CN216991031U - All revolving racks of machine tooling - Google Patents

Abstract

The utility model belongs to the technical field of machined part conveying devices, and particularly relates to a machining turnover frame which comprises a bearing component, wherein a first clamping component and a second clamping component are respectively arranged on two sides of the bearing component; the utility model has reasonable design, reasonable structure, simple operation, reliable use and good safety performance, reduces manual operation, improves the working efficiency, has low manufacturing cost, is matched with a travelling crane for use, and is particularly suitable for the turnover of workpieces in a workshop.

Description

All revolving racks of machine tooling

Technical Field

The utility model belongs to the technical field of machined part conveying devices, and particularly relates to a machining turnover frame.

Background

At present, the turnover of the machined parts between a machine tool and a machine tool or between the machine tool and a warehouse is completed through manpower or a trolley, the labor intensity is high, the working efficiency is low, particularly, the transportation of the shaft and pipe machined parts by the trolley is inconvenient, and the machined parts easily slide off the trolley in the transportation process, so that potential safety hazards exist.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a machining turnover frame which is reasonable in structure, simple to operate, good in safety performance and high in working efficiency.

In order to solve the technical problems, the utility model provides the following technical scheme:

the utility model provides a machine tooling turnover frame, includes bearing assembly, its characterized in that: the two sides of the bearing component are respectively provided with a first clamping component and a second clamping component, the top end of the first clamping component is hinged with the top end of the second clamping component, a locking component is arranged on the second clamping component close to the position where the second clamping component is hinged with the first clamping component, and the locking component penetrates through the first clamping component and extends to the outside of the first clamping component.

The following is the further optimization of the technical scheme of the utility model:

the first clamping assembly comprises two first connecting blocks which are arranged in parallel at a certain interval, and a plurality of second connecting blocks are fixedly connected between the two first connecting blocks.

And (4) further optimizing: the bottom rigid coupling of first connecting block has first carrier block, and the top rigid coupling of first connecting block has the third connecting block, and the third connecting block is the contained angle with first connecting block and lays, and the one end rigid coupling that first connecting block was kept away from to the third connecting block has the back shaft.

And (4) further optimizing: the equal rigid coupling in the position department of back shaft near its both ends has the support cover, and the rigid coupling has the fourth connecting block between two third connecting blocks.

And (4) further optimizing: the second clamping component comprises two fifth connecting blocks which are arranged in parallel at a certain interval, and a plurality of sixth connecting blocks are fixedly connected between the two fifth connecting blocks.

And (4) further optimizing: the bottom end of the fifth connecting block is fixedly connected with a second bearing block, the top end of the fifth connecting block is fixedly connected with a seventh connecting block, the seventh connecting block and the fifth connecting block are arranged at an included angle, one end of the seventh connecting block, far away from the fifth connecting block, is fixedly connected with a rotating shaft, and the rotating shaft is rotatably connected with the supporting sleeve.

Further optimization: the fixed connection has the eighth connecting block between two seventh connecting blocks, and the rigid connection has first supporting shoe and second supporting shoe on the side that the eighth connecting block is close to the pivot, and first supporting shoe and second supporting shoe interval certain distance parallel arrangement are established, and the support column is established to first supporting shoe endotheca, and the one end and the second supporting shoe threaded connection of first supporting shoe are kept away from to the support column.

And (4) further optimizing: the locking assembly comprises a rotating sleeve, the rotating sleeve is rotatably connected with the supporting column, a handle is fixedly connected to the rotating sleeve, and one end, far away from the rotating sleeve, of the handle penetrates through a cavity between the supporting shaft and the fourth connecting block and extends to the outside of the first clamping assembly.

Further optimization: the lower surface of the handle is fixedly connected with a locking block, and one end of the handle, which is far away from the rotating sleeve, is fixedly sleeved with a handle sleeve.

Further optimization: the bearing assembly comprises a bearing frame, side frames are fixedly connected to two sides of the bearing frame, the bottom ends of the side frames extend to the lower side of the bearing frame and are fixedly connected with two first ground feet, and an insertion channel is arranged between the two first ground feet.

The utility model has reasonable design, reasonable structure, simple operation, reliable use and good safety performance, reduces manual operation, improves the working efficiency, has low manufacturing cost, is matched with a travelling crane for use, and is particularly suitable for the turnover of workpieces in a workshop.

The utility model is further illustrated with reference to the following figures and examples.

Drawings

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

FIG. 2 is a schematic structural view of the carrier assembly removed according to the embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a first clamping assembly according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a second clamping assembly according to an embodiment of the present invention;

FIG. 5 is a schematic structural view of a locking assembly in an embodiment of the present invention;

fig. 6 is a schematic structural diagram of a carrier assembly according to an embodiment of the utility model.

In the figure: 1-a carrier assembly; 101-a carrier frame; 102-side frame; 103-a first anchor; 2-a first clamping assembly; 201-first connection block; 202-a second connection block; 203-third connecting block; 204-supporting shaft; 205-support sleeve; 206-a first carrier block; 207-fourth connection block; 208-a first stiffener plate; 3-a second clamping assembly; 301-fifth connection block; 302-sixth connection block; 303-seventh connecting block; 304-eighth connection block; 305-a first support block; 306-a second support block; 307-support column; 308-a second carrier block; 309-a rotating shaft; 310-a second stiffener plate; 4-a locking assembly; 401-rotating sleeve; 402-a handle; 403-a locking block; 404-handle cover.

Detailed Description

As shown in fig. 1-6, a machining turnover frame comprises a bearing component 1, wherein a first clamping component 2 and a second clamping component 3 are respectively arranged on two sides of the bearing component 1, the top end of the first clamping component 2 is hinged to the top end of the second clamping component 3, a locking component 4 is arranged on the second clamping component 3 near the position where the second clamping component is hinged to the first clamping component 2, and the locking component 4 penetrates through the first clamping component 2 and extends to the outside.

As shown in fig. 6, the carrying assembly 1 includes a carrying frame 101, side frames 102 are fixedly connected to two sides of the carrying frame 101, bottom ends of the side frames 102 extend to a lateral lower side of the carrying frame 101 and are fixedly connected with two first ground pins 103 symmetrically arranged, and an insertion channel is provided between the two first ground pins 103.

The design is simple and reasonable in structure and reliable in use, and is particularly suitable for loading shaft and pipe workpieces.

The carrier frame 101 and the side frames 102 are each formed by welding a plurality of rectangular pipes.

The first anchor 103 is made of a rectangular tube.

By the design, the bearing assembly 1 is convenient to process and manufacture, the weight of the bearing assembly 1 is reduced, and the rectangular pipes can be purchased from the market, so that the production cost of the tool is reduced.

As shown in fig. 2 and 3, the first clamping assembly 2 includes two first connecting blocks 201 arranged in parallel at a certain distance, and two second connecting blocks 202 are fixedly connected between the two first connecting blocks 201.

The bottom end of the first connecting block 201 is fixedly connected with a first bearing block 206, the top end of the first connecting block 201 is fixedly connected with a third connecting block 203, the third connecting block 203 and the first connecting block 201 are arranged at an included angle, and one end, far away from the first connecting block 201, of the third connecting block 203 is fixedly connected with a supporting shaft 204.

The support shaft 204 is fixedly connected with support sleeves 205 at positions close to the two ends.

A fourth connecting block 207 is fixedly connected between the two third connecting blocks 203.

A first reinforcing plate 208 is fixedly connected to a position of the first connecting block 201 close to the top end thereof, and one end of the first reinforcing plate 208 far away from the first connecting block 201 is fixedly connected with the corresponding third connecting block 203.

The first connecting block 201, the second connecting block 202, the third connecting block 203, the first bearing block 206 and the fourth connecting block 207 are all made of rectangular pipes.

Design like this, both made things convenient for first centre gripping subassembly 2 manufacturing, alleviateed first centre gripping subassembly 2's weight again to the rectangular pipe can be purchased from market, thereby has reduced the manufacturing cost of frock.

As shown in fig. 2 and 4, the second clamping assembly 3 includes two fifth connecting blocks 301 arranged in parallel at a certain distance, and two sixth connecting blocks 302 are fixedly connected between the two fifth connecting blocks 301.

The bottom end of the fifth connecting block 301 is fixedly connected with a second bearing block 308, the top end of the fifth connecting block 301 is fixedly connected with a seventh connecting block 303, the seventh connecting block 303 and the fifth connecting block 301 are arranged at an included angle, one end of the seventh connecting block 303, which is far away from the fifth connecting block 301, is fixedly connected with a rotating shaft 309, and the rotating shaft 309 is rotatably connected with the support sleeve 205.

An eighth connecting block 304 is fixedly connected between the two seventh connecting blocks 303.

The fifth connecting block 301, the sixth connecting block 302, the seventh connecting block 303, the eighth connecting block 304 and the second carrier block 308 are all machined from rectangular tubes.

Design like this, both made things convenient for second centre gripping subassembly 3 manufacturing, alleviateed second centre gripping subassembly 3's weight again to the rectangular pipe can be purchased from market, thereby has reduced the manufacturing cost of frock.

A first supporting block 305 and a second supporting block 306 are fixedly connected to the side of the eighth connecting block 304 close to the rotating shaft 309, and the first supporting block 305 and the second supporting block 306 are arranged in parallel at a certain distance.

A supporting column 307 is sleeved in the first supporting block 305, and one end of the supporting column 307 far away from the first supporting block 305 is in threaded connection with the second supporting block 306.

The first support block 305 is made of a nut, the second support block 306 is a nut, and the support column 307 is a bolt.

Due to the design, the nut and the bolt can be purchased from the market, so that the production cost of the tool is reduced, and the tool is convenient to manufacture and install.

The position of the fifth connecting block 301 close to the top end thereof is fixedly connected with a second reinforcing plate 310, and one end of the second reinforcing plate 310 far away from the fifth connecting block 301 is fixedly connected with the corresponding seventh connecting block 303.

As shown in fig. 2 and 5, the locking assembly 4 includes a rotating sleeve 401, the rotating sleeve 401 is rotatably connected to a supporting column 307, a handle 402 is fixedly connected to the rotating sleeve 401, and an end of the handle 402 away from the rotating sleeve 401 passes through a cavity between the supporting shaft 204 and the fourth connecting block 207 and extends to the outside of the first clamping assembly 2.

A locking block 403 is fixed to the lower surface of the handle 402.

The rotating sleeve 401 and the handle 402 are both made of round tubes, and the locking block 403 is made of rectangular tubes.

The handle sleeve 404 is fixedly sleeved at one end of the handle 402 far away from the rotating sleeve 401.

The handle cover 404 is made of soft material such as plastic and rubber.

When the device is used, the machining turnover frame (without the bearing component 1) is hoisted to the bearing component 1 accessory provided with a machined part through the crane, and the first clamping component 2 and the second clamping component 3 are rotated to enable the first bearing block 206 and the second bearing block 308 to be away from each other.

The trolley drives the first and second gripper assemblies 2, 3 downward, and when the first and second bearing blocks 206, 308 are moved to the horizontally aligned insertion channel position, the handle 402 is pulled to bring the first and second bearing blocks 206, 308 closer together into the insertion channel.

The handle 402 is rotated downwards to drive the locking block 403 to move downwards, so that the locking block 403 is clamped outside the fourth connecting block 207, the first bearing block 206 and the second bearing block 308 are not far away any more, and then the machining turnover frame is moved to move the machined part to the side of a machine tool or in a warehouse.

It will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in the embodiments described above without departing from the principles and spirit of the utility model, the scope of which is defined by the appended claims.

Claims (10)

1. A machine tooling turnover frame, includes carrier assembly (1), its characterized in that: the two sides of the bearing component (1) are respectively provided with a first clamping component (2) and a second clamping component (3), the top end of the first clamping component (2) is hinged to the top end of the second clamping component (3), a locking component (4) is arranged on the second clamping component (3) close to the position where the second clamping component is hinged to the first clamping component (2), and the locking component (4) penetrates through the first clamping component (2) and extends to the outside of the first clamping component (2).

2. A machine processing turret according to claim 1, characterized in that: the first clamping assembly (2) comprises two first connecting blocks (201) which are arranged in parallel at a certain interval, and a plurality of second connecting blocks (202) are fixedly connected between the two first connecting blocks (201).

3. A machine processing turret according to claim 2, characterized in that: the bottom rigid coupling of first connecting block (201) has first carrier block (206), and the top rigid coupling of first connecting block (201) has third connecting block (203), and third connecting block (203) is the contained angle with first connecting block (201) and lays, and the one end rigid coupling that first connecting block (201) was kept away from in third connecting block (203) has back shaft (204).

4. A machine processing turret according to claim 3, characterized in that: the positions of the supporting shaft (204) close to the two ends of the supporting shaft are fixedly connected with supporting sleeves (205), and a fourth connecting block (207) is fixedly connected between the two third connecting blocks (203).

5. A machine turnover frame as claimed in claim 4, wherein: the second clamping assembly (3) comprises two fifth connecting blocks (301) which are arranged in parallel at a certain interval, and a plurality of sixth connecting blocks (302) are fixedly connected between the two fifth connecting blocks (301).

6. A machine processing turnaround according to claim 5, wherein: the bottom end of the fifth connecting block (301) is fixedly connected with a second bearing block (308), the top end of the fifth connecting block (301) is fixedly connected with a seventh connecting block (303), the seventh connecting block (303) and the fifth connecting block (301) are arranged in an included angle, one end, far away from the fifth connecting block (301), of the seventh connecting block (303) is fixedly connected with a rotating shaft (309), and the rotating shaft (309) is rotatably connected with the support sleeve (205).

7. A machine processing turnaround according to claim 6, wherein: two the rigid coupling has eighth connecting block (304) between seventh connecting block (303), the rigid coupling has first supporting block (305) and second supporting block (306) on eighth connecting block (304) is close to the side of pivot (309), first supporting block (305) and second supporting block (306) interval certain distance parallel arrangement, support column (307) are established to first supporting block (305) endotheca, the one end and the second supporting block (306) threaded connection of first supporting block (305) are kept away from to support column (307).

8. A machine turnover frame as claimed in claim 7, wherein: locking Assembly (4) are including rotating cover (401), rotate cover (401) and support column (307) and rotate and be connected, rotate the rigid coupling on cover (401) and have handle (402), and the one end that handle (402) kept away from rotating cover (401) passes the cavity between support shaft (204) and fourth connecting block (207) and extends to the outside of first centre gripping subassembly (2).

9. The machine processing turnaround of claim 8, wherein: the lower surface of the handle (402) is fixedly connected with a locking block (403), and one end of the handle (402), which is far away from the rotating sleeve (401), is fixedly sleeved with a handle sleeve (404).

10. A machine processing turret according to claim 9, characterized in that: the bearing assembly (1) comprises a bearing frame (101), side frames (102) are fixedly connected to two sides of the bearing frame (101), the bottom ends of the side frames (102) extend to the side lower portion of the bearing frame (101) and are fixedly connected with two first ground feet (103), and an insertion channel is arranged between the two first ground feet (103).

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