CN220999753U - High-elasticity beryllium bronze wire annealing device - Google Patents

Abstract

The utility model discloses a high-elasticity beryllium bronze wire annealing device, which belongs to the technical field of beryllium bronze wire processing, and has the technical key points that: the device comprises an adjusting unit, a placing unit and a cooling unit, wherein the adjusting unit is rotationally connected in a cooling chamber and is connected with the placing unit and used for driving the placing unit to lift in the cooling chamber; and the dislocation unit is arranged on the cooling chamber and connected with the placement unit and is used for dislocation of lifting positions of the two groups of placement units. When annealing high elasticity beryllium bronze wire rod, through placing high elasticity beryllium bronze wire rod on placing the unit, open the adjustment unit, the adjustment unit can be through placing the connection of unit with two sets of and drive two sets of units of placing and carry out reverse slip, and place the unit and can misplace each other under the effect of dislocation unit, has prevented to place the unit and has taken place the phenomenon of mutual interference at gliding in-process. The heating and cooling of the high-elasticity beryllium bronze wire can be freely switched, and the treatment efficiency of annealing the beryllium bronze wire is improved.

Description

High-elasticity beryllium bronze wire annealing device

Technical Field

The utility model relates to the technical field of beryllium bronze wire processing, in particular to a high-elasticity beryllium bronze wire annealing device.

Background

Annealing refers to slowly heating the metal to a temperature, for a sufficient time, and then cooling at a suitable rate. The aim is to reduce the hardness and improve the machinability; residual stress is eliminated, the size is stabilized, and the deformation and crack tendency is reduced; fine grains, adjust the structure and eliminate the defect of the structure.

In order to enable the beryllium bronze wire to have the performance, in the production of the beryllium bronze wire, the beryllium bronze wire is often required to be annealed, when the existing annealing furnace is used for annealing the beryllium bronze wire, the beryllium bronze wire is firstly required to be placed into the annealing furnace manually and then heated through the annealing furnace, when the beryllium bronze wire is heated to a certain temperature, the annealing furnace stops heating, and is slowly cooled along with the beryllium bronze wire, and after the annealing treatment of the beryllium bronze wire is completed, the beryllium bronze wire is taken out from the annealing furnace, so that the annealing treatment of the beryllium bronze wire is realized.

Therefore, the high-elasticity beryllium bronze wire annealing device needs to heat and cool the beryllium bronze wire stepwise, reduces the efficiency of annealing treatment on the beryllium bronze wire, and is difficult to popularize and apply, so the high-elasticity beryllium bronze wire annealing device is needed to solve the problems.

Disclosure of utility model

Aiming at the defects existing in the prior art, the embodiment of the utility model aims to provide a high-elasticity beryllium bronze wire annealing device so as to solve the problems in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

A high elasticity beryllium bronze wire annealing device, comprising:

the surface of the annealing furnace is provided with a heating ring;

The cooling chamber is connected to the side surface of the annealing furnace, and is internally provided with a placing unit which is used for placing beryllium bronze wires;

The adjusting unit is rotationally connected in the cooling chamber and connected with the placing unit and is used for driving the placing unit to lift in the cooling chamber;

And the dislocation unit is arranged on the cooling chamber and connected with the placement unit and is used for dislocation of lifting positions of the two groups of placement units.

Compared with the prior art, the embodiment of the utility model has the following beneficial effects: the utility model is rotatably connected in the cooling chamber by arranging the adjusting unit, is connected with the placing unit and is used for driving the placing unit to lift in the cooling chamber; and the dislocation unit is arranged on the cooling chamber and connected with the placement unit and is used for dislocation of lifting positions of the two groups of placement units.

When annealing high elasticity beryllium bronze wire rod, through placing high elasticity beryllium bronze wire rod on placing the unit, open the adjustment unit, the adjustment unit can be through placing the connection of unit with two sets of and drive two sets of units of placing and carry out reverse slip, and place the unit and can misplace each other under the effect of dislocation unit, has prevented to place the unit and has taken place the phenomenon of mutual interference at gliding in-process. Therefore, the heating and cooling of the high-elasticity beryllium bronze wire can be freely switched, the heating and cooling of the beryllium bronze wire can be synchronously processed, and the processing efficiency of annealing the high-elasticity beryllium bronze wire is effectively improved.

In order to more clearly illustrate the structural features and efficacy of the present utility model, the present utility model will be described in detail below with reference to the accompanying drawings and examples.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a high-elasticity beryllium bronze wire annealing device provided by an embodiment of the utility model.

Fig. 2 is a schematic structural diagram of an annealing rack according to an embodiment of the present utility model.

Fig. 3 is a schematic structural view of an L-shaped frame according to an embodiment of the present utility model.

Reference numerals: 1-annealing furnace, 11-heating ring, 12-cooling chamber, 2-placing unit, 21-slide bar, 22-slider, 23-L-shaped frame, 24-annealing placing frame, 241-supporting rod, 3-adjusting unit, 31-adjusting rod, 32-tooth plate, 33-chain, 34-connecting rod, 4-dislocation unit, 41-first chute, 42-second chute, 43-chute and 44-slide column.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Specific implementations of the utility model are described in detail below in connection with specific embodiments.

Referring to fig. 1 to 3, a high-elasticity beryllium bronze wire annealing device includes:

an annealing furnace 1, wherein a heating ring 11 is arranged on the surface of the annealing furnace 1;

A cooling chamber 12 connected to a side surface of the annealing furnace 1, in which a placement unit 2 is installed, the placement unit 2 being for placing beryllium bronze wires;

the adjusting unit 3 is rotatably connected in the cooling chamber 12 and is connected with the placing unit 2 and is used for driving the placing unit 2 to lift in the cooling chamber 12;

And the dislocation unit 4 is arranged on the cooling chamber 12, is connected with the placement units 2 and is used for dislocation of lifting positions of the two groups of placement units 2.

In the embodiment of the utility model, when the high-elasticity beryllium bronze wire is annealed, the high-elasticity beryllium bronze wire is placed on the placement unit 2, the adjustment unit 3 is started, the adjustment unit 3 can drive the two groups of placement units 2 to slide reversely through the connection with the two groups of placement units 2, and the placement units 2 can be mutually staggered under the action of the dislocation unit 4, so that the phenomenon that the placement units 2 interfere with each other in the sliding process is prevented. Therefore, the heating and cooling of the high-elasticity beryllium bronze wire can be freely switched, and the annealing treatment efficiency of the high-elasticity beryllium bronze wire is improved.

In one embodiment of the present utility model, as shown in fig. 1, 2 and 3, the placement unit 2 includes:

a slide bar 21 fixed in the cooling chamber 12, the surface of which is slidably connected with a slide 22;

An L-shaped frame 23 is slidably connected to the slider 22, and an annealing rack 24 is mounted at the end.

In this embodiment, the sliding rod 21 is fixed in the cooling chamber 12, and the surface is connected with the sliding piece 22 in a sliding manner; the L-shaped frame 23 is slidably connected in the sliding piece 22, and an annealing placing frame 24 is arranged at the end part.

When annealing the high-elasticity beryllium bronze wire, the high-elasticity beryllium bronze wire is placed on the annealing rack 24, the adjusting unit 3 is started, the adjusting unit 3 can drive the sliding piece 22 to slide upwards on the sliding rod 21 through connection with the sliding piece 22, and the sliding piece 22 can drive the annealing rack 24 at the end part of the high-elasticity beryllium bronze wire to ascend through connection with the L-shaped rack 23 until the annealing rack 24 drives the high-elasticity beryllium bronze wire on the surface of the high-elasticity beryllium bronze wire to ascend into the annealing furnace 1. The heating ring 11 is started, so that the heating ring 11 can heat the annealing furnace 1, and the high-elasticity beryllium bronze wire in the annealing furnace 1 can be annealed.

The sliding rod 21 in the placement unit 2 can also be replaced by a limiting groove, the limiting groove is formed in the inner wall of the cooling chamber 12, and the sliding piece 22 is slidably connected in the limiting groove, so that the sliding piece 22 can be stably lifted in the limiting groove.

In one embodiment of the present utility model, as shown in fig. 1, the placement unit 2 is mounted with two sets, and the surface of the two sets of annealing holders 24 is mounted with three sets of struts 241.

When the small-sized high-elasticity beryllium bronze wires are annealed, three groups of high-elasticity beryllium bronze wires are placed on the struts 241, respectively. When the high-elasticity beryllium bronze wire with larger specification is annealed, the high-elasticity beryllium bronze wire is only required to be placed on the outer surfaces of the three groups of struts 241. Thereby being capable of placing high-elasticity beryllium bronze wires with different specifications.

In one embodiment of the utility model, as shown in fig. 1, the adjusting unit 3 includes:

an adjusting lever 31 rotatably connected to the cooling chamber 12 and having a dental tray 32 mounted on the surface thereof;

A chain 33 connected between the two sets of tooth plates 32;

A link 34 hinged between the slider 22 and the chain 33.

In this embodiment, the adjusting lever 31 is rotatably connected in the cooling chamber 12, and the dental tray 32 is installed on the surface; the chain 33 is connected between the two sets of tooth plates 32; the link 34 is hinged between the slider 22 and the chain 33.

The adjusting rod 31 is rotated, the adjusting rod 31 can drive the toothed disc 32 on the surface of the adjusting rod to rotate in the process of rotating in the cooling chamber 12, so that the toothed disc 32 can drive the chain 33 to rotate, and the chain 33 can drive the sliding piece 22 to slide on the sliding rod 21 through connection with the connecting rod 34, so that the sliding piece 22 can conveniently drive the high-elasticity beryllium bronze wire on the surface of the annealing rack 24 to lift through the L-shaped frame 23, and the high-elasticity beryllium bronze wire can slide into the annealing furnace 1 to carry out annealing treatment.

The adjusting unit 3 can also be replaced by an electric telescopic rod, so that the sliding piece 22 can be conveniently driven to slide on the sliding rod 21.

In one embodiment of the present utility model, as shown in fig. 1, the dislocation unit 4 includes:

a first chute 41 provided in the cooling chamber 12;

A second chute 42 provided in the cooling chamber 12;

A chute 43 provided in the cooling chamber 12, both ends of which are respectively connected between the first chute 41 and the second chute 42;

The slide column 44 is fixed to the L-shaped frame 23 and slidably connected to the first slide groove 41, the second slide groove 42, and the chute 43.

In this embodiment, the first chute 41 is formed on the cooling chamber 12; the second chute 42 is arranged on the cooling chamber 12; the chute 43 is arranged on the cooling chamber 12, and two ends of the chute are respectively communicated between the first chute 41 and the second chute 42; the sliding column 44 is fixed on the L-shaped frame 23, and is slidably connected in the first chute 41, the second chute 42, and the chute 43.

When the sliding member 22 slides upwards, the sliding member 22 can drive the sliding column 44 to slide upwards in the second sliding groove 42 through the L-shaped frame 23. Because the sliding column 44 is respectively connected with the first sliding groove 41, the second sliding groove 42 and the sliding groove 43 in a sliding manner, the sliding column 44 can slide into the sliding groove 43, and when the sliding column 44 slides in the sliding groove 43, the sliding column 44 can drive the L-shaped frame 23 to slide rightwards in the sliding piece 22 under the pushing of the sliding groove 43, so that the L-shaped frame 23 can drive the high-elasticity beryllium bronze wire to slide rightwards synchronously through the annealing rack 24. Until the sliding column 44 slides into the first chute 41, the sliding column 44 can be adjusted to slide vertically upwards, so that the annealing rack 24 also slides vertically upwards at this time, until the annealing rack 24 drives the high-elasticity beryllium bronze wire to slide into the annealing furnace 1.

The chute 43 in the dislocation unit 4 may be replaced by an arc slot, and the arc slot is slidably connected with the sliding column 44, so that the sliding column 44 drives the L-shaped frame 23 to slide in the sliding member 22 under the pushing of the arc slot.

The working principle of the utility model is as follows: when annealing the high-elasticity beryllium bronze wire, the high-elasticity beryllium bronze wire is set on the annealing holder 24. The adjusting rod 31 is rotated, the adjusting rod 31 can drive the toothed disc 32 on the surface of the adjusting rod to rotate in the process of rotating in the cooling chamber 12, so that the toothed disc 32 can drive the chain 33 to rotate, and the chain 33 can drive the sliding piece 22 to slide on the sliding rod 21 through connection with the connecting rod 34, so that the sliding piece 22 can conveniently drive the high-elasticity beryllium bronze wire on the surface of the annealing rack 24 to lift through the L-shaped frame 23, and the high-elasticity beryllium bronze wire can slide into the annealing furnace 1 to carry out annealing treatment.

When the sliding member 22 slides upwards, the sliding member 22 can drive the sliding column 44 to slide upwards in the second sliding groove 42 through the L-shaped frame 23. Because the sliding column 44 is respectively connected with the first sliding groove 41, the second sliding groove 42 and the sliding groove 43 in a sliding manner, the sliding column 44 can slide into the sliding groove 43, and when the sliding column 44 slides in the sliding groove 43, the sliding column 44 can drive the L-shaped frame 23 to slide rightwards in the sliding piece 22 under the pushing of the sliding groove 43, so that the L-shaped frame 23 can drive the high-elasticity beryllium bronze wire to slide rightwards synchronously through the annealing rack 24. Until the sliding column 44 slides into the first chute 41, the sliding column 44 can be adjusted to slide vertically upwards, so that the annealing rack 24 also slides vertically upwards at this time, until the annealing rack 24 drives the high-elasticity beryllium bronze wire to slide into the annealing furnace 1.

Since the two sets of the placement units 2 are installed, the two sets of the placement units 2 can slide reversely under the action of the chain 33, and the two sets of the annealing racks 24 can be staggered with each other under the action of the chute 43, so that the two sets of the annealing racks 24 can be prevented from interfering with each other in the process of sliding reversely.

When one group of annealing racks 24 slides into the annealing furnace 1, the other group of annealing racks 24 can slide into the cooling chamber 12, so that when one group of high-elasticity beryllium bronze wires is annealed in the annealing furnace 1, the other group of annealed high-elasticity beryllium bronze wires can be subjected to cooling treatment, thereby freely switching the heating and cooling of the high-elasticity beryllium bronze wires and improving the treatment efficiency of annealing the high-elasticity beryllium bronze wires.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically connected, electrically connected or can be communicated with each other; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (5)

1. A high elasticity beryllium bronze wire annealing device, comprising:

the surface of the annealing furnace is provided with a heating ring;

The cooling chamber is connected to the side surface of the annealing furnace, and is internally provided with a placing unit which is used for placing beryllium bronze wires;

The adjusting unit is rotationally connected in the cooling chamber and connected with the placing unit and is used for driving the placing unit to lift in the cooling chamber;

And the dislocation unit is arranged on the cooling chamber and connected with the placement unit and is used for dislocation of lifting positions of the two groups of placement units.

2. The high-elasticity beryllium bronze wire annealing device according to claim 1, wherein the placement unit comprises:

The sliding rod is fixed in the cooling chamber, and the surface of the sliding rod is connected with a sliding piece in a sliding way;

The L-shaped frame is connected in the sliding piece in a sliding way, and an annealing placing frame is arranged at the end part of the L-shaped frame.

3. The high-elasticity beryllium bronze wire annealing device according to claim 2, wherein two groups of the placing units are installed, and three groups of struts are installed on the surfaces of the two groups of annealing racks.

4. The high-elasticity beryllium bronze wire annealing device according to claim 2, wherein the adjusting unit comprises:

the adjusting rod is rotationally connected in the cooling chamber, and the surface of the adjusting rod is provided with a dental tray;

The chain is connected between the two groups of tooth plates;

and the connecting rod is hinged between the sliding piece and the chain.

5. The high-elasticity beryllium bronze wire annealing device according to claim 4, wherein the dislocation unit comprises:

the first chute is arranged on the cooling chamber;

the second chute is arranged on the cooling chamber;

the chute is arranged on the cooling chamber, and two ends of the chute are respectively communicated between the first chute and the second chute;

And the sliding column is fixed on the L-shaped frame and is in sliding connection with the first sliding groove, the second sliding groove and the chute.