CN116572036A - Hot extrusion die steel sawing positioning assembly and application method thereof - Google Patents

Abstract

The invention discloses a hot extrusion die hacksaw positioning assembly and a use method thereof, wherein the hot extrusion die hacksaw positioning assembly comprises a distance adjusting mechanism, a first clamping mechanism capable of fixing the top end of a die raw material is arranged at the distance adjusting end of the distance adjusting mechanism, and a second clamping mechanism capable of clamping the periphery side of the die raw material is arranged near the hacksaw end of the distance adjusting mechanism; the first clamping mechanism comprises a movable disc with a cavity inside, the surface of the movable disc is provided with a plurality of first clamping arms which are arranged in a circumferential array and can move relatively or oppositely, and the second clamping mechanism comprises two second clamping arms which are symmetrically arranged and can move relatively or oppositely; the whole device is high in automation degree, the first clamping mechanism and the second clamping mechanism are controlled in real time by means of the pressure sensor, and the equidistant cutting function is realized by means of the distance sensor and the distance adjusting mechanism.

Description

Hot extrusion die steel sawing positioning assembly and application method thereof

Technical Field

The invention relates to a steel sawing and positioning assembly of a hot extrusion die and a use method thereof.

Background

The hot extrusion is a process of forming a section bar or a pipe with a required shape by extruding a die cavity through a plastic metal blank under the action of pressure, so that the strength of the die is required to a certain extent, and if the strength is insufficient, a material is not formed in the extrusion process, and the die is deformed first.

And when producing the mould, the first step is to the raw and other materials cutting, and because the raw and other materials itself has certain intensity, when the cutting, if the cutting precision is poor, then can directly influence subsequent production, and can increase the degree of difficulty for subsequent production, consequently, can adopt anchor clamps to fix it when the cutting, treat to fix the back completely and cut it with the help of the hacksaw, and before the cutting, need the manual work to measure its length, and every time cut all need the repetitive operation, so can not only increase the work load, still can reduce efficiency, therefore, need a kind to be able to accurately fix the mould raw and other materials, and can assist the hacksaw to realize equidistant fixed subassembly of cutting.

Disclosure of Invention

The invention aims to provide a hot extrusion die steel sawing and positioning assembly and a using method thereof, which are used for solving the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: comprising the steps of (a) a step of,

the distance adjusting mechanism is provided with a first clamping mechanism capable of fixing the top end of the die raw material at a distance adjusting end, and a second clamping mechanism capable of clamping the periphery side of the die raw material is arranged close to the hacksaw end;

the first clamping mechanism comprises a movable disc with a cavity inside, the surface of the movable disc is provided with a plurality of first clamping arms which are arranged in a circumferential array and can move relatively or oppositely, and the second clamping mechanism comprises two second clamping arms which are symmetrically arranged and can move relatively or oppositely;

the movable disc is provided with a contact pause mechanism capable of controlling an external feeding device so as to finish the action of pausing the conveying of the die raw materials.

Preferably, the device further comprises a base, the distance adjusting mechanism comprises a screw rod arranged on the base, a first motor is arranged on the side face of the base, the screw rod is arranged at a power output end of the screw rod, the front surface and the rear surface of the base are respectively provided with a support, the two supports are arranged on the periphery side of the movable disc, and the movable disc is arranged on the periphery side of the screw rod.

Preferably, the movable disc surface and the cavity are provided with sliding grooves in a circumferential array, the sliding grooves are provided with sliding blocks in the movable disc cavity, a speed reducer is arranged at the central position in the movable disc cavity, a plurality of movable rods are arranged at the power output end of the speed reducer in a circumferential array, the other ends of the movable rods are arranged on the sliding blocks, the first clamping arms are arranged on the sliding blocks on the movable disc surface, and the sliding blocks are arranged on the first clamping arms.

Preferably, the second clamping mechanism comprises a transmission bin arranged on the base, toothed bars are symmetrically arranged in the cavity of the transmission bin in a central mode, tooth blocks are arranged in the central position of the cavity of the transmission bin, the two toothed bars are meshed with the tooth blocks, and the two second clamping arms are respectively arranged on the two toothed bars.

Preferably, the contact suspension mechanism comprises a protection bin arranged on the movable disc, spring blocks are symmetrically arranged in a cavity of the protection bin, contact extrusion blocks are arranged on the two spring blocks, and a distance sensor is arranged in the middle of the cavity of the protection bin.

Preferably, the side of the movable disc, which is far away from the first clamping arm, is provided with a second motor, and the speed reducer is arranged at the power output end of the second motor.

Preferably, the surface of the transmission bin is provided with a hydraulic rod, and one toothed bar is arranged at the power output end of the hydraulic rod.

Preferably, one of the second clamping arms is provided with a pressure sensor at its clamping end.

Preferably, the clamping ends of the first clamping arm and the second clamping arm are corrugated.

Compared with the prior art, the invention has the beneficial effects that:

1. the method for fixing the raw materials at two positions is adopted integrally, so that the fixing capability is stronger, and the influence on the cutting precision caused by shaking or position deviation is reduced during cutting;

2. the whole device is higher in automation degree, the first clamping mechanism and the second clamping mechanism are controlled in real time by means of the pressure sensor, and the equidistant cutting function is realized by means of the distance sensor and the distance adjusting mechanism, so that the whole device can be widely applied to a large number of fixed assemblies during the production and cutting of the hot extrusion die.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present invention;

FIG. 2 is a schematic side view of an embodiment of the present invention;

FIG. 3 is a schematic view of the internal structure of a protection cabin according to an embodiment of the present invention;

FIG. 4 is a schematic view showing the internal structure of a cavity of a mobile disc according to an embodiment of the present invention;

fig. 5 is a schematic view of the internal structure of the cavity of the transmission bin according to an embodiment of the invention.

In the figure: 1. a base; 201. a moving tray; 202. a first clamping arm; 203. a sliding groove; 204. a slide block; 205. a speed reducer; 206. a movable rod; 301. a second clamping arm; 302. a transmission bin; 303. a toothed bar; 304. tooth blocks; 401. a screw rod; 402. a first motor; 403. a bracket; 501. a protection bin; 502. a spring block; 503. contacting the extrusion block; 504. a distance sensor; 6. a second motor; 7. a hydraulic rod; 8. a pressure sensor.

Detailed Description

In order to solve the problems that the existing fixing is unstable and equidistant cutting cannot be assisted, the invention provides a hot extrusion die steel sawing positioning assembly and a using method thereof. The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the invention thus described is only a part, but not all, of the inventions described. All other inventions obtained by those skilled in the art without making any creative effort based on the inventions in the present invention are within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a hot extrusion die steel sawing and positioning assembly, comprising,

the distance adjusting mechanism is provided with a first clamping mechanism capable of fixing the top end of the die raw material at a distance adjusting end, and a second clamping mechanism capable of clamping the periphery side of the die raw material is arranged close to the hacksaw end;

the first clamping mechanism comprises a movable disc 201 with a cavity inside, a plurality of first clamping arms 202 which are arranged on the surface of the movable disc 201 in a circumferential array and can move relatively or oppositely, and the second clamping mechanism comprises two second clamping arms 301 which are symmetrically arranged and can move relatively or oppositely;

the movable tray 201 is provided with a contact pause mechanism capable of controlling an external feeding device so as to finish the action of pausing the conveying of the die raw material.

Specifically, the distance adjusting mechanism further comprises a base 1, the distance adjusting mechanism comprises a screw rod 401 arranged on the base 1, a first motor 402 is arranged on the side face of the base 1, the screw rod 401 is arranged at the power output end of the screw rod 401, brackets 403 are arranged on the front surface and the rear surface of the base 1, the two brackets 403 are arranged on the outer peripheral side of the movable disc 201, and the movable disc 201 is arranged on the outer peripheral side of the screw rod 401; the movable disc 201 cannot rotate under the limitation of the bracket 403, so that when the screw rod 401 rotates, the movable disc 201 is driven to move under the action of the screw thread, and raw materials with different lengths can be fixed.

Specifically, sliding grooves 203 are formed in the surface of the movable disk 201 and in the cavity in a circumferential array manner, sliding blocks 204 are arranged on the sliding grooves 203 in the cavity of the movable disk 201, a speed reducer 205 is arranged in the center of the cavity of the movable disk 201, a plurality of movable rods 206 are arranged at the power output end of the speed reducer 205 in a circumferential array manner, the other ends of the movable rods 206 are arranged on the sliding blocks 204, the first clamping arms 202 are arranged on the sliding blocks 204 on the surface of the movable disk 201, and the sliding blocks 204 are arranged on the first clamping arms 202; during clamping, the second motor 6 drives the speed reducer 205 to rotate, the speed reducer 205 drives the movable rod 206 on the surface of the speed reducer to rotate, and the movable rod 206 can rotate on the sliding block 204 because the other side of the movable rod 206 is connected to the sliding block 204, so that all the sliding blocks 204 are pulled to move in opposite directions by changing the angle between the movable rod 206 and the sliding block 204, and the first clamping arm 202 on the surface of the sliding block 204 is driven to move in opposite directions to clamp the top end of the raw material.

Specifically, the second clamping mechanism includes a driving bin 302 disposed on the base 1, a toothed bar 303 is disposed in the cavity of the driving bin 302 in a central symmetry manner, a toothed block 304 is disposed in the central position of the cavity of the driving bin 302, two toothed bars 303 are meshed with the toothed block 304, and two second clamping arms 301 are respectively disposed on the two toothed bars 303; the hydraulic rod 7 drives the toothed bars 303 on the surfaces to move, and the meshing action of the toothed blocks 304 drives the other toothed bar 303 to move in opposite directions, so as to drive the second clamping arms 301 on the surfaces of the two toothed bars 303 to move in opposite directions for clamping.

Specifically, the contact suspension mechanism includes a protection cabin 501 disposed on the moving disc 201, spring blocks 502 are symmetrically disposed in a cavity of the protection cabin 501, contact extrusion blocks 503 are disposed on both the spring blocks 502, and a distance sensor 504 is disposed in a middle position of the cavity of the protection cabin 501; when the contact extrusion block 503 is extruded, the contact extrusion block 503 moves to the side of the distance sensor 504 so as to be sensed by the contact extrusion block, and when the contact extrusion block is not extruded, the contact extrusion block 503 is driven to reset under the action of the spring block 502 so as to be separated from the sensing range of the distance sensor 504.

Specifically, the side of the moving disc 201 away from the first clamping arm 202 is provided with a second motor 6, and the speed reducer 205 is arranged at the power output end of the second motor 6; the decelerator 205 is powered by means of the second motor 6.

Specifically, the surface of the transmission bin 302 is provided with a hydraulic rod 7, and one of the toothed bars 303 is arranged at the power output end of the hydraulic rod 7; the toothed bar 303 is powered by means of the hydraulic bar 7.

Specifically, a pressure sensor 8 is disposed at a clamping end of one of the second clamping arms 301; since the moving distance of the first clamping arm 202 and the second clamping arm 301 is the same in the unit time when the first clamping arm 202 and the second clamping arm 301 are designed, the raw material is fixed by the pressure sensor 8 in real time, and the first clamping arm 202 and the second clamping arm 301 are stopped moving after the critical value is reached.

Specifically, the clamping ends of the first clamping arm 202 and the second clamping arm 301 are corrugated; the friction force of the first clamping arm 202 and the second clamping arm 301 is increased, so that the raw material can be better fixed as a whole.

The application method of the hot extrusion die steel sawing positioning assembly comprises the following steps:

step A, an installation device: the second clamping arm 301 is arranged at the cutting position of the hacksaw, the distance sensor 504 is connected with an external feeding device through a control panel, when the distance sensor 504 receives a signal, the external feeding device stops conveying the die raw materials, when the pressure sensor 8 reaches a certain number, the die raw materials cannot deviate during the cutting of the hacksaw, the die raw materials are not deviated, the die raw materials are sequentially critical values, and when the critical values are reached, the first clamping arm 202 and the second clamping arm 301 stop moving;

step B, adjusting: according to the required cutting length, the length of the moving disc 201 from the cutting position of the hacksaw is adjusted, when the length is adjusted, the first motor 402 is started, the first motor 402 drives the screw rod 401 to rotate, and the moving disc 201 is driven to move under the action of the screw thread until the moving disc moves to a preset distance;

step C, fixing: the external feeding device pushes raw materials to move until the external feeding device is in contact with the contact extrusion blocks 503 on the movable disc 201 and extrudes the raw materials, the external feeding device stops pushing the raw materials to move after receiving signals by the distance sensor 504, the second motor 6 and the hydraulic rod 7 are synchronously started, the second motor 6 drives the speed reducer 205 to rotate, the speed reducer 205 drives the movable rod 206 on the surface of the speed reducer to rotate, and the movable rod 206 can rotate on the sliding block 204 because the other side of the movable rod 206 is connected to the sliding block 204, so that all the sliding blocks 204 are pulled to move in opposite directions by changing the angle with the sliding block 204, the first clamping arms 202 on the surface of the sliding block 204 are driven to move in opposite directions to clamp the top ends of the raw materials, the hydraulic rod 7 drives the toothed rods 303 on the surface of the sliding block to move, the other toothed rods 303 are driven to move in opposite directions under the meshing action of the toothed blocks 304, and then the second clamping arms 301 on the surfaces of the two toothed rods 303 are driven to move in opposite directions to clamp until the critical value of the pressure sensor 8 is reached, and then the movement of the first clamping arms 202 and the second clamping arms 301 is stopped;

and D, starting the hacksaw to cut the raw materials, after cutting, reversely starting the second motor 6 and the hydraulic rod 7 to enable the first clamping arm 202 and the second clamping arm 301 to cancel fixing of the cut raw materials, taking out the raw materials, and repeating the operations to realize a large number of equidistant cutting.

The steel sawing and positioning assembly of the hot extrusion die and the use method thereof have the following advantages:

1. the method for fixing the raw materials at two positions is adopted integrally, so that the fixing capability is stronger, and the influence on the cutting precision caused by shaking or position deviation is reduced during cutting;

2. the whole device is high in automation degree, the first clamping mechanism and the second clamping mechanism are controlled in real time by means of the pressure sensor 8, and the equidistant cutting function is realized by means of the distance sensor 504 and the distance adjusting mechanism, so that the whole device can be widely applied to a large number of fixed assemblies during the production and cutting of the hot extrusion die.

Although the present invention has been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents.

Claims (10)

1. The utility model provides a hot extrusion die steel saw cuts locating component which characterized in that: comprising the steps of (a) a step of,

the distance adjusting mechanism is provided with a first clamping mechanism capable of fixing the top end of the die raw material at a distance adjusting end, and a second clamping mechanism capable of clamping the periphery side of the die raw material is arranged close to the hacksaw end;

the first clamping mechanism comprises a movable disc (201) with a cavity inside, a plurality of first clamping arms (202) which are arranged on the surface of the movable disc (201) in a circumferential array and can move relatively or oppositely, and the second clamping mechanism comprises two second clamping arms (301) which are symmetrically arranged and can move relatively or oppositely;

the movable disc (201) is provided with a contact pause mechanism capable of controlling an external feeding device so as to finish the action of pausing the conveying of the die raw materials.

2. The hot extrusion die steel sawing positioning assembly as claimed in claim 1, wherein: still include base (1), distance adjustment mechanism is including setting up lead screw (401) on base (1), base (1) side is provided with first motor (402), lead screw (401) set up in lead screw (401) power take off, both sides all are provided with support (403) around base (1), two support (403) all set up on movable disk (201) periphery side, movable disk (201) set up on lead screw (401) periphery side.

3. The hot extrusion die steel sawing positioning assembly as claimed in claim 1, wherein: the movable disc comprises a movable disc body and is characterized in that sliding grooves (203) are formed in the surface of the movable disc body and in a cavity in a circumferential array mode, sliding blocks (204) are arranged on the sliding grooves (203) in the cavity of the movable disc body, a speed reducer (205) is arranged in the central position of the cavity of the movable disc body, a plurality of movable rods (206) are arranged at the power output end of the speed reducer (205) in a circumferential array mode, the other ends of the movable rods (206) are arranged on the sliding blocks (204), first clamping arms (202) are arranged on the sliding blocks (204) on the surface of the movable disc body, and the sliding blocks (204) are arranged on the first clamping arms (202).

4. A hot extrusion die steel sawing positioning assembly as claimed in claim 2, wherein: the second clamping mechanism comprises a transmission bin (302) arranged on the base (1), toothed bars (303) are symmetrically arranged in the cavity of the transmission bin (302) in a central mode, tooth blocks (304) are arranged in the central position of the cavity of the transmission bin (302), the two toothed bars (303) are meshed with the tooth blocks (304), and the two second clamping arms (301) are arranged on the two toothed bars (303) respectively.

5. The hot extrusion die steel sawing positioning assembly as claimed in claim 1, wherein: the contact suspension mechanism comprises a protection bin (501) arranged on a movable disc (201), spring blocks (502) are symmetrically arranged in the cavity of the protection bin (501), contact extrusion blocks (503) are arranged on the two spring blocks (502), and a distance sensor (504) is arranged in the middle of the cavity of the protection bin (501).

6. A hot extrusion die steel sawing positioning assembly as claimed in claim 2, wherein: the movable disc (201) is provided with a second motor (6) far away from the first clamping arm (202), and a speed reducer (205) is arranged at the power output end of the second motor (6).

7. The hot extrusion die steel sawing positioning assembly as claimed in claim 4, wherein: the surface of the transmission bin (302) is provided with a hydraulic rod (7), and one toothed rod (303) is arranged at the power output end of the hydraulic rod (7).

8. The hot extrusion die steel sawing positioning assembly as claimed in claim 1, wherein: one of the clamping ends of the second clamping arm (301) is provided with a pressure sensor (8).

9. The hot extrusion die steel sawing positioning assembly as claimed in claim 1, wherein: the clamping ends of the first clamping arm (202) and the second clamping arm (301) are corrugated.

10. A method of using a hot extrusion die hacksaw positioning assembly according to any one of claims 1 to 9, characterized in that: the method comprises the following steps:

step (A), an installation device: the second clamping arm (301) is arranged at the cutting position of the hacksaw, the distance sensor (504) is connected with an external feeding device through a control panel, when the distance sensor (504) receives a signal, the external feeding device stops conveying the die raw materials, when the pressure sensor (8) reaches a certain number, the die raw materials cannot deviate when the hacksaw cuts, the die raw materials are sequentially critical values, and when the critical values are reached, the first clamping arm (202) and the second clamping arm (301) stop moving;

step (B), adjusting: according to the required cutting length, the length of the moving disc (201) from the cutting position of the hacksaw is adjusted, when the length is adjusted, a first motor (402) is started, the first motor (402) drives a screw rod (401) to rotate, and the moving disc (201) is driven to move under the action of threads until the moving disc moves to a preset distance;

step (C), fixing: the external feeding device pushes raw materials to move until the external feeding device is in contact with a contact extrusion block (503) on a moving disc (201) and extrudes the raw materials, the external feeding device is stopped to continuously push the raw materials after receiving a signal by a distance sensor (504), a second motor (6) and a hydraulic rod (7) are synchronously started, the second motor (6) drives a speed reducer (205) to rotate, the speed reducer (205) drives a movable rod (206) on the surface of the speed reducer to rotate, the movable rod (206) is connected to a sliding block (204) on the other side, and the movable rod (206) can rotate on the sliding block (204), so that all the sliding blocks (204) are pulled to move in opposite directions through changing the angle with the sliding block (204), a first clamping arm (202) on the surface of the sliding block (204) is driven to move in opposite directions to clamp the top end of the raw materials, a toothed rod (303) on the surface of the hydraulic rod (7) is driven to move, the toothed rod (303) on the other toothed block (304) is driven to move in opposite directions under the meshing action of the toothed block (304), and then a second clamping arm (301) on the surface of the two toothed rods is driven to move in opposite directions until a first clamping arm (301) and a critical value of the second clamping arm (301) is stopped;

and (D) starting the hacksaw to cut the raw materials, after cutting is finished, reversely starting the second motor (6) and the hydraulic rod (7) to enable the first clamping arm (202) and the second clamping arm (301) to cancel fixing the cut raw materials, taking out the raw materials, and repeating the operations to realize mass equidistant cutting.