CN215887131U

CN215887131U - Vacuum annealing device for titanium alloy parts

Info

Publication number: CN215887131U
Application number: CN202122254537.9U
Authority: CN
Inventors: 翟广伟
Original assignee: Gaobeidian Yiyou Industry Co ltd
Current assignee: Gaobeidian Yiyou Industry Co ltd
Priority date: 2021-09-17
Filing date: 2021-09-17
Publication date: 2022-02-22
Anticipated expiration: 2031-09-17

Abstract

The utility model discloses a vacuum annealing device for titanium alloy parts, which comprises a furnace body and a base, wherein the base is installed at the center of the bottom of the furnace body through a bolt and is horizontally arranged, a hollow disc is rotated at the center of the bottom in the furnace body and is horizontally arranged, a first gear is rotated inside the base and is horizontally arranged, a rotating rod is fixed at the center of the top of the first gear and is vertically arranged, the top end of the rotating rod penetrates through the connecting surface of the furnace body and the base and is fixed at the center of the bottom of the hollow disc, a rotating mechanism used for rotating the first gear is arranged inside the base, clamping plates are respectively slid at two ends of the top of the hollow disc and are horizontally arranged, a first sliding plate and a second sliding plate are respectively slid at two ends inside the hollow disc, and a synchronous moving mechanism used for synchronously moving the first sliding plate and the second sliding plate is arranged inside the hollow disc. The utility model avoids the situation of shaking when the vacuum annealing device is used, thereby improving the stability of the device.

Description

Vacuum annealing device for titanium alloy parts

Technical Field

The utility model relates to the technical field of titanium alloy part processing, in particular to a vacuum annealing device for a titanium alloy part.

Background

Titanium alloy refers to a variety of alloy metals made from titanium and other metals. Titanium is an important structural metal developed in the 50 s of the 20 th century, titanium alloy has high strength, good corrosion resistance and high heat resistance, and a vacuum annealing device is required to be used in the processing of titanium alloy parts.

The conventional vacuum annealing device for the titanium alloy parts does not have the function of rotating the titanium alloy parts, so that the vacuum annealing device is unevenly heated, and the processing quality of the titanium alloy parts is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects in the prior art and provides a vacuum annealing device for titanium alloy parts.

In order to achieve the purpose, the utility model adopts the following technical scheme:

the utility model provides a titanium alloy part vacuum annealing device, includes furnace body and base, the base passes through the bolt and installs in furnace body bottom center department and level setting, and bottom center department rotates in the furnace body has hollow dish and level setting, the inside rotation of base has first gear and level setting, and first gear top center department is fixed with bull stick and vertical setting, the bull stick top is passed furnace body and base connection face and is fixed in hollow dish bottom center department, and the inside slewing mechanism who is used for rotating first gear that is equipped with of base, hollow dish top both ends all slide and have splint and the setting of levelling, and the inside both ends of hollow dish slide respectively has first slide and second slide, the inside synchronous motion mechanism who is used for first slide of synchronous motion and second slide that is equipped with of hollow dish.

As a further scheme of the utility model, the top of the hollow disc is provided with a strip-shaped notch and is horizontally arranged, the tops of the first sliding plate and the second sliding plate are respectively fixed with a convex column, and the tops of the two convex columns respectively penetrate through the strip-shaped notch and are respectively fixed at the centers of the bottoms of the two clamping plates.

As a further aspect of the present invention, the synchronous moving mechanism includes a belt and a driving motor, the belt is rotated inside the hollow disc and horizontally disposed, the upper lateral edge of the belt passes through the first sliding plate and slides inside the first sliding plate, the lower lateral edge of the belt passes through the first sliding plate and is adhered inside the first sliding plate, the upper lateral edge of the belt passes through the second sliding plate and is adhered inside the second sliding plate, and the lower lateral edge of the belt passes through the second sliding plate and slides inside the second sliding plate.

As a further scheme of the utility model, the driving motor is horizontally arranged at the bottom in the hollow disc, pulleys are arranged at two ends in the belt, and an output shaft of the driving motor is arranged at the center of one side of one pulley.

As a further scheme of the utility model, one side of the furnace body is open and is hinged with a furnace door, the other side of the furnace body is provided with an operation panel, and four ends of a symmetrical side surface at the bottom of the furnace body are all fixed with supporting legs.

As a further scheme of the utility model, the rotating mechanism comprises a positive and negative motor, the positive and negative motor is vertically arranged on one side in the base, and a second gear is arranged at the top of an output shaft of the positive and negative motor and is meshed with the first gear.

As a further scheme of the utility model, the rotating mechanism comprises a telescopic rod, the telescopic rod is horizontally arranged on one side in the base, and the top end of an output shaft of the telescopic rod is provided with a rack which is meshed with the first gear.

The utility model has the beneficial effects that:

1. according to the utility model, when the titanium alloy part needs to be processed, the titanium alloy part is firstly placed at the top of the hollow disc, one of the pulleys is driven to rotate by the driving motor, one of the pulleys can drive the belt to rotate, the belt can drive the first sliding plate and the second sliding plate to synchronously move, the first sliding plate and the second sliding plate can drive the two convex columns to synchronously move, the two convex columns can drive the two clamping plates to synchronously move, the two clamping plates can clamp and fix the titanium alloy part by synchronously moving, the situation of shaking when the vacuum annealing device is used is avoided, and the use stability of the device is further improved.

2. According to the utility model, after the titanium alloy part is fixed, the furnace door is closed, the positive and negative motors drive the second gear to rotate, the second gear rotates to drive the first gear to rotate, the first gear rotates to drive the rotating rod to rotate, the rotating rod rotates to drive the hollow disc to rotate, and the hollow disc rotates to drive the titanium alloy part to rotate, so that the titanium alloy part can be uniformly heated, the condition that the titanium alloy part is not uniformly heated by the conventional vacuum annealing device is avoided, and the quality of processing the titanium alloy part is improved.

3. According to the utility model, after the titanium alloy part is fixed, the furnace door is closed, the rack is driven to move through the telescopic rod, the rack can drive the first gear to rotate through movement, the rotating rod can be driven to rotate through rotation of the first gear, the hollow disc can be driven to rotate through rotation of the rotating rod, the titanium alloy part can be driven to rotate through rotation of the hollow disc, so that the titanium alloy part can be uniformly heated, the condition that the titanium alloy part is not uniformly heated by the conventional vacuum annealing device is avoided, and the quality of processing the titanium alloy part is improved.

Drawings

FIG. 1 is a schematic structural view of a vacuum annealing apparatus for titanium alloy parts according to example 1 of the present invention;

FIG. 2 is a schematic structural view of a hollow disc of a vacuum annealing apparatus for titanium alloy parts according to example 1 of the present invention;

FIG. 3 is a sectional view of a base of a vacuum annealing apparatus for a titanium alloy part according to embodiment 1 of the present invention;

FIG. 4 is a schematic structural view of a vacuum annealing apparatus for titanium alloy parts according to embodiment 2 of the present invention.

In the figure: 1. a furnace body; 2. a base; 3. a hollow disc; 4. a furnace door; 5. a strip-shaped notch; 6. a splint; 7. a belt; 8. a first slide plate; 9. a second slide plate; 10. a convex column; 11. a pulley; 12. a drive motor; 13. a rotating rod; 14. a first gear; 15. a second gear; 16. a positive and negative motor; 17. a rack; 18. a telescopic rod.

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.

Example 1

Referring to fig. 1-3, a vacuum annealing device for titanium alloy parts comprises a furnace body 1 and a base 2, wherein the base 2 is installed at the center of the bottom of the furnace body 1 through a bolt and horizontally arranged, a hollow disc 3 is rotated at the center of the bottom in the furnace body 1 and is horizontally arranged, a first gear 14 is rotated inside the base 2 and is horizontally arranged, and the top center of the first gear 14 is fixed with a rotating rod 13 and is vertically arranged, the top end of the rotating rod 13 passes through the connecting surface of the furnace body 1 and the base 2 and is fixed at the bottom center of the hollow disc 3, and a rotating mechanism for rotating the first gear 14 is arranged inside the base 2, the clamping plates 6 are arranged at both ends of the top of the hollow disc 3 in a sliding manner and are arranged horizontally, and a first sliding plate 8 and a second sliding plate 9 are respectively arranged at two ends inside the hollow disc 3 in a sliding manner, and a synchronous moving mechanism for synchronously moving the first sliding plate 8 and the second sliding plate 9 is arranged inside the hollow disc 3.

Further, bar notch 5 and level setting have been seted up at 3 tops of hollow dish, and first slide 8 and second slide 9 tops all are fixed with projection 10, and two projection 10 tops all pass bar notch 5 and are fixed in two splint 6 bottom center departments respectively.

Further, the synchronous moving mechanism comprises a belt 7 and a driving motor 12, the belt 7 rotates inside the hollow disc 3 and is horizontally arranged, the upper transverse edge of the belt 7 penetrates through the first sliding plate 8 and slides inside the first sliding plate 8, the lower transverse edge of the belt 7 penetrates through the first sliding plate 8 and is bonded inside the first sliding plate 8, the upper transverse edge of the belt 7 penetrates through the second sliding plate 9 and is bonded inside the second sliding plate 9, and the lower transverse edge of the belt 7 penetrates through the second sliding plate 9 and slides inside the second sliding plate 9.

Further, a driving motor 12 is horizontally arranged at the bottom in the hollow disc 3, pulleys 11 are arranged at two ends in the belt 7, and an output shaft of the driving motor 12 is arranged at the center of one side of one pulley 11.

Furthermore, one side of the furnace body 1 is open and is hinged with a furnace door 4, the other side of the furnace body 1 is provided with an operation panel, and four ends of a symmetrical side surface at the bottom of the furnace body 1 are all fixed with supporting legs.

Further, the rotating mechanism comprises a positive and negative motor 16, the positive and negative motor 16 is vertically installed on one side inside the base 2, and a second gear 15 is installed on the top of an output shaft of the positive and negative motor 16 and meshed with the first gear 14.

The working principle of the embodiment is as follows: when in actual use, when a titanium alloy part needs to be processed, the titanium alloy part is firstly placed at the top of the hollow disc 3, one of the pulleys 11 is driven to rotate by the driving motor 12, one of the pulleys 11 rotates to drive the belt 7 to rotate, the belt 7 rotates to drive the first sliding plate 8 and the second sliding plate 9 to synchronously move, the first sliding plate 8 and the second sliding plate 9 synchronously move to drive the two convex columns 10 to synchronously move, the two convex columns 10 synchronously move to drive the two clamping plates 6 to synchronously move, the two clamping plates 6 synchronously move to clamp and fix the titanium alloy part, the situation of shaking when the vacuum annealing device is used is avoided, the use stability of the device is further improved, after the titanium alloy part is fixed, the furnace door 4 is closed, the positive and negative motor 16 drives the second gear 15 to rotate, the second gear 15 rotates to drive the first gear 14 to rotate, first gear 14 rotates and can drive bull stick 13 and rotate, and bull stick 13 rotates and can drive hollow dish 3 and rotate, and hollow dish 3 rotates and can drive the titanium alloy part and rotate to can make this titanium alloy part carry out even heating, avoid present vacuum annealing device to the inhomogeneous condition emergence of titanium alloy part heating, and then improved the quality to titanium alloy parts machining.

Example 2

Referring to fig. 4, a titanium alloy part vacuum annealing device, including furnace body 1 and base 2, base 2 passes through the bolt and installs in 1 bottom center department of furnace body and level setting, and bottom center department rotates hollow disc 3 and level setting in furnace body 1, the inside rotation of base 2 has first gear 14 and level setting, and 14 top center departments of first gear are fixed with bull stick 13 and vertical setting, 13 tops of bull stick

pass furnace body

1 and 2 connection face of base and be fixed in 3 bottom center departments of hollow disc, and the inside slewing mechanism who is used for rotating first gear 14 that is equipped with of

base

2, 3 top both ends of hollow disc all slide and have splint 6 and equal level setting, and 3 inside both ends of hollow disc slide respectively and have first slide 8 and second slide 9, the inside synchronous motion mechanism who is used for first slide 8 of synchronous motion and second slide 9 that is equipped with of hollow disc 3.

Further, the rotating mechanism comprises an expansion link 18, the expansion link 18 is horizontally arranged on one side inside the base 2, and a rack 17 is arranged at the top end of an output shaft of the expansion link 18 and is meshed with the first gear 14.

The working principle of the embodiment is as follows: when in actual use, after fixing the titanium alloy part, close furnace gate 4 and drive rack 17 through telescopic link 18 and remove, rack 17 removes and can drive first gear 14 and rotate, first gear 14 rotates and can drive bull stick 13 and rotate, bull stick 13 rotates and can drive hollow disc 3 and rotate, hollow disc 3 rotates and can drive the titanium alloy part and rotate, thereby can make this titanium alloy part carry out even heating, avoided present vacuum annealing device to take place to the inhomogeneous condition of titanium alloy part heating, and then improved the quality to titanium alloy parts machining.

Having shown and described the basic principles and essential features of the utility model and its advantages, it will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof, and it is therefore intended that the embodiments be considered as illustrative and not restrictive in all respects, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein, any reference signs in the claims being therefore intended to be embraced therein.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. A vacuum annealing device for titanium alloy parts comprises a furnace body (1) and a base (2), and is characterized in that the base (2) is installed at the center of the bottom of the furnace body (1) through bolts and is horizontally arranged, a hollow disc (3) is rotated at the center of the bottom in the furnace body (1) and is horizontally arranged, a first gear (14) is rotated inside the base (2) and is horizontally arranged, a rotating rod (13) is fixed at the center of the top of the first gear (14) and is vertically arranged, the top end of the rotating rod (13) penetrates through the connecting surface of the furnace body (1) and the base (2) and is fixed at the center of the bottom of the hollow disc (3), a rotating mechanism for rotating the first gear (14) is arranged inside the base (2), clamping plates (6) are respectively slid at the two ends of the top of the hollow disc (3) and are respectively horizontally arranged, and a first sliding plate (8) and a second sliding plate (9) are respectively slid at the two ends of the inside of the hollow disc (3), the hollow disc (3) is internally provided with a synchronous moving mechanism for synchronously moving the first sliding plate (8) and the second sliding plate (9).

2. The vacuum annealing device for the titanium alloy parts according to claim 1, wherein the top of the hollow disc (3) is provided with a strip-shaped notch (5) and is horizontally arranged, the tops of the first sliding plate (8) and the second sliding plate (9) are respectively fixed with a convex column (10), and the tops of the two convex columns (10) respectively penetrate through the strip-shaped notch (5) and are respectively fixed at the centers of the bottoms of the two clamping plates (6).

3. The vacuum annealing device for titanium alloy parts according to claim 2, wherein said synchronous moving mechanism comprises a belt (7) and a driving motor (12), and the belt (7) rotates inside the hollow disc (3) and is horizontally arranged, the upper lateral edge of the belt (7) passes through the first sliding plate (8) and slides inside the first sliding plate (8), the lower lateral edge of the belt (7) passes through the first sliding plate (8) and is adhered inside the first sliding plate (8), the upper lateral edge of the belt (7) passes through the second sliding plate (9) and is adhered inside the second sliding plate (9), and the lower lateral edge of the belt (7) passes through the second sliding plate (9) and slides inside the second sliding plate (9).

4. The vacuum annealing device for titanium alloy parts according to claim 3, wherein said driving motor (12) is horizontally installed at the bottom inside the hollow disc (3), pulleys (11) are installed at both ends inside the belt (7), and the output shaft of said driving motor (12) is installed at the center of one side of one of the pulleys (11).

5. The vacuum annealing device for the titanium alloy parts according to claim 4, wherein one side of the furnace body (1) is open and hinged with a furnace door (4), the other side of the furnace body (1) is provided with an operating panel, and four ends of a symmetrical side surface at the bottom of the furnace body (1) are respectively fixed with a support leg.

6. The vacuum annealing device for the titanium alloy parts according to claim 5, wherein the rotating mechanism comprises a forward and reverse motor (16), the forward and reverse motor (16) is vertically installed on one side inside the base (2), and a second gear (15) is installed on the top of an output shaft of the forward and reverse motor (16) and is meshed with the first gear (14).

7. The vacuum annealing device for the titanium alloy parts according to claim 5, wherein the rotating mechanism comprises a telescopic rod (18), the telescopic rod (18) is horizontally arranged on one side inside the base (2), and the top end of the output shaft of the telescopic rod (18) is provided with a rack (17) and is meshed with the first gear (14).