CN217493256U - Automatic spinning forming device of shell - Google Patents

Abstract

The utility model relates to an automatic spin forming device of shell, including the frame, set up centre gripping subassembly and spin forming subassembly in the frame, the centre gripping subassembly is used for centre gripping shell raw materials, and the spin forming subassembly includes: the bidirectional movement module is arranged on the rack; the spinning module is arranged on the bidirectional movement module; and the cutting knife module is arranged on the bidirectional movement module and is used for cutting the shell which is spun into a preset shape to a preset size. The utility model discloses when shell lateral wall size need be less than shell bottom thickness, utilize the cutting knife module directly to cut the shell lateral wall to preset size, need not the shell and reinstall the cutting that carries out overall dimension on cutting equipment, reduced the step of centre gripping again, improved production efficiency, and the same group's two-way motion module of cutting knife module and spinning module sharing, practiced thrift the manufacturing cost of device.

Description

Automatic spinning forming device of shell

Technical Field

The utility model belongs to the technical field of the spinning-lathe technique and specifically relates to indicate an automatic spinning forming device of shell.

Background

The spinning is to fix the flat or hollow blank on the die of the spinning machine, and press the blank with spinning wheel or driving rod while the blank rotates along with the main shaft of the machine to make it generate local plastic deformation. Along with the progress of the process and the processing and use requirements of people, the requirements on the shape and the size of parts are higher and higher, in the field of machining, the shell of some parts needs to be processed into the outline size with thick bottom and thin side wall, but the spinning machine can only change the shape of the raw material and cannot change the thickness of the raw material, after the shell raw material is spun into the preset shape by the spinning machine, the shell spun into the preset shape needs to be installed on a cutting device again for cutting the outline size, so that the part production needs to be clamped again after being transported from the spinning machine to the cutting device, and the production process is complicated.

SUMMERY OF THE UTILITY MODEL

Therefore, the utility model discloses the technical problem that will solve lies in overcoming among the prior art spinning-lathe and can't change shell raw materials thickness, the inconvenient problem of special overall dimension's shell production.

In order to solve the technical problem, the utility model provides an automatic spin forming device of shell, which comprises a frame, set up centre gripping subassembly and spin forming subassembly in the frame, the centre gripping subassembly is used for centre gripping shell raw materials, the spin forming subassembly includes

The bidirectional movement module is arranged on the rack;

the spinning module is arranged on the bidirectional movement module and is used for spinning the shell raw material into a shell with a preset shape;

and the cutting knife module is arranged on the bidirectional movement module and used for cutting the shell which is spun into a preset shape to a preset size.

In an embodiment of the present invention, the cutting knife module includes a knife rest and a knife head, the knife rest is disposed on the two-way movement module, and the knife head is disposed on the knife rest.

In an embodiment of the present invention, the tool post is rotatably connected to the two-way movement module.

In an embodiment of the present invention, the two-way movement module is provided with a material receiving box.

In an embodiment of the present invention, the material receiving box is obliquely arranged on the two-way movement module.

In one embodiment of the present invention, the clamping assembly comprises

A rotary drive source provided on the chassis;

the driving rotating shaft is arranged at the output end of the rotating driving source;

the driven rotating shaft is rotatably connected to the rack, and the shell raw material is clamped between the driving rotating shaft and the driven rotating shaft.

In an embodiment of the present invention, the driven shaft is rotatably connected to the frame through a bearing.

The utility model discloses an embodiment, set up the automatic feeding subassembly in the frame, the automatic feeding subassembly includes:

the discharging frame is arranged on the rack and used for placing shell raw materials;

the blanking module is arranged on the material placing frame and used for pushing the shell raw material on the material placing frame to the clamping component;

and the supporting module is arranged on the bidirectional movement module and used for supporting the shell raw material clamped by the clamping assembly.

In an embodiment of the present invention, the blanking module includes

The blanking frame is arranged on the blanking frame;

the blanking groove is arranged in the blanking frame;

the smashing plate is arranged in the blanking groove and used for pushing the shell raw material to the supporting module;

the blanking cylinder is arranged on the blanking frame and used for pushing the smashing plate to slide in the blanking groove;

the material supporting rod is connected to the blanking frame in a rotating mode through a torsional spring and used for supporting the shell raw materials entering the blanking groove.

In an embodiment of the present invention, the supporting module comprises

The adjusting cylinder is arranged on the bidirectional movement module;

the material bearing seat is arranged on the adjusting cylinder;

the adjusting cylinder drives the material bearing seat to move up and down, and the vertical distance from the material bearing seat to the clamping assembly is adjusted.

Compared with the prior art, the technical scheme of the utility model have following advantage:

an automatic spinning forming device of shell, through set up the cutting knife module on the two-way motion module, when shell lateral wall size need be less than shell bottom thickness, the cutting knife module can cut the shell of spinning forming of spinning module, utilize the cutting knife module directly to cut the shell lateral wall to preset size, need not the shell and install the cutting of carrying out overall dimension again on cutting equipment, the step of reinstallating has been reduced, the production efficiency is improved, and the same two-way motion module of group of cutting knife module and spinning module sharing, the manufacturing cost of device has been practiced thrift.

Drawings

In order to make the content of the invention more clearly understood, the invention will now be described in further detail with reference to specific embodiments thereof, in conjunction with the accompanying drawings, in which

FIG. 1 is a schematic structural view of an automatic casing spinning forming device according to a preferred embodiment of the present invention;

FIG. 2 is a schematic structural view of a cutting knife module in the automatic spinning forming apparatus for housing shown in FIG. 1;

FIG. 3 is a schematic structural view of a blanking module in the automatic spinning forming apparatus for housing shown in FIG. 1;

fig. 4 is a schematic structural diagram of a support module in the automatic spin-forming apparatus for housing shown in fig. 1.

The specification reference numbers indicate: 1. a frame; 2. a clamping assembly; 21. a rotation drive source; 22. a driving rotating shaft; 23. a driven rotating shaft; 3. spinning and forming the assembly; 31. a bidirectional movement module; 32. a spinning module; 33. a cutting knife module; 331. a tool holder; 332. a cutter head; 4. a material receiving box; 5. an automatic feeding assembly; 51. a material placing frame; 52. a blanking module; 521. a blanking frame; 522. a discharging groove; 523. smashing a board; 524. a blanking cylinder; 525. a material supporting rod; 53. a support module; 531. an adjusting cylinder; 532. a material bearing seat.

Detailed Description

The present invention is further described with reference to the following drawings and specific embodiments so that those skilled in the art can better understand the present invention and can implement the present invention, but the embodiments are not to be construed as limiting the present invention.

Referring to fig. 1-4, the utility model discloses an automatic spinning forming device of shell, including frame 1, set up centre gripping subassembly 2 and spinning forming subassembly 3 in the frame 1, centre gripping subassembly 2 is used for centre gripping shell raw materials, and spinning forming subassembly 3 includes

The bidirectional movement module 31, the bidirectional movement module 31 is set up on framework 1;

the spinning module 32, the spinning module 32 is arranged on the bidirectional movement module 31, and is used for spinning the shell raw material into a shell with a preset shape;

and a cutter module 33, the cutter module 33 being provided on the bidirectional movement module 31 for cutting the housing spun into a predetermined shape to a predetermined size.

The working principle and the beneficial effects of the technical scheme are as follows: when the device is used, firstly, the shell raw material is fixed on the clamping component 2, the clamping component 2 drives the shell raw material to rotate, the bidirectional movement module 31 drives the spinning module 32 to perform bidirectional movement, the position of the spinning module 32 is adjusted to the shell raw material position, the shell raw material is spun into a preset shape, then the bidirectional movement module 31 drives the cutter module to move to the shell raw material position, the shell which is spun into the preset shape is cut, the thickness of the shell side wall is cut to the preset size, the device can cut the shell which is spun into the preset shape, when the size of the shell side wall needs to be smaller than the thickness of the bottom of the shell, the shell side wall is directly cut to the preset size by using the cutter module 33, the shell does not need to be transferred to a cutting device for cutting the external dimension, the steps of transferring and re-clamping are reduced, the production efficiency is improved, and the cutter module 33 and the spinning module 32 share the same bidirectional movement module 31, the manufacturing cost of the device is saved.

Preferably, the cutting knife module 33 includes a knife holder 331 and a knife head 332, the knife holder 331 is disposed on the bidirectional movement module 31, and the knife head 332 is disposed on the knife holder 331.

The tool post 331 provides support for the tool bit 332, and the tool bit 332 is stably mounted on the bidirectional movement module 31, so that the tool bit 332 is stable in structure when the shell is cut, and the cutting precision is guaranteed.

Preferably, the tool holder 331 is rotatably connected to the two-way movement module 31.

Rotate tool rest 331 and connect on two-way motion module 31, can adjust the position of tool bit 332, prevent spinning module 32 during operation, tool bit 332 and centre gripping subassembly 2 from interfering, and can adjust tool bit 332's cutting angle, have more the practicality.

Wherein, preferably, the material receiving box 4 is arranged on the bidirectional movement module 31.

Through setting up material receiving box 4, can collect to material receiving box 4 after the shell shaping in, convenient unified transportation, and material receiving box 4 can be with the garbage collection that cutting knife module 33 cut, prevent that the waste material from getting into inside the two-way motion module 31, influence the precision of two-way motion module 31, guarantee the cutting precision of cutting knife module 33.

Wherein, preferably, the material receiving box 4 is obliquely arranged on the bidirectional movement module 31.

The material receiving box 4 is obliquely arranged, the shell falls to the material receiving box 4 after being formed, and then slides to one side of the material receiving box 4, so that the shell is convenient to collect.

Wherein, preferably, the clamping assembly 2 comprises

A rotation drive source 21, the rotation drive source 21 being provided on the frame 1;

an active rotating shaft 22, the active rotating shaft 22 being provided at an output end of the rotary drive source 21;

the driven rotating shaft 23, the driven rotating shaft 23 is connected on the frame 1 in a rotating way, and the shell raw material is clamped between the driving rotating shaft 22 and the driven rotating shaft 23.

When the shell raw materials are clamped, the shell raw materials are placed between the driving rotating shaft 22 and the driven rotating shaft 23, the driving rotating shaft 22 and the driven rotating shaft 23 move oppositely to clamp the shell raw materials, the rotary driving source 21 drives the driving rotating shaft 22 to rotate, and the driving rotating shaft 22 drives the shell raw materials to rotate.

Preferably, the driven rotating shaft 23 is rotatably connected to the frame 1 through a bearing.

Rotate driven spindle 23 and connect in frame 1 through setting up the bearing, utilize bearing rotational stability's characteristics, it is more stable when making centre gripping subassembly 2 drive shell raw materials and rotate.

Preferably, the automatic feeding assembly 5 is arranged on the machine frame 1, the automatic feeding assembly 5 comprises a material placing frame 51, and the material placing frame 51 is arranged on the machine frame 1 and used for placing shell raw materials;

the blanking module 52 is arranged on the discharging frame 51 and used for pushing the shell raw material on the discharging frame 51 to the clamping component 2;

and the supporting module 53 is arranged on the bidirectional movement module 31 and used for supporting the shell raw material clamped by the clamping component 2.

Can save a plurality of shell raw materials through setting up blowing frame 51, the during operation, the shell raw materials that unloading module 52 will be on the blowing frame 51 pushes away to centre gripping subassembly 2, can provide the support for the shell raw materials of unloading module 52 propelling movement through setting up support module 53, makes things convenient for centre gripping subassembly 2's centre gripping.

Wherein, preferably, the blanking module 52 comprises

The blanking frame 521, the blanking frame 521 is arranged on the blanking frame 51;

the blanking groove 522 is arranged in the blanking frame 521;

the smashing plate 523, the smashing plate 523 is arranged in the feeding groove 522, and the smashing plate 523 is used for pushing the shell raw material to the supporting module 53;

the blanking cylinder 524 is arranged on the blanking frame 521 and used for pushing the smashing plate 523 to slide in the blanking groove 522;

the material supporting rod 525 is connected to the blanking frame 521 in a rotating mode through a torsion spring and used for supporting the shell raw materials entering the blanking groove 522.

When the blanking module 52 works, the blanking cylinder 524 pushes the smashing plate 523 to move downwards in the blanking groove 522, and the smashing plate 523 pushes the shell raw material to the supporting module 53. Support material pole 525 and be connected with unloading frame 521 through the torsional spring, when pounding board 523 and not promoting the shell raw materials, support material pole 525 and support the shell raw materials under the spring action of torsional spring, prevent that the shell raw materials from falling out down silo 522, when pounding board 523 and promote shell raw materials downstream, support material pole 525 and rotate and no longer block that the shell raw materials fall out down the silo.

Wherein, preferably, the supporting module 53 comprises

The adjusting cylinder 531, the adjusting cylinder 531 is arranged on the bidirectional movement module 31;

the material bearing seat 532 is arranged on the adjusting cylinder 531;

the adjusting cylinder 531 drives the material bearing seat 532 to move up and down, and the vertical distance from the material bearing seat 532 to the clamping assembly 2 is adjusted.

The material bearing seat 532 provides support for the shell raw materials, and the adjusting cylinder 531 drives the material bearing seat 532 to move to adjust the position of the shell raw materials, so that the clamping position of the shell raw materials is accurate, and the shell raw materials with different sizes can be adapted.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications can be made without departing from the scope of the invention.

Claims (10)

1. The utility model provides an automatic spin forming device of shell, includes the frame, set up centre gripping subassembly and spin forming subassembly in the frame, the centre gripping subassembly is used for centre gripping shell raw materials, its characterized in that: the spin forming assembly comprises

The bidirectional movement module is arranged on the rack;

the spinning module is arranged on the bidirectional movement module and is used for spinning the shell raw material into a shell with a preset shape;

and the cutting knife module is arranged on the bidirectional movement module and is used for cutting the shell which is spun into a preset shape to a preset size.

2. The automatic spinning forming device of the shell according to claim 1, characterized in that: the cutting knife module comprises a knife rest and a knife head, the knife rest is arranged on the bidirectional movement module, and the knife head is arranged on the knife rest.

3. The automatic spinning forming device of the shell according to claim 2, characterized in that: the tool rest is rotationally connected to the bidirectional movement module.

4. The automatic spinning forming device for the outer shell according to claim 1, characterized in that: and the bidirectional movement module is provided with a material receiving box.

5. The automatic spinning forming device for the outer shell according to claim 4, characterized in that: the material receiving box is obliquely arranged on the bidirectional movement module.

6. The automatic spinning forming device for the outer shell according to claim 1, characterized in that: the clamping assembly comprises

A rotary drive source provided on the frame;

the driving rotating shaft is arranged at the output end of the rotating driving source;

the driven spindle, the driven spindle rotates to be connected in the frame, the centre gripping of shell raw materials is in the initiative pivot with between the driven spindle.

7. The automatic spinning forming device of the shell according to claim 6, characterized in that: the driven rotating shaft is rotatably connected to the rack through a bearing.

8. The automatic spinning forming device of the shell according to claim 1, characterized in that: set up automatic feeding subassembly in the frame, automatic feeding subassembly includes:

the discharging frame is arranged on the rack and used for placing shell raw materials;

the blanking module is arranged on the material placing frame and used for pushing the shell raw material on the material placing frame to the clamping component;

and the supporting module is arranged on the bidirectional movement module and used for supporting the shell raw material clamped by the clamping assembly.

9. The automatic spinning forming device of the shell according to claim 8, characterized in that: the blanking module comprises

The blanking frame is arranged on the blanking frame;

the blanking groove is arranged in the blanking frame;

the smashing plate is arranged in the blanking groove and used for pushing the shell raw material to the supporting module;

the blanking air cylinder is arranged on the blanking frame and used for pushing the smashing plate to slide in the blanking groove;

the material supporting rod is connected to the blanking frame in a rotating mode through a torsional spring and used for supporting the shell raw materials entering the blanking groove.

10. The automatic spinning forming device of the shell according to claim 8, characterized in that: the supporting module comprises

The adjusting cylinder is arranged on the bidirectional movement module;

the material bearing seat is arranged on the adjusting cylinder;

the adjusting cylinder drives the material bearing seat to move up and down, and the vertical distance between the material bearing seat and the shell raw material clamped by the clamping assembly is adjusted.

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