KR101968025B1 - Heat processing apparatus for annealing furnace - Google Patents

Abstract

The present invention relates to a heat processing apparatus for an annealing furnace. According to the present invention, the heat processing apparatus for an annealing furnace comprises: an apparatus body provided in an annealing furnace; and a fluid supply means connected to the annealing furnace and the apparatus body, and provided with at least one supply pipe supplying a fluid to the inside of the apparatus body. The fluid supply means is provided to move with respect to at least one of the annealing furnace and the apparatus body, and to change a distance from the supply pipe to the apparatus body.

Description

{HEAT PROCESSING APPARATUS FOR ANNEALING FURNACE}

The present invention relates to an annealing heat treatment apparatus.

A general stainless steel brass annealing line is a line for producing a stainless steel plate having a glossy surface having a mirror-like surface and is subjected to a heat treatment in a reducing atmosphere containing hydrogen in order to prevent degradation of gloss due to oxidation occurring during the annealing process .

The annealing furnace 10 shown in Fig. 1 is a facility used for the heat treatment of such a light annealing line, and a vertical annealing furnace is mainly used in order to minimize the interference of the steel plates and to keep the furnace pressure in a stable state.

The vertical annealing furnace 10 is provided with a heating furnace 2 in which a stainless steel plate 1 is heat treated and a muffle 3 in which a hydrogen gas is filled in the heating furnace 2 in a reducing atmosphere, And a cooling base 4 for cooling the heat-treated stainless steel plate 1. [0031] As shown in Fig.

The stainless steel sheet 1 is drawn into the lower portion of the muffle 3 and is drawn out to the upper portion. The entrance portion of the stainless steel sheet 1 can be sealed by the seal box 5.

Piping devices (not shown) are connected to the inside of the muffle 3 to supply nitrogen gas together with hydrogen gas into the muffle. The hydrogen and nitrogen gas thus supplied directly affect decarburization and grain structure formation during annealing .

However, in the muffle (3) and the heating furnace (2), the piping devices welded to the muffle (3) as elements for repeating heating and cooling repeatedly thermally expand and contract to weaken durability and eventually break or break .

KR 10-2016-0015261 A (2016.02.12)

The object of the present invention is to improve the durability of the annealing heat treatment apparatus and to prolong the life of the apparatus.

Further, the present invention aims at reducing the maintenance cost of the apparatus and contributing to the reduction of the manufacturing cost.

The present invention relates to an annealing heat treatment apparatus.

An annealing heat treatment apparatus according to the present invention comprises: a device body provided inside an annealing furnace; And a fluid supply means connected to the annealing furnace and the apparatus body and having at least one supply pipe for supplying a fluid into the apparatus body, wherein the fluid supply means includes at least one of the annealing furnace and the apparatus body So that the distance from the supply pipe to the apparatus body can be changed.

The fluid supply means may include a length varying member connected to the apparatus body to communicate with the inside of the apparatus body and exposed to the outside of the annealing furnace; And the supply pipe connected to the elongated deformable member, wherein the elongate deformable member has a fluid discharge port of the supply pipe inside and can surround the supply pipe to block the fluid discharge port from the outside.

Further, preferably, the supply pipe includes: a first supply pipe connected to the length-varying member to supply a first fluid at a first fluid outlet; And a second supply pipe connected to the elongated deformable member to supply a second fluid at a second fluid outlet, wherein the second supply pipe has a second fluid outlet communicating with an outer circumference of the first supply pipe and a second fluid outlet And may be connected to the length-varying member so as to be positioned between the inner circumference of the deforming member.

Preferably, the length-varying member has a narrowest area of an end closest to the apparatus body on a plane perpendicular to a direction in which the supply pipe supplies fluid, an area of an end farthest from the apparatus body is the widest, The area can be provided to widen linearly.

It is also preferable that the fluid supply means further comprises a sleeve member having a hollow portion and connected to at least one of the annealing furnace and the apparatus body such that the length varying member and the supply pipe are located in the hollow portion .

More preferably, the length-varying member may be formed of a flexible material.

Also preferably, the length-varying member may be a corrugated tube that is elongated or contracted in the same direction as the supply pipe supplies the fluid.

Preferably, the sleeve member has an inner surface corresponding to an outer surface of the elongated member, and the side surface may be linearly inclined.

And, preferably, the supply pipe may be provided to supply hydrogen gas to the first fluid and nitrogen gas to the second fluid.

According to the present invention, the durability of the annealing heat treatment apparatus is improved and the life of the apparatus is prolonged.

In addition, there is an effect that the maintenance cost of the apparatus is reduced and the manufacturing cost is reduced.

Fig. 1 schematically shows a conventional annealing furnace.
FIG. 2 schematically shows an annealing heat treatment apparatus according to a preferred embodiment of the present invention.
FIG. 3 schematically shows an annealing heat treatment apparatus according to another embodiment of the present invention.
4 is a local enlarged view of Fig.

In order to facilitate an understanding of the description of the embodiments of the present invention, elements denoted by the same reference numerals in the accompanying drawings are the same element, and among the constituent elements that perform the same function in each embodiment, Respectively.

Further, in order to clarify the gist of the present invention, a description of elements and techniques well known in the prior art will be omitted, and the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood, however, that the spirit and scope of the present invention are not limited to the embodiments shown, but may be suggested by those skilled in the art in other forms, additions, or alternatives, .

FIG. 2 shows an annealing heat treatment apparatus 100 according to a preferred embodiment of the present invention.

The annealing heat treatment apparatus 100 according to an embodiment of the present invention includes an apparatus body 110 provided inside an annealing furnace 101 and an annealing furnace 101 connected to the annealing furnace 101 and the apparatus body, And a fluid supply means 120 having at least one supply pipe 122 for supplying fluid to the space 111. [

Hereinafter, the apparatus body 110 may be a muffle provided inside the annealing furnace 101, and the annealing furnace 101 may include a furnace.

The supply pipe 122 may be provided to be moved with respect to at least one of the annealing furnace 101 and the apparatus body 110 so that the distance to the apparatus body 110, To the device body 110 in the fluid supply direction.

The supply pipe 122 is movably provided with respect to the apparatus body 110 without being welded to the apparatus body 110 as in the prior art so that the supply pipe 122 is disconnected from the apparatus body 110 by thermal expansion or heat shrinkage There is no fear of becoming.

The fluid supply means (120) further includes a length-deforming member (121) connected to the apparatus body so as to communicate with the inside of the apparatus body and exposed to the outside of the annealing furnace, And is connected to the deformable member 121.

The length-deforming member 121 includes a pipe accommodating space 121a having a constant volume therein, and the pipe accommodating space 121a is shielded from the outside.

One side of the length-changing member 121 is drawn into the annealing furnace 101 and connected to the apparatus body 110. Accordingly, the inner space 111 of the apparatus body 110 can communicate with the pipe accommodating space 121a of the elongated member 121.

The weight of the length-deforming member 121 can be dispersed and supported by the annealing furnace 101 and the apparatus body 110 and the length of the length-varying member 121 can be adjusted by the weight of the furnace 101 and the apparatus body 110 The supply pipe 122 may be inserted into the fixing surface 121b of the length-deforming member 121 and exist in the pipe accommodating space 121a of the length-deforming member 121. [

The supply pipe 122 is provided with a control valve 126 for controlling the opening and closing of the passage so that the flow of the fluid inside the supply pipe 122 can be controlled by controlling the control valve 126.

Preferably, the control valve 126 is connected to a control unit (not shown), and the operator can remotely control the opening and closing of the control valve 126 through the control of a control unit (not shown).

However, it should be understood that the present invention is not limited thereto, and may be appropriately changed by those skilled in the art.

At this time, the length-varying member 121 is made of a flexible material and can be provided to extend or contract in a direction opposite to the fluid supply direction or the fluid supply direction.

In this case, one side of the length-deforming member 121 can be connected and fixed to the apparatus body 110, and thus a part of the supply pipe 122 connected to the length-deforming member 121 and the length- So that the device body 110 can support the load.

However, in this state, in order to enable the length deformation member 121 to be deformed in the direction opposite to the fluid supply direction or the fluid supply direction, a connection such as a rolling bearing is formed between the annealing furnace 101 and the length- An auxiliary member (not shown) is provided to allow the inside of the annealing furnace 101 and the outside of the furnace 101 to be blocked while allowing the length of the length-deforming member 121 to be deformed.

However, the present invention is not necessarily limited to the present invention, but may be appropriately modified by those skilled in the art.

3, the fluid supply unit 120 according to another embodiment of the present invention includes a hollow portion 127a, and the length modification member 121, And a sleeve member 127 connected to at least one of the annealing furnace 101 and the apparatus body 110 so that the supply pipe 122 is located.

The sleeve member 127 is made of a ceramic material and is connected to and fixed to the apparatus body 110 and the worn-out shaft 101. In this case, A connection assisting member (not shown) is provided to facilitate the deformation of the length-changing member 121.

When the sleeve member 127 is made of a ceramic material and the length-deforming member 121 is wrapped, heat damage to the length-deforming member 121 and the supply pipe 122 can be prevented, and the durability of the apparatus can be further improved.

However, the material of the sleeve member 127 is not necessarily limited to the present invention, but may be appropriately changed depending on the operator and the working environment.

Preferably, the supply pipe according to the present invention may exist in the pipe accommodating space 121a of the elongated deformable member 121, as shown in Fig.

The supply pipe 122 includes a first supply pipe 123 for supplying the first fluid at the first fluid outlet 125a and a second supply pipe 124 for supplying the second fluid at the second fluid outlet 125b .

At this time, the second supply pipe 124 is fixed to the length-changing member 121 so that the second fluid outlet 125b is positioned between the outer circumference of the first supply pipe 123 and the inner circumference of the length- And may be connected to the surface 121b.

Accordingly, the second fluid supplied from the second supply pipe 124 may exist in the pipe accommodating space 121a of the length-varying member 121 in a considerable number.

Since the first fluid outlet 125a of the first supply pipe 123 is located at the end of the elongated member 121, the first fluid outlet 125a of the first supply pipe 123 is relatively positioned closer to the first body 110 than the second fluid outlet 121b. The first fluid discharged through the fluid outlet 125a may be hydrogen, and the second fluid may be nitrogen.

The area of the end portion S1 closest to the apparatus body 110 is narrowest on a plane perpendicular to the direction in which the supply pipe 122 supplies the fluid to the length-changing member 121, The area of the end S2 that is farthest from the main body 110 is the widest. If the area is linearly widened, the flow path of the second fluid narrows linearly as the main body 110 approaches the main body 110.

Therefore, the flow rate at the end S1 closest to the apparatus body 110 at the inside of the elongated deformable member 121 is increased by the Venturi principle, and it is possible to induce the rapid introduction of the fluid into the apparatus body 110.

The first supply pipe 123 is positioned at the center and the second supply pipe 124 is disposed between the first supply pipe 123 and the inner surface of the length-variable member 121, And then comes into contact with the hydrogen gas discharged from the first fluid outlet 125a at the end S1 closest to the apparatus body 110. [

Therefore, since the nitrogen that is discharged from the first fluid outlet 125a flows into the inner space 111 of the device body 110 more quickly due to the explosive force of the hydrogen, hydrogen and nitrogen gas are introduced into the interior of the device body 110 It is possible to more effectively enter the space 111.

The inner surface of the sleeve member 127 disposed on the outer circumference of the lengthwise deforming member 121 is also provided in a shape corresponding to the outer surface of the length varying member 121, Likewise, the side surface may be linearly inclined.

Also preferably, the length-varying member 121 may be provided as a corrugated tube that is elongated or contracted in the same or opposite direction as the direction in which the supply pipe 122 supplies the fluid.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be apparent to those of ordinary skill in the art.

1: Stainless steel plate 2: Heating furnace
3: Muffle 4: Cooling Base
5: sealed box 10, 101: annealing furnace
110: device body 111: inner space
120: fluid supply means 121:
121a: pipe accommodating space 122: supply pipe
123: first supply pipe 124: second supply pipe
125: fluid outlet 125a: first fluid outlet
125b: second fluid outlet port 126: control valve
127: Sleeve member

Claims (9)

A device body provided inside the annealing furnace; And
And a fluid supply means having at least one of the annealing furnace and a supply pipe connected to the apparatus body for supplying a fluid into the apparatus body,
Wherein the fluid supply means comprises:
Wherein the apparatus is moved relative to at least one of the annealing furnace and the apparatus body to change a distance from the supply pipe to the apparatus body.
The method according to claim 1,
Wherein the fluid supply means comprises:
A length varying member connected to the apparatus body so as to communicate with the inside of the apparatus body and exposed to the outside of the annealing furnace; And
And the supply pipe connected to the length-varying member,
The length-
Wherein the fluid discharge port of the supply pipe is present inside and surrounds the supply pipe so as to block the fluid discharge port from the outside.
3. The method of claim 2,
Wherein the supply pipe comprises:
A first supply pipe connected to the length-varying member to supply a first fluid at a first fluid outlet; And
And a second supply pipe connected to the length-varying member to supply a second fluid at a second fluid outlet,
Wherein the second supply pipe includes:
And the second fluid outlet is connected to the length-changing member so that the second fluid outlet is located between the outer periphery of the first supply pipe and the inner periphery of the length-varying member.
The method according to claim 2 or 3,
The length-
On the plane perpendicular to the direction in which the supply pipe supplies fluid, the area of the end closest to the apparatus body is narrowest, the area of the end farthest from the apparatus body is the widest, and the area is linearly widened The annealing heat treatment apparatus comprising:
The method according to claim 2 or 3,
Wherein the fluid supply means comprises:
A sleeve member having a hollow portion and connected to at least one of the annealing furnace and the apparatus body such that the lengthwise deforming member and the supply pipe are located in the hollow portion;
Further comprising an annealing heat treatment apparatus.
The method according to claim 2 or 3,
The length-
Wherein the annealing heat treatment apparatus is made of a flexible material.
The method according to claim 6,
The length-
Wherein the supply pipe is a corrugated tube which is elongated or contracted in the same direction as the direction of supplying the fluid.
6. The method of claim 5,
The sleeve member
Wherein the inner surface is formed in a shape corresponding to the outer surface of the elongated member, and the side surface is linearly inclined.
The method of claim 3,
Wherein the supply pipe comprises:
Supplying hydrogen gas to the first fluid,
And the second fluid is supplied to supply nitrogen gas.

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