CN216226762U - Titanium ingot processing equipment with turn-over function - Google Patents

Abstract

The utility model discloses titanium ingot processing equipment with a turnover function, which relates to the field of titanium ingot processing and comprises a processing equipment body, wherein two supports are symmetrically and fixedly arranged on the processing equipment body, connecting holes are formed in the two supports, connecting rotating blocks are rotatably arranged in the two connecting holes, telescopic sleeves are fixedly arranged on the sides, close to each other, of the two connecting rotating blocks, telescopic sliding shafts are sleeved in the telescopic sleeves in a sliding mode, pressing plates are fixedly arranged on the sides, far away from the telescopic sleeves, of the telescopic sliding shafts, and two connecting sliding shafts are symmetrically and slidably sleeved on the connecting rotating blocks. The connecting rotating block and the connecting sliding shaft are arranged in the structure, the connecting rotating block is rotated to drive the connecting sliding shaft and the supporting pressing block to act on the titanium ingot, the titanium ingot is driven to turn over on the processing equipment body, turning over of the titanium ingot is completed, operation danger of operators is reduced, and operation safety of the processing equipment body is improved.

Description

Titanium ingot processing equipment with turn-over function

Technical Field

The utility model relates to the technical field of titanium ingot processing, in particular to titanium ingot processing equipment with a turnover function.

Background

Titanium and titanium alloy ingots can be referred to as titanium ingots for short, titanium sponge is used as a raw material for producing the titanium ingots, and the titanium ingots are subjected to high-temperature smelting to obtain compact titanium ingots, so that the titanium ingots can be further processed into titanium materials by forging and pressing, and only when the titanium sponge is made into compact malleable metals, the titanium ingots can be mechanically processed and can be widely applied to various industrial departments.

The existing titanium ingot needs manual turnover in the machining process, so that operators are involved by equipment with a high probability in the turnover process, and the danger is high, and therefore the titanium ingot machining equipment with the turnover function is needed to meet the requirements of people.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide titanium ingot processing equipment with a turnover function, and solve the problem that operators are very dangerous because of being involved in the equipment with high probability during turnover in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: a titanium ingot processing device with a turnover function comprises a processing device body, wherein two brackets are symmetrically and fixedly installed on the processing device body, connecting holes are formed in the two brackets, connecting rotating blocks are installed in the two connecting holes in a rotating mode, telescopic sleeves are fixedly installed on the sides, close to each other, of the two connecting rotating blocks, telescopic sliding shafts are sleeved in the telescopic sleeves in a sliding mode, pressing plates are fixedly installed on the sides, far away from the telescopic sleeves, of the telescopic sliding shafts, two connecting sliding shafts are sleeved on the connecting rotating blocks in a sliding mode symmetrically, supporting pressing blocks are fixedly installed on the two connecting sliding shafts, an operator places a titanium ingot on the processing device body, then pulls the pressing plates to drive the telescopic sliding shafts to retract and compress telescopic springs, places the titanium ingot between the two pressing plates, then pushes the telescopic sliding shafts to slide and drives the pressing plates to act on the titanium ingot under the action of the telescopic springs, and fixing the titanium ingot.

Preferably, one side fixed mounting that telescopic tube was kept away from to the connection commentaries on classics piece has the threaded rod, and the threaded rod is threaded mounting has the bolt, rotates the bolt, makes it rotate the slip on the threaded rod, and then drives the interlock slide and slide, and the interlock slide drives and connects the slide axle and support the briquetting and act on the titanium ingot for support briquetting sticiss the titanium ingot.

Preferably, the threaded rod is sleeved with a linkage sliding plate in a sliding mode, the two connecting sliding shafts are fixedly mounted on the linkage sliding plate, the bolt is rotated to enable the connecting sliding shafts to rotate and slide on the threaded rod, the linkage sliding plate is driven to slide, the linkage sliding plate drives the connecting sliding shafts and the supporting pressing block to act on the titanium ingot, and the supporting pressing block is enabled to tightly press the titanium ingot.

Preferably, the threaded rod is sleeved with a return spring in a sliding mode, one end of the return spring is in contact with the connecting rotating block, the other end of the return spring is in contact with the linkage sliding plate, and the return spring is used for driving the linkage sliding plate to reset in a sliding mode.

Preferably, the inner wall of the connecting hole is provided with an annular clamping groove, an annular clamping block is rotatably mounted in the annular clamping groove, the annular clamping block is fixedly mounted on the connecting rotating block, the annular clamping groove and the annular clamping block interact to prevent the connecting rotating block from falling out of the connecting hole, and the mounting stability of the connecting rotating block is ensured.

Preferably, two distance limiting slide holes are symmetrically formed in the inner wall of the telescopic sleeve, distance limiting slide blocks are arranged in the two distance limiting slide holes in a sliding mode, the two distance limiting slide blocks are fixedly arranged on the telescopic slide shaft, and the distance limiting slide holes and the distance limiting slide blocks interact to ensure the connection stability between the telescopic sleeve and the telescopic slide shaft.

Preferably, the telescopic sleeve is sleeved with a telescopic spring in a sliding manner, one end of the telescopic spring is in contact with the telescopic sliding shaft, the other end of the telescopic spring is in contact with the connecting rotating block, and under the action of the telescopic spring, the telescopic sliding shaft is pushed to slide and drive the pressing plate to act on the titanium ingot so as to fix the titanium ingot.

The utility model has the beneficial effects that:

according to the utility model, through the arrangement of the connecting rotating block, the connecting sliding shaft and the supporting pressing block, the connecting rotating block is rotated to drive the connecting sliding shaft and the supporting pressing block to act on the titanium ingot, so that the titanium ingot is driven to turn over on the processing equipment body, the turning over of the titanium ingot is completed, the operation danger of operators is reduced, and the operation safety of the processing equipment body is improved.

According to the utility model, through the arrangement of the structures such as the telescopic sliding shaft and the pressing plates, the two pressing plates act on the titanium ingot, the placement stability of the titanium ingot in the processing process is ensured, the titanium ingot is prevented from moving due to the shaking of equipment in the processing process, and the function of ensuring the processing stability of the titanium ingot is achieved.

Drawings

FIG. 1 is a schematic structural diagram of a titanium ingot processing apparatus with a turnover function according to the present invention;

FIG. 2 is a schematic view of a connection structure of a connection slide shaft and other structures in titanium ingot processing equipment with a turnover function according to the present invention;

FIG. 3 is a schematic cross-sectional structural view of a connecting slide shaft and other structures in a titanium ingot processing device with a turnover function according to the present invention;

fig. 4 is a schematic sectional structural view of structures such as a distance-limiting slider in titanium ingot processing equipment with a turnover function according to the present invention.

In the figure: 1. processing the equipment body; 2. a support; 3. connecting holes; 4. connecting the rotary block; 5. a telescopic sleeve; 6. a telescopic sliding shaft; 7. pressing a plate; 8. a distance limiting slide hole; 9. a distance limiting slide block; 10. a tension spring; 11. an annular neck; 12. an annular fixture block; 13. a threaded rod; 14. a bolt; 15. linking a sliding plate; 16. connecting a sliding shaft; 17. supporting the pressing block; 18. a return spring; 19. (ii) a 20. In that respect

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-4, a titanium ingot processing device with a turnover function comprises a processing device body 1, two brackets 2 are symmetrically and fixedly installed on the processing device body 1, connecting holes 3 are respectively formed on the two brackets 2, connecting rotating blocks 4 are respectively and rotatably installed in the two connecting holes 3, telescopic sleeves 5 are respectively and fixedly installed on the sides, close to each other, of the two connecting rotating blocks 4, telescopic sliding shafts 6 are slidably sleeved in the telescopic sleeves 5, pressing plates 7 are fixedly installed on the sides, far away from the telescopic sleeves 5, of the telescopic sliding shafts 6, two connecting sliding shafts 16 are symmetrically and slidably sleeved on the connecting rotating blocks 4, supporting pressing blocks 17 are respectively and fixedly installed on the two connecting sliding shafts 16, an operator places a titanium ingot on the processing device body 1, then pulls the pressing plates 7 to drive the telescopic sliding shafts 6 to retract and compress the telescopic springs 10, and places the titanium ingot between the two pressing plates 7, then under the action of the telescopic spring 10, the telescopic sliding shaft 6 is pushed to slide and drive the pressing plate 7 to act on the titanium ingot, so that the titanium ingot is fixed.

Referring to fig. 2-4, a threaded rod 13 is fixedly mounted on one side of the connecting rotating block 4, which is far away from the telescopic sleeve 5, a bolt 14 is mounted on the threaded rod 13 in a threaded manner, the bolt 14 is rotated to enable the connecting rotating block to rotate and slide on the threaded rod 13, and then the linkage sliding plate 15 is driven to slide, the linkage sliding plate 15 drives the connecting sliding shaft 16 and the supporting pressing block 17 to act on a titanium ingot, so that the supporting pressing block 17 tightly presses the titanium ingot.

Referring to fig. 3-4, a linkage sliding plate 15 is slidably sleeved on a threaded rod 13, two connecting sliding shafts 16 are fixedly mounted on the linkage sliding plate 15, a bolt 14 is rotated to enable the connecting sliding shafts to rotate and slide on the threaded rod 13, the linkage sliding plate 15 is driven to slide, the linkage sliding plate 15 drives the connecting sliding shafts 16 and a supporting pressing block 17 to act on a titanium ingot, and the supporting pressing block 17 tightly presses the titanium ingot.

Referring to fig. 2-4, the threaded rod 13 is slidably sleeved with a return spring 18, one end of the return spring 18 is in contact with the connecting rotating block 4, the other end of the return spring 18 is in contact with the interlocking slide plate 15, and the return spring 18 is used for driving the interlocking slide plate 15 to slidably return.

Referring to fig. 3, the inner wall of the connecting hole 3 is provided with an annular clamping groove 11, an annular clamping block 12 is rotatably mounted in the annular clamping groove 11, the annular clamping block 12 is fixedly mounted on the connecting rotating block 4, the annular clamping groove 11 and the annular clamping block 12 interact with each other to prevent the connecting rotating block 4 from falling out of the connecting hole 3, and the mounting stability of the connecting rotating block 4 is ensured.

Referring to fig. 2-4, two distance limiting slide holes 8 are symmetrically formed in the inner wall of the telescopic sleeve 5, distance limiting slide blocks 9 are slidably mounted in the two distance limiting slide holes 8, the two distance limiting slide blocks 9 are fixedly mounted on the telescopic slide shaft 6, and the distance limiting slide holes 8 and the distance limiting slide blocks 9 interact with each other to ensure the connection stability between the telescopic sleeve 5 and the telescopic slide shaft 6.

Referring to fig. 3-4, an extension spring 10 is slidably sleeved in an extension sleeve 5, one end of the extension spring 10 is in contact with an extension sliding shaft 6, the other end of the extension spring 10 is in contact with a connecting rotating block 4, and under the action of the extension spring 10, the extension sliding shaft 6 is pushed to slide and a pressing plate 7 is driven to act on a titanium ingot so as to fix the titanium ingot.

The working principle of the utility model is as follows:

an operator places a titanium ingot on the processing equipment body 1, then pulls the pressure plates 7 to drive the telescopic sliding shafts 6 to retract and compress the telescopic springs 10, places the titanium ingot between the two pressure plates 7, then under the action of the telescopic springs 10, the telescopic sliding shafts 6 are pushed to slide and the pressure plates 7 are driven to act on the titanium ingot, so as to fix the titanium ingot, when the titanium ingot needs to be turned over in the processing process, the bolts 14 are rotated to enable the titanium ingot to rotate and slide on the threaded rods 13, further the linkage sliding plates 15 are driven to slide, the linkage sliding plates 15 drive the connection sliding shafts 16 and the support pressing blocks 17 to act on the titanium ingot, so that the support pressing blocks 17 tightly press the titanium ingot, then the connection rotating blocks 4 are rotated in the connecting holes 3, further the connection sliding shafts 16 and the support pressing blocks 17 are driven to rotate, further the titanium ingot is driven to turn over, so as to complete the turning over of the titanium ingot, wherein the annular clamping grooves 11 and the annular clamping blocks 12 interact to prevent the connection rotating blocks 4 from falling out from the connecting holes 3, the installation stability of the connecting rotating block 4 is ensured, the return spring 18 is used for driving the linkage sliding plate 15 to slide and reset, and the interaction of the distance limiting slide hole 8 and the distance limiting slide block 9 ensures the connection stability between the telescopic sleeve 5 and the telescopic slide shaft 6.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (7)

1. The utility model provides a titanium ingot processing equipment with turn-over function, includes processing equipment body (1), its characterized in that: processing equipment body (1) is gone up symmetry fixed mounting and is had two supports (2), has all seted up connecting hole (3) on two supports (2), all rotates in two connecting holes (3) and installs and connect commentaries on classics piece (4), and two connect the equal fixed mounting in one side that commentaries on classics piece (4) are close to each other and have telescopic tube (5), slip in telescopic tube (5) and cup jointed flexible sliding shaft (6), one side fixed mounting that telescopic tube (5) were kept away from in flexible sliding shaft (6) has clamp plate (7), connect and slide on changeing piece (4) symmetry and cup jointed two and connect sliding shaft (16), equal fixed mounting has support briquetting (17) on two connection sliding shaft (16).

2. The titanium ingot processing equipment with the turnover function as claimed in claim 1, wherein: one side of the connecting rotating block (4) far away from the telescopic sleeve (5) is fixedly provided with a threaded rod (13), and the threaded rod (13) is provided with a bolt (14) in a threaded manner.

3. The titanium ingot processing equipment with the turnover function as claimed in claim 2, wherein: threaded rod (13) go up sliding sleeve and have connect interlock slide (15), two connect sliding shaft (16) all fixed mounting on interlock slide (15).

4. The titanium ingot processing equipment with the turnover function as claimed in claim 2, wherein: the threaded rod (13) is sleeved with a return spring (18) in a sliding mode, one end of the return spring (18) is in contact with the connecting rotating block (4), and the other end of the return spring (18) is in contact with the linkage sliding plate (15).

5. The titanium ingot processing equipment with the turnover function as claimed in claim 1, wherein: the inner wall of the connecting hole (3) is provided with an annular clamping groove (11), an annular clamping block (12) is rotatably mounted in the annular clamping groove (11), and the annular clamping block (12) is fixedly mounted on the connecting rotating block (4).

6. The titanium ingot processing equipment with the turnover function as claimed in claim 1, wherein: two distance limiting slide holes (8) are symmetrically formed in the inner wall of the telescopic sleeve (5), distance limiting slide blocks (9) are arranged in the two distance limiting slide holes (8) in a sliding mode, and the two distance limiting slide blocks (9) are fixedly arranged on the telescopic slide shaft (6).

7. The titanium ingot processing equipment with the turnover function as claimed in claim 1, wherein: the telescopic sleeve (5) is sleeved with a telescopic spring (10) in a sliding mode, one end of the telescopic spring (10) is in contact with the telescopic sliding shaft (6), and the other end of the telescopic spring (10) is in contact with the connecting rotating block (4).

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