CN220468066U - Material frame for annealing titanium alloy vacuum furnace - Google Patents

Abstract

The utility model discloses a material rack for annealing of a titanium alloy vacuum furnace, and belongs to the technical field of titanium alloy production. The utility model provides a titanium alloy vacuum furnace annealing material frame, includes the work or material rest body, still includes: the placing plate is connected to the material rack body in a sliding manner, a plurality of groups of sliding grooves are formed in the material rack body, the placing plate is connected to the sliding grooves in a sliding manner, a plurality of groups of mounting grooves are uniformly formed in the placing plate, and a limiting rod for limiting the position of the titanium alloy is arranged on the placing plate; the lifting assembly is used for driving the travelling wheels to lift; according to the utility model, the travelling wheels are arranged on the material rack body in a lifting manner, so that the movement of the material rack body is facilitated, the transfer speed is improved, the annealing efficiency is improved, and the material rack body is prevented from moving to strike the inner wall of the vacuum furnace in the annealing process, so that the material rack body is prevented from being damaged.

Description

Material frame for annealing titanium alloy vacuum furnace

Technical Field

The utility model relates to the technical field of titanium alloy production, in particular to a material rack for annealing of a titanium alloy vacuum furnace.

Background

In recent years, titanium alloys have been increasingly used in aerospace applications due to their excellent properties. After the mechanical processing of the titanium alloy part, the stress relief treatment can effectively prolong the service life of the part, the titanium alloy is easy to oxidize at high temperature, and the annealing is carried out in a vacuum environment, so that the titanium alloy is prevented from being oxidized, and the surface quality of the titanium alloy is protected.

In the prior art, when the material rack for titanium alloy annealing is used, the material rack is inconvenient to take out from the vacuum furnace, the production efficiency is affected, the placing position of the material rack on the material rack is inconvenient to adjust according to the size of the material, and the space utilization rate is low.

Disclosure of Invention

The utility model aims to solve the problems that a material rack is inconvenient to take out from a vacuum furnace and the placing position of the material cannot be adjusted according to the size of the material in the prior art, and provides a titanium alloy material rack for annealing of the vacuum furnace.

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

the utility model provides a titanium alloy vacuum furnace annealing material frame, includes the work or material rest body, still includes: the placing plate is connected to the material rack body in a sliding manner, a plurality of groups of sliding grooves are formed in the material rack body, the placing plate is connected to the sliding grooves in a sliding manner, a plurality of groups of mounting grooves are uniformly formed in the placing plate, and a limiting rod for limiting the position of the titanium alloy is arranged on the placing plate; the lifting device is characterized in that travelling wheels on the material rack body can be arranged in a lifting manner, and lifting components for driving the travelling wheels to lift are arranged in the material rack body.

In order to drive the travelling wheel to lift, preferably, the lifting assembly comprises a limiting plate which is connected to the material frame body in a sliding manner, wherein the travelling wheel is connected to the limiting plate in a rotating manner, and a limiting groove matched with the limiting plate is formed in the material frame body; the rotary rack comprises a rack body, a first rotary shaft, a second rotary shaft, a first rotary shaft and a second rotary shaft, wherein the first rotary shaft is rotationally connected to the rack body, a handle used for driving the first rotary shaft to rotate is fixedly connected to one end of the first rotary shaft, and the first rotary shaft drives a limiting plate to slide through a transmission piece.

In order to facilitate the installation of the limiting rod, preferably, the bottom of the limiting rod is fixedly connected with a mounting plate, the bottom of the mounting plate is fixedly connected with a connecting block, and the connecting block is arranged in the mounting groove through a limiting piece.

In order to prevent the stop lever from accidentally falling, further, the limiting piece comprises a limiting cylinder, wherein a threaded hole is formed in the connecting block, the limiting cylinder is in threaded connection with the threaded hole, an arc groove is formed in the inner wall of the mounting groove, a ball body clamped with the arc groove is arranged at one end of the limiting cylinder, and the ball body is connected in the limiting cylinder through a first spring.

Preferably, the cavity is formed in the material rack body, the baffle is connected in the cavity in a sliding manner, one end of the placing plate abuts against the baffle, the material rack body is connected with the pushing plate in a sliding manner, and one end of the pushing plate extends into the cavity and is fixedly connected with the baffle.

Further, a second spring is arranged in the cavity, and two ends of the second spring are fixedly connected with the baffle plate and the cavity respectively.

Compared with the prior art, the utility model provides the material rack for annealing the titanium alloy vacuum furnace, which has the following beneficial effects:

1. according to the material rack for annealing of the titanium alloy vacuum furnace, the travelling wheels are arranged on the material rack body in a lifting manner, so that on one hand, the movement of the material rack body is facilitated, on the one hand, in the transferring process, physical strength can be saved, the transferring speed can be improved, and further, the annealing efficiency can be improved, and on the other hand, the material rack body can be prevented from moving to impact the inner wall of the vacuum furnace in the annealing process, so that the material rack body is damaged;

2. this titanium alloy vacuum furnace is annealed and is used frame sets up multiunit spout through on four stands of work or material rest body, and place the board in sliding connection in the spout to set up multiunit mounting groove on placing the board, in the use, be convenient for place the layer number of board according to the high adjustment of material, adjust the distance between the board is placed to adjacent two-layer promptly, then can also be according to the length and the width adjustment of material in the position of placing on the board, help improving the space utilization to the work or material rest body, improve annealing quality.

The travelling wheel is arranged on the material rack body in a lifting manner, so that the material rack body can be moved conveniently, the transfer speed is increased, the annealing efficiency is further improved, and the material rack body can be prevented from moving to impact the inner wall of the vacuum furnace in the annealing process, so that the material rack body is prevented from being damaged.

Drawings

FIG. 1 is a schematic diagram of a frame for annealing a titanium alloy vacuum furnace;

FIG. 2 is a schematic diagram II of a frame for annealing a titanium alloy vacuum furnace;

FIG. 3 is a schematic structural view of a frame stop lever for annealing a titanium alloy vacuum furnace;

fig. 4 is a schematic structural view of a frame baffle for annealing a titanium alloy vacuum furnace.

In the figure: 1. a work or material rest body; 101. a chute; 102. a limit groove; 103. a cavity; 2. placing a plate; 201. a mounting groove; 202. an arc groove; 3. a mounting plate; 301. a connecting block; 302. a limit rod; 4. a limiting cylinder; 401. a sphere; 402. a first spring; 5. a baffle; 501. a push plate; 502. a second spring; 6. a walking wheel; 601. a limiting plate; 602. a rack; 7. a first rotating shaft; 701. a first worm; 702. a handle; 8. a second rotating shaft; 801. and a first worm wheel.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

In the description of the present utility model, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present utility model and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Examples:

referring to fig. 1-4, a material rack for annealing of a titanium alloy vacuum furnace comprises a material rack body 1 with a frame structure, wherein four upright posts and six cross beams are formed, a plurality of groups of sliding grooves 101 are formed in the four upright posts on the material rack body 1, the plurality of groups of sliding grooves 101 are distributed up and down along the axial direction of the upright posts, wherein the sliding grooves 101 penetrate through two upright posts at the front end and then extend to two upright posts at the rear, the rear upright posts are not penetrated, at least one group of sliding grooves 101 is formed, seven groups of sliding grooves are selected, a placing plate 2 is connected in a sliding manner in the sliding grooves 101, a plurality of groups of mounting grooves 201 are uniformly formed in the placing plate 2, a limiting rod 302 for limiting the position of the titanium alloy is arranged on the placing plate 2, and then the position of the limiting rod 302 on the placing plate 2 can be set according to the height condition of the material in use, so as to limit the horizontal movement of the material on the placing plate 2 in order to prevent the material from sliding from the placing plate 2 in the moving process of the material rack body 1; the walking wheels 6 are rotationally connected to the outer side wall of the material frame body 1, four groups of the walking wheels 6 are symmetrically arranged, the four groups of the walking wheels 6 are arranged on the material frame body 1 in a lifting mode, lifting components used for driving the walking wheels 6 to lift are arranged in the material frame body 1, when the material frame body 1 is pushed into a vacuum furnace or pulled out of the vacuum furnace in use, the lifting components drive the walking wheels 6 to move downwards, so that the walking wheels 6 are in contact with the ground, at the moment, the material frame body 1 is convenient to transfer, when the material frame body 1 is parked, in order to prevent the material frame body from moving in the vacuum furnace, the walking wheels 6 can be driven to slide upwards through the lifting components again, so that the material frame body 1 directly stands in the vacuum furnace, and the material frame body 1 is prevented from moving to strike the inner wall of the vacuum furnace in the annealing process, so that the material frame body 1 is damaged.

When the annealing device is used, the travelling wheels 6 are arranged on the material rack body 1 in a lifting manner, so that the material rack body 1 can be moved conveniently, physical strength can be saved in the transferring process, the transferring speed can be improved, and the annealing efficiency can be improved; through offer multiunit spout 101 on four stands of work or material rest body 1, sliding connection places board 2 in spout 101 to set up multiunit mounting groove 201 on placing board 2, in the use, be convenient for place the layer number of board 2 according to the high adjustment of material, adjust the distance between the board 2 is placed to adjacent two-layer promptly, then can also be according to the length and the width adjustment of material in place the position on board 2, help improving the space utilization to work or material rest body 1, improve annealing quality.

Referring to fig. 1 and 2, here we design the lifting assembly as: the four upright post outer side walls on the material frame body 1 are respectively provided with a limit groove 102, the limit groove 102 is in sliding connection with a limit plate 601, the travelling wheel 6 is rotationally connected to the limit plate 601, the material frame body 1 is rotationally connected with a first rotating shaft 7, one end of the first rotating shaft 7 is fixedly connected with a handle 702 for driving the first rotating shaft 7 to rotate, the first rotating shaft 7 drives the limit plate 601 to slide through a transmission piece, and here, the transmission piece is designed to be: the material rack body 1 is rotationally connected with a second rotating shaft 8, the axis of the second rotating shaft 8 is mutually perpendicular to the axis of the first rotating shaft 7, two groups of third rotating shafts are rotationally connected in the material rack body 1, the axes of the two groups of third rotating shafts are parallel to the axis of the first rotating shaft 7 and are respectively distributed at two ends of the second rotating shaft 8, a first worm 701 is fixedly connected with the first rotating shaft 7, a first worm wheel 801 meshed with the first worm 701 is fixedly connected with the second rotating shaft 8, similarly, two worm wheels II are fixedly connected with two ends of the second rotating shaft 8, worm wheels II matched with the two worm wheels are respectively fixedly connected with the three groups of rotating shafts, the rack 602 is fixedly connected to the limiting plate 601, gears meshed with the corresponding racks 602 are fixedly connected to the two ends of the two groups of rotating shafts III respectively, when the limiting plate is used, the rotating handle 702 is used for driving the rotating shaft I7 to rotate, then the worm I701 is used for driving the rotating shaft II 8 to rotate, and the limiting plate 601 can be driven to slide up and down on the side wall of the material rack body 1 with the travelling wheel 6, lifting is reliable, self-locking is achieved, and the travelling wheel 6 can be prevented from sliding upwards along the limiting groove 102 under the action of gravity, so that the use safety is affected.

Referring to fig. 1-3, a mounting plate 3 is fixedly connected to the bottom of a limiting rod 302, the bottom of the mounting plate 3 is attached to the top of a placing plate 2, a connecting block 301 is fixedly connected to the bottom of the mounting plate 3, the connecting block 301 is slidably connected in a corresponding mounting groove 201, and the connecting block 301 is limited to be pulled out through a limiting piece, so that the limiting rod 302 is prevented from accidentally falling down in the moving process, materials are caused to fall down together, the use is affected, and in the use process, the limiting rod 302 is inserted into the corresponding mounting groove 201 according to the length and the width of the materials, so that the limiting rod 302 is limited to move at the outer wall of the materials, and the falling of the limiting rod is prevented.

Referring to fig. 3, here we design the limiting piece as a limiting cylinder 4, a threaded hole is formed in a connecting block 301, the limiting cylinder 4 is in threaded connection with the threaded hole, an arc groove 202 is formed in the inner wall of a mounting groove 201, a ball 401 engaged with the arc groove 202 is arranged at one end of the limiting cylinder 4, the ball 401 is elastically connected in the limiting cylinder 4 through a first spring 402, when the connecting block 301 at the bottom of a limiting rod 302 is inserted into the mounting groove 201 in use, the ball 401 is just engaged with the arc groove 202, and when the limiting rod 302 is pulled out, certain resistance is provided, so that accidental falling of the limiting rod can be prevented, and protection of materials is affected.

Referring to fig. 1, fig. 2 and fig. 4, a cavity 103 is provided in a column in front of a material rack body 1, a baffle 5 is slidably connected in the cavity 103, one end of the baffle 5 extends into a chute 101, the baffle 5 abuts against the front end of a placing plate 2, a push plate 501 is slidably connected on the material rack body 1, one end of the push plate 501 extends into the cavity 103 and is fixedly connected with the baffle 5, in order to further limit the movement of the baffle 5 and prevent the movement of the baffle 5 due to vibration, a second spring 502 is provided in the cavity 103, two ends of the second spring 502 are fixedly connected with the baffle 5 and the cavity 103 respectively, so that the baffle 5 always abuts against the front end of the placing plate 2 under the condition of no other external force, when the placing plate 2 is placed into or taken out of the chute 101, the baffle 5 is pushed away from the chute 101 by pushing the push plate 501, and an opening of the chute 101 is opened, at this time, the placing plate 2 can be placed into or taken out of the chute 101, and the placing plate 2 can be prevented from falling out of the chute 101 in the transfer process of the material rack body 1, so that the safety is affected.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. The utility model provides a titanium alloy vacuum furnace annealing material frame, includes work or material rest body (1), its characterized in that still includes:

a placing plate (2) which is connected on the material rack body (1) in a sliding way,

the material rack comprises a material rack body (1), a plurality of groups of sliding grooves (101) are formed in the material rack body (1), a placing plate (2) is connected in the sliding grooves (101) in a sliding mode, a plurality of groups of mounting grooves (201) are uniformly formed in the placing plate (2), and a limiting rod (302) for limiting the position of a titanium alloy is arranged on the placing plate (2);

the lifting device is characterized in that a travelling wheel (6) arranged on the material rack body (1) can be lifted, and a lifting assembly used for driving the travelling wheel (6) to lift is arranged in the material rack body (1).

2. The stand for annealing a titanium alloy vacuum furnace according to claim 1, wherein said lifting assembly comprises

A limiting plate (601) which is connected on the material rack body (1) in a sliding way,

the travelling wheel (6) is rotatably connected to the limiting plate (601), and the material rack body (1) is provided with a limiting groove (102) matched with the limiting plate (601);

the rotary rack comprises a first rotary shaft (7) which is rotationally connected to a rack body (1), a handle (702) which is used for driving the first rotary shaft (7) to rotate is fixedly connected to one end of the first rotary shaft (7), and the first rotary shaft (7) drives a limiting plate (601) to slide through a transmission piece.

3. The material frame for annealing of the titanium alloy vacuum furnace according to claim 1, wherein the bottom of the limiting rod (302) is fixedly connected with a mounting plate (3), the bottom of the mounting plate (3) is fixedly connected with a connecting block (301), and the connecting block (301) is arranged in the mounting groove (201) through a limiting piece.

4. A titanium alloy vacuum furnace annealing stand according to claim 3, wherein said stopper comprises

A limiting cylinder (4),

the connecting block (301) is internally provided with a threaded hole, the limiting cylinder (4) is in threaded connection with the threaded hole, the inner wall of the mounting groove (201) is provided with an arc groove (202), one end of the limiting cylinder (4) is provided with a ball body (401) clamped with the arc groove (202), and the ball body (401) is connected with the limiting cylinder (4) through a first spring (402).

5. The material rack for annealing of the titanium alloy vacuum furnace according to claim 1, wherein a cavity (103) is formed in the material rack body (1), a baffle (5) is connected in the cavity (103) in a sliding manner, one end of the placing plate (2) is propped against the baffle (5), a push plate (501) is connected to the material rack body (1) in a sliding manner, and one end of the push plate (501) extends into the cavity (103) and is fixedly connected with the baffle (5).

6. The titanium alloy vacuum furnace annealing material rack according to claim 5, wherein a second spring (502) is arranged in the cavity (103), and two ends of the second spring (502) are fixedly connected with the baffle (5) and the cavity (103) respectively.