment of the position of the cutting cylinder 322, a push cylinder 325 is installed at the top of the extension plate 311, wherein the cutting cylinder 322 is slidably connected to the top of the extension plate 311, and the output end of the push cylinder 325 is connected to the cutting cylinder 322, and at the same time, the push cylinder 325 is electrically connected to a pressure sensor 421 at the bottom wall of the barrel 412.

During operation, when the pressure sensor 421 at the bottom wall of the charging basket 412 senses that the pressure changes to half of the storage capacity of the charging basket 412, an electric signal is transmitted to the pushing cylinder 325, and at this time, the pushing cylinder 325 drives the cutting cylinder 322 to move along the upper end of the extension plate 311 so as to adjust the position of the cutter 321, thereby facilitating control of the cutting length of the cutter 321 to the coiled material, and achieving the purpose of effectively improving the storage capacity of the charging basket 412.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (6)

1. The utility model provides a incomplete roll of bimetal disc processing apparatus which characterized in that: the device comprises a guiding mechanism (2) and a cutting mechanism (3) which are arranged at one output end of a forming machine body (1), wherein the guiding mechanism (2) is connected with the cutting mechanism (3) and is communicated with the output end of the forming machine body (1), one side of the forming machine body (1) is provided with a collecting mechanism (4) corresponding to the output end of the guiding mechanism (2), and an adjusting mechanism (5) for adjusting the output direction of the guiding mechanism (2) is arranged on the cutting mechanism (3);

the cutting mechanism (3) comprises a mounting assembly (31) and a cutting assembly (32), the mounting assembly (31) is connected with one output end of the forming machine body (1), and the cutting assembly (32) is arranged on the mounting assembly (31) and the output end corresponds to one output end of the forming machine body (1);

the guiding-out mechanism (2) comprises a connecting component (21) and a discharging component (22), the connecting component (21) is arranged on one side of the mounting component (31), and the discharging component (22) is movably connected with the mounting component (31) through the connecting component (21);

the adjusting mechanism (5) comprises a lifting assembly (51) and an adjacent assembly (52), the lifting assembly is arranged on the cutting mechanism (3) and the output end of the lifting assembly is connected with the guiding mechanism (2), and the guiding mechanism (2) is connected with the output end of the forming machine body (1) through the adjacent assembly (52);

the abutting assembly (52) comprises a connecting strip (521) and a blanking plate (522), the blanking plate (522) is rotationally connected with one output end of the forming machine body (1), and the connecting strip (521) is rotationally connected to the movable side of the blanking plate (522) and is rotationally connected with the guiding-out mechanism (2).

2. The apparatus for processing a stub roll of a bimetallic disk as recited in claim 1, wherein: the lifting assembly (51) comprises a movable block (511) and a lifting air cylinder (512), the movable block (511) is slidably connected to one side of the material guiding mechanism (2), and the lifting air cylinder (512) is arranged on the cutting mechanism (3) and the output end of the lifting air cylinder is connected with the movable block (511).

3. The apparatus for processing a stub roll of a bimetallic disk as recited in claim 2, wherein: the collecting mechanism (4) comprises an aggregate component (41) and an induction component (42), wherein the aggregate component (41) is arranged on one side of the forming machine body (1) and corresponds to the output end of the guiding mechanism (2), and the induction component (42) is arranged in the aggregate component (41) and is electrically connected with the lifting component (51).

4. A dual-metal disc stub roll processing apparatus according to claim 3, wherein: the aggregate assembly (41) comprises a bottom frame (411) and a charging basket (412), wherein the charging basket (412) is provided with a plurality of charging baskets (411), the bottom frame (411) is arranged on one side of the forming machine body (1), and the charging basket (412) is arranged on the bottom frame (411) and correspondingly arranged below the guide-out mechanism (2) and the blanking plate (522).

5. A dual-metal disc stub roll processing apparatus according to claim 3, wherein: the collecting mechanism (4) further comprises a uniform discharging component (43), the uniform discharging component (43) is arranged on the underframe (411) and connected with the charging drums (412), and the uniform discharging component (43) is electrically connected with the sensing component (42).

6. A dual-metal disc stub roll processing apparatus according to claim 3, wherein: the cutting assembly (32) comprises a cutter (321) and a cutting cylinder (322), the cutting cylinder (322) is arranged on the mounting assembly (31), and the cutter (321) is arranged at the output end of the cutting cylinder (322) and corresponds to the guiding-out mechanism (2) in position.