KR101833024B1 - Valve device for induction heating furnace - Google Patents

Abstract

The present invention discloses a valve apparatus for an induction heating furnace. The valve apparatus for an induction heating furnace includes a working space having an upper and a lower working space and a first refrigerant circulating flow path through which the refrigerant circulates, the main body being coupled to the induction heating furnace, And a second refrigerant circulating flow path in which a molten steel inlet port is formed at an upper end side of the upper end side so as to be infused with molten steel and the refrigerant circulates; And an opening and closing operation unit for operating the opening and closing unit up and down.

Description

VALVE DEVICE FOR INDUCTION HEATING FURNACE [0001]

The present invention relates to a valve apparatus for an induction heating furnace, and more particularly, to a valve apparatus for induction heating furnace which operates to remove a foreign substance (scale) formed in a molten steel inlet port to prevent clogging by foreign matter And more particularly to a low-pressure valve device.

Generally, an induction heating furnace used in a steel manufacturing process is a facility for supplying refined molten steel to be stored therein, and to heat or heat it to a desired temperature. Such induction heating furnace uses a molten steel heating method by electromagnetic induction as a method of keeping or heating molten steel.

For example, in an induction heating furnace in which preheating is completed, molten steel is stored, and an induction heating furnace in which molten steel is stored generates an induction electric field by applying a high frequency current to the coil to heat or heat the molten steel. Heat is generated in the molten steel due to the generated induced electric field so that the molten steel is kept at a predetermined temperature or heated.

In the induction heating furnace, a valve is provided to discharge molten steel as needed, and the cooling water is circulated in the valve to prevent the valve from being damaged.

However, the conventional induction heating furnace valve has a problem in that after the molten steel is discharged, the molten steel remaining inside is hardened and the inlet port is frequently clogged. Therefore, there is a need to improve this.

On the other hand, Korean Patent Laid-Open No. 10-2011-0128875 (published on November 30, 2011) discloses "a drive device for a control valve for liquid metal casting ", and Korean Registered Utility Model No. 20-0218317 : 2001.01.15) discloses a "valve opening / closing device for an upper heating type heating furnace ".

The present invention provides a valve device for an induction heating furnace which is created by the above-described necessity and which can prevent clogging of a molten steel inlet by operating while removing a scale generated in a molten steel inlet port located in the induction heating furnace It has its purpose.

According to an aspect of the present invention, there is provided an induction heating furnace valve device including a working space communicating with an upper portion and a lower portion, and a first refrigerant circulating flow path through which refrigerant circulates, A second molten refrigerant circulation passage through which the refrigerant circulates, and a second molten refrigerant circulation path through which the refrigerant is circulated, the second refrigerant circulation conduit being inserted into the operating space portion so as to be vertically movable so that the lower end thereof is exposed to the lower side of the main body, And an opening and closing operation unit provided in the main body to be connected to the elevating and lowering opening and closing unit and operating the elevating and lowering opening and closing unit up and down.

The main body includes a first cylinder having the first refrigerant circulating flow path and coupled to the induction heating furnace, and a sealing portion for sealing the lift-off opening / closing unit, and the second cylinder coupled to the first cylinder, And a cylinder.

In addition, the elevating / lowering opening / closing unit is coupled to the operating space portion of the main body so that the molten steel inflow port is opened when the main body is lifted from the main body and the molten steel inflow port is closed when the main body is lowered, A lift-off opening / closing part formed in the shape of a hollow body having an upper end closed and opened at a lower end and connected to the opening / closing operation part; a flow path groove formed in the outer surface so as to form a second refrigerant circulation path, And a molten steel discharge portion having a molten steel discharge port for discharging molten steel flowing into the molten steel inlet.

In addition, the flow path groove portion may include a refrigerant inflow groove formed in an outer surface of a lower end portion of the molten steel discharge portion and a longitudinal direction formed in an outer surface of the molten steel discharge portion to communicate with the refrigerant inflow groove, And a refrigerant diffusion groove for diffusing the refrigerant.

As described above, the valve apparatus for induction heating furnace according to the present invention operates while removing the scale generated in the molten steel inlet located in the induction heating furnace, unlike the prior art, thereby preventing clogging of the molten steel inlet due to scale .

1 is a view showing a state in which a valve apparatus for an induction heating furnace according to an embodiment of the present invention is applied.
2 is an exploded perspective view illustrating a valve apparatus for an induction heating furnace according to an embodiment of the present invention.
3 is an assembled perspective view illustrating a valve apparatus for an induction heating furnace according to an embodiment of the present invention.
4 is a sectional view taken along line AA in Fig.
5 is a sectional view taken along line BB of Fig.
6 is an operational state diagram of a valve apparatus for an induction heating furnace according to an embodiment of the present invention.
7 is an exploded perspective view illustrating a lifting / lowering unit according to an embodiment of the present invention.
8 is a cross-sectional view of the connection of Fig.

Hereinafter, preferred embodiments of the valve apparatus for an induction heating furnace according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a view showing a state in which a valve apparatus for an induction heating furnace according to an embodiment of the present invention is applied. FIG. 2 is an exploded perspective view showing a valve apparatus for an induction heating furnace according to an embodiment of the present invention. And FIG. 3 is a perspective view illustrating a valve apparatus for an induction heating furnace according to an embodiment of the present invention.

3 is a cross-sectional view taken along the line BB in Fig. 3, Fig. 6 is an operational state view of the valve apparatus for an induction heating furnace according to an embodiment of the present invention, Fig. 7 is a cross- 8 is an exploded cross-sectional view of the lifting and lowering opening and closing unit according to the embodiment of the present invention.

1 to 8, a valve apparatus 100 for an induction heating furnace according to an embodiment of the present invention is a valve apparatus for induction heating furnace 100 installed in an induction heating furnace 10, Respectively.

The valve apparatus 100 for induction heating according to the present embodiment includes a main body 110 coupled to the induction heating furnace 10 and an elevating opening and closing unit 120 and an opening and closing operation unit 130 for operating the elevation opening and closing unit 120. Such valve apparatus 100 for induction heating furnace is prevented from being clogged by the scale.

The main body 110 is provided with a working space 111 in which the lifting and lowering opening and closing unit 120 is vertically coupled to be lifted and lowered and a first refrigerant circulating flow path 113 is provided to prevent breakage and deformation do.

Specifically, the main body 110 includes a first cylinder 115 that is joined to the induction heating furnace 10, a second cylinder 117 that is coupled to the first cylinder 115 for sealing the lifting and lowering opening and closing unit 120, ). At this time, the first cylinder 115 is welded to the lower surface of the induction heating furnace 10, and the second cylinder 117 is coupled to the first cylinder 115 through the fastening member.

The main body 110 has a first cylinder 115 and a second cylinder 117 formed with a working space 111 vertically through the first cylinder 115 and a first refrigerant circulating flow path 113 is formed in the first cylinder 115 . The formation of the first refrigerant circulation flow path 113 in the first cylinder 115 is intended to prevent deformation and breakage of the first cylinder 115 in direct contact with the molten steel.

The first cylinder 115 is provided with a heating furnace coupling portion 115a inserted into the induction heating furnace 10 and a first flange 115a protruding from the heating furnace coupling portion 115a and joined to the lower face of the induction heating furnace 10, And a branch portion 115b.

The first refrigerant circulation passage 113 includes a first refrigerant inlet 113a and a first refrigerant outlet 113b formed to correspond to the first flange 115b and a first refrigerant inlet 113b and a first refrigerant inlet 113b, And a first circulation flow passage 113c formed in the heating chamber engagement portion 115a so as to communicate with the first refrigerant discharge port 113b. The first refrigerant circulation flow path 113 circulates the refrigerant flowing through the first refrigerant inlet port 113a along the first circulation flow path 113c to cool the first cylinder 115, 113b. In addition, the first refrigerant inlet 113a and the first refrigerant outlet 113b are connected to a separate refrigerant supply device.

 The second cylinder 117 is coupled to the first flange portion 115b of the first cylinder 115 so as to seal the first cylinder 115 as well as to seal the lift-off opening and closing unit 120. The second cylinder 117 includes an operation guide portion 117a which is coupled to the lift-off opening and closing unit 120 so as to penetrate therethrough and a second guide portion 117b protruding from the operation guide portion 117a and engaged with the first flange portion 115b. And a flange portion 117b. The second cylinder 117 is provided with a sealing portion 119 for sealing the lifting and lowering opening and closing unit 120 in the operation guide portion 117a.

The sealing portion 119 not only seals the second cylinder 117 and the lift-off opening / closing unit 120 but also restricts the vertical movement of the lift-off opening / closing unit 120 so that the lift- . For this purpose, the sealing portion 119 is formed inside the operation guide portion 117a.

Specifically, the sealing portion 119 includes a first sealing member 119a for sealing between the operating space portion 111 and the elevation opening / closing unit 120, A second sealing member 119c for sealing between the movement restricting ceiling space 119b and the lift-off opening and closing unit 120 and a second restricting sealing space portion 119b for preventing the escape of the lift- 119b). ≪ / RTI >

The first sealing member 119a is coupled to the operation guide portion 117a and the second sealing member 119c is coupled to the lift-off switching unit 120.

The release preventing member 119d is formed with a male screw portion on the outer surface so that the third sealing member 119e for sealing the movement restricting sealing portion 119b is engaged and easily assembled in the movement restricting sealing portion 119b . At this time, a female screw portion is formed on the inner surface of the movement restricting sealing space portion 119b. This is to allow the lifting and lowering opening and closing unit 120 to be easily assembled to the main body 110.

The lift-off opening / closing unit 120 is vertically movably inserted into the operating space 111 such that the lower end thereof is exposed to the lower side of the second cylinder 117, and a molten steel inlet 120a into which the molten steel is injected is formed on the upper end side . When the elevating and lowering operation unit 130 is raised by the opening and closing operation unit 130, the molten steel inlet port 120a is exposed to the upper side of the first cylinder 115 and is opened. When the elevating and lowering operation unit 130 is lowered, The inlet 120a is inserted into the operating space 111, and the molten steel inlet 120a is sealed.

Since the lifting and lowering opening and closing unit 120 is lifted up and down through the opening and closing operation part 130, the scaling formed on the molten steel inlet 120a collides with the second cylinder 117 upon ascending and descending, do. It is possible to prevent the molten steel inlet 120a from being clogged by the scaling.

In particular, the lift-off switching unit 120 is provided with a second refrigerant circulation channel 121 so that cooling by the refrigerant can be more effectively performed.

The lifting and lowering opening and closing unit 120 according to the present embodiment includes a lifting and lowering opening 123 for selectively discharging the molten steel to form the second refrigerant circulating flow path 121 and a second refrigerant circulating flow path 121 And a molten steel discharging portion 125 which is inserted and joined to the lifting and lowering opening 123.

The lifting and lowering opening and closing part 123 is movably coupled to the operating space part 111 so as to be connected to the opening and closing operation part 130. A molten steel inflow port 120a is formed on the outer surface of the upper end part, do. The lifting and lowering opening and closing part 123 has a hollow shape with an upper end closed and a lower end opened and forms a second refrigerant circulation flow path 121 in a pair with a molten steel discharge part 125 coupled to the inside.

The lifting and lowering opening and closing part 123 is coupled to the main body 110 such that the sealing support part 123a is inserted into the movement restricting space part 119b and the second sealing member 119c is engaged with the outer surface of the sealing supporting part 123a. do.

The lifting and lowering opening and closing unit 123 is opened while the molten steel inlet 120a is exposed to the outside of the main body 110 when the main body 110 is lifted from the main body 110. When the molten steel inlet 120a is lowered from the main body 110, And is sealed. The lifting and lowering opening and closing part 123 is supported by the end of the sealing part 119 when the lifting and lowering part 123 is lifted or lowered from the main body 110. When the lifting and lowering part 123 is lowered from the main body 110, .

The molten steel discharge portion 125 is provided with a flow groove portion 127 for forming the second coolant circulation flow passage 121 in a pair with the lift opening and closing portion 123 and discharges molten steel flowing into the molten steel inlet port 120a at the central portion thereof A molten steel discharge port 125a is formed to penetrate through the molten steel discharge port 125a. The molten steel discharge portion 125 is inserted and joined to the lifting and lowering opening portion 123 so that the molten steel discharge port 125a communicates with the molten steel inlet port 120a.

In addition, the molten steel discharge portion 125 is formed with a spacing protrusion 125b on the upper surface thereof so that the second refrigerant circulation passage 121 is formed in a wider area. Accordingly, the second refrigerant circulation flow path 121 is formed between the upper surface of the molten steel discharge portion 125 and the lifting / lowering switching portion 123, so that the refrigerant circulates over a wider area, thereby increasing the cooling effect.

The flow path groove portion 127 has a refrigerant inflow groove 127a formed on the outer surface of the lower end portion of the molten steel discharge portion 125 so as to allow the refrigerant to flow therein and a molten steel discharge portion 127a for diffusing and transferring the refrigerant flowing into the refrigerant inflow groove 127a And a refrigerant discharge groove 127c formed so as to correspond to the refrigerant inlet groove 127a through which the refrigerant circulated through the refrigerant diffusion groove 127b is discharged. At this time, the coolant inflow groove 127a and the coolant discharge groove 127c are partitioned through a partition rib 127d extending from the coolant diffusion groove 127b. A first diffusion groove 127b 'for circulating refrigerant flowing through the refrigerant diffusion groove 127b and the refrigerant introduction groove 127a to the upper surface of the molten steel discharge portion 125 through the partition rib 127d, And a second diffusion groove 127b "for circulating the refrigerant circulated on the upper surface of the discharge portion 125 to the refrigerant discharge groove 127c.

That is, the refrigerant flowing into the refrigerant inflow groove 127a is circulated upward along the first diffusion groove 127b 'and then transferred downward along the second diffusion groove 127b' The second refrigerant circulation channel 121 is formed at the lower end of the lift-off opening / closing part 123 so as to communicate with the refrigerant inlet groove 127a, so that the second refrigerant circulation channel 121 is formed to be discharged to the discharge groove 127c. And a second refrigerant outlet 121b formed at the lower end of the lifting and lowering opening 123 to communicate with the refrigerant discharge groove 127c.

The opening and closing operation part 130 is provided on the main body 110 to connect the lift-off opening and closing unit 120 to operate the lift-off opening and closing unit 120 up and down. Specifically, the opening and closing operation part 130 includes an actuator 131 coupled to the outer surface of the second cylinder 117, and a connection flange 130 connected to the outer surface of the lower end of the lift-off opening and closing part 123 to be connected to the cylinder rod of the actuator 131. [ (133). At this time, the lifting and lowering opening 123 is formed with a coupling groove 123b so that the coupling flange 133 is firmly coupled.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the claims.

10: Induction heating furnace 100: Valve unit for induction heating furnace
110: main body 111: operating space part
113: first refrigerant circulation flow path 115: first cylinder
117: second cylinder 119: sealing part
120: lift-off switching unit 121: second refrigerant circulation channel
123: lift-off opening / closing part 125:
127: flow groove portion 130: actuator
131: Connecting flange

Claims (4)

A main body coupled to the induction heating furnace and having a working space communicating with the first and second refrigerant circulation circulation channels; And a second refrigerant circulation channel in which a lower end portion is exposed to the lower side of the main body so as to be vertically movable, a molten steel inlet port through which molten steel is injected into the upper end side surface, ; And an opening and closing operation unit, which is provided in the main body to be connected to the elevating and lowering opening and closing unit and operates the elevating and lowering opening and closing unit up and down,
The elevating /
The molten steel inflow port is opened when the main body is lifted from the main body and is elevatably coupled to the operating space portion of the main body so that the molten steel inflow port is closed and inserted into the main body when the main body is lowered from the main body, A lifting opening / closing part formed in a hollow body shape and connected to the opening / closing operation part; And
A molten steel discharge portion having a flow path groove formed on an outer surface thereof to form a second coolant circulation flow path and being coupled to the inside of the lift-off switching portion and having a molten steel discharge port for discharging molten steel flowing into the molten steel inlet;
Wherein the valve device is a valve device for an induction heating furnace. The apparatus of claim 1,
A first cylinder having the first refrigerant circulation channel and coupled to the induction heating furnace; And
A second cylinder having a sealing portion for sealing the lift-off opening / closing unit, the second cylinder being coupled to the first cylinder;
Wherein the valve device is a valve device for an induction heating furnace. delete The fluid machine according to claim 1,
A coolant inflow groove formed on an outer surface of a lower end portion of the molten steel discharge portion; And
A refrigerant diffusion groove portion formed in the longitudinal direction on the outer surface of the molten steel discharge portion so as to communicate with the refrigerant inlet groove and simultaneously diffusing the refrigerant flowing through the refrigerant inlet groove;
Wherein the valve device is a valve device for an induction heating furnace.

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