KR20190001120U - insulation structure - Google Patents

Abstract

The heat insulating structure of the heating furnace according to the present invention includes a bellows cover configured to enclose a side surface of a heat transfer pipe drawn out from the inside of the heating furnace to the outside, and a bellows cover interposed between the heat transfer tube and the bellows cover, And shielding means for preventing the bellows cover from being deteriorated by blocking the bellows cover.
The shielding means includes a heat insulating unit in which a plurality of heat insulating packs surrounding the side of the heat transfer tube are combined in a circumferential direction.
Each of the heat insulating packs constituting the heat insulating unit is composed of a pocket cover made of a fabric material excellent in chemical resistance and a heat insulating filler made of fibrous material excellent in heat insulating property filled therein.
The heat insulating structure of the heating furnace according to the present invention may further include a heat insulating cover to prevent heat radiated from the heat transfer tube from being transmitted to the heat insulating unit.
According to the heat insulating structure of the heating furnace according to the present invention, it is possible to positively prevent the working fluid from leaking from the heating furnace due to the nature of the packing means, and heat is transmitted from the heat transfer tube to the bellows cover side It is advantageous in that the deterioration phenomenon of the bellows cover can be effectively prevented.

Description

[0001] The present invention relates to an insulation structure of a heating furnace,

The present invention relates to a heat insulating structure of a heating furnace for preventing degradation of a bellows cover provided to prevent leakage of a working fluid from a cogeneration power plant or the like.

Generally, the power generation system of a thermal power plant and a cogeneration plant basically consists of heating a working fluid by a boiler and operating a steam turbine by using a heated working fluid. In the case of a cogeneration power plant, the power generation principle is the same as a thermal power plant One is different from a thermal power plant in that it recycles the working fluid's heat source and supplies it to the heating area or industrial heat source in the vicinity of the power plant.

As shown in FIG. 1, the heat exchanging apparatus includes a heating furnace 10 connected to a heat supply apparatus such as a boiler, and a heat exchanger 10 for heating the inside of the heating furnace 10 And a heat transfer pipe (20) communicating with the outside through.

According to the heat exchanger of the cogeneration plant, the high-temperature working fluid (combustion gas) heated by the boiler flows into the heating furnace 10 after the turbine is operated and the working fluid flows into the heat transfer tube 20 in the heating furnace 10, The heat exchange fluid is heated by exchanging heat with the heat exchange fluid in the heat exchange fluid. As described above, the heated heat exchange fluid is utilized as a new heat supply source.

In the power plant, since the intermittent operation is performed periodically, there is also a change in the amount of heat transferred to the heat exchanger. The heating furnace 10 and the heat transfer pipe 20, which are structures in the heat exchanger, .

Particularly, in the case of the heat transfer pipe 20, since the expansion ratio (elongation ratio) in the longitudinal direction is large due to its structure and material characteristics, the heat transfer pipe 20, And a sealing structure using a sealing member so that the working fluid in the housing 10 is not leaked.

The heat transfer tube 20 is also irregularly displaced in the lateral direction due to thermal deformation caused by vibrations or intermittent operation that occurs during operation of the heating furnace 10. [

Therefore, in the prior art, the sealing structure at the boundary between the heating furnace 10 and the heat transfer tube 20 gradually breaks as the vibration due to thermal deformation of the heat transfer tube 20 is repeated over time, If leakage occurs, there is a fear that the situation will be caused to maintain the safety of the facility.

A bellows cover 30 for covering the displacement of the heat transfer tube 20 at the joint portion between the heating furnace 10 and the heat transfer tube 20 so as not to break the sealing structure of the heating furnace 10 The sealing structure used was found.

The bellows cover 30 is a pipe-shaped structure capable of expanding and contracting in the lengthwise direction and covers the outer surface of the heat transfer tube 20. The upper and lower ends of the bellows cover 30 are connected to the side surface of the heat transfer tube 20 by the upper and lower brackets 32, And the upper surface of the heating furnace 10, respectively.

According to this sealing structure, since the bellows cover 30 elastically surrounds the boundary between the heating furnace 10 and the heat transfer pipe 20, there is a risk that the working fluid in the heating furnace 10 leaks to the outside The phenomenon is prevented.

According to this conventional technique, the leakage of working fluid leaked through the boundary between the heating furnace 10 and the heat transfer pipe 20 is prevented from leaking to the outside of the bellows cover 30, but the bellows cover 30 itself Not only comes into contact with the high-temperature working fluid, but also the stress caused by the stretching and shrinking operation is gradually accumulated.

If the deterioration state of the bellows cover 30 is intensified, the expansion and contraction operation is not properly performed. In the worst case, the bellows cover 30 ruptures and there is a risk of causing a large problem of leakage of the working fluid.

According to the prior art, the bellows cover 30 is fixed by the fastening bolts 36 passing through the upper bracket 32 and the lower bracket 34 as described above. Bolt holes are to be formed in the bellows cover 30 and the respective brackets 32, 34.

Accordingly, since it is difficult to form the airtight structure of the bolt hole, there is a fear that the working fluid leaking to the inside of the bellows cover 30 may leak to the outside of the bellows cover 30 through the bolt hole do.

It is an object of the present invention to provide a heat insulating structure of a heating furnace capable of preventing the deterioration of the bellows cover by completely shielding the working fluid leaked from the heating furnace.

According to an aspect of the present invention, there is provided a heat insulating structure for a heating furnace, including: a bellows cover configured to surround a side surface of a heat transfer tube drawn out from the inside of a heating furnace to the outside; and a bellows cover interposed between the heat transfer tube and the bellows cover And shielding means for preventing the bellows cover from being deteriorated by blocking a working fluid leaked from the heating furnace.

The shielding means includes a heat insulating unit in which a plurality of heat insulating packs surrounding the side of the heat transfer tube are combined in a circumferential direction.

Each of the heat insulating packs constituting the heat insulating unit is composed of a pocket cover made of a fabric material excellent in chemical resistance and a heat insulating filler made of fibrous material excellent in heat insulating property filled therein.

The heat insulating structure of the heating furnace according to the present invention may further include a heat insulating cover to prevent heat radiated from the heat transfer tube from being transmitted to the heat insulating unit.

As described above, according to the heat insulating structure of the heating furnace according to the present invention, it is possible to positively prevent the working fluid from leaking from the heating furnace due to the nature of the packing means, and due to the characteristics of the heat insulating cover, There is an advantage that heat can not be transmitted and the deterioration phenomenon of the bellows cover can be effectively prevented.

1 is a cross-sectional view showing a heat insulating structure of a heating furnace according to the prior art.
2 is a sectional view showing a heat insulating structure of a heating furnace according to the present invention.
3 is an external perspective view showing a heat insulating structure of the heating furnace according to the present invention.
4 is an exploded perspective view showing the construction of the heat insulating unit applied to the present invention.
5 is a cross-sectional view showing a heat insulating pack structure of an insulating unit applied to the present invention.

Specific details for carrying out the present invention will be described in detail with reference to FIGS. 2 to 5 attached hereto.

2 and 3, the heat insulating structure of the heating furnace according to the present invention includes a bellows cover 30 (see FIG. 2) configured to surround the side surface of the heat transfer tube 20 drawn out from the inside of the heating furnace 10 And shielding means interposed between the heat transfer pipe 20 and the bellows cover 30 for blocking heat from being transmitted to the bellows cover 30 due to the working fluid leaking from the heating furnace 10 .

4, the shielding means includes a heat insulating unit 40 in which a plurality of heat insulating packs 42 surrounding the side of the heat transfer tube 20 are combined in a circumferentially overlapping manner.

Each of the heat insulating packs 42 constituting the heat insulating unit 40 includes a pocket cover 421 made of a fabric material and a heat insulating filler material 422 made of fibrous material such as cotton .

Here, the pocket cover 421 is preferably made of a fiber material having a high chemical resistance such as a silica fabric, and the heat-insulating filler 422 may be made of a material such as silica wool It can be made of a material excellent in heat insulation.

The lower end of the heat insulating unit 40 is supported by a lower casing 50 attached to the upper surface of the heating furnace 10 and the upper end of the upper cover panel 60 is attached to the heat transfer tube 20. [ Lt; / RTI >

Here, the lower end of the heat insulating unit 40 is bent in the outward direction, and the lower casing 50 surrounds the side surface and the upper surface of the lower end of the bent heat insulating pack 42, 50 are commonly passed through the lower ends of the respective heat insulating packs 42 to fix the heat insulating packs 42 in close contact with each other.

The upper end of the heat insulating unit 40 is fixedly connected to the upper cover panel 60 so that the heat insulating packs 42 can pass through the upper end of the heat insulating packs 42 in common.

Further, according to the present invention, the bellows cover is mounted in an air-tight manner in which there is no fear of leakage of a working fluid.

The upper cover panel 60 has a lower support wall 54 having a predetermined length protruded upward from the upper surface of the lower casing 50. The upper cover panel 60 has an upper support wall 64 Are protruded downward.

The lower end of the bellows cover 30 surrounds the lower support wall 54 of the lower casing 50 and is bound by the lower clamp 56. The upper end of the bellows cover 30 is supported by the upper portion of the upper cover panel 60 Surrounding the wall 64 and bound by the upper clamp 66.

The lower clamp 56 and the upper clamp 66 surround the outer periphery of the bellows cover 30 and are tightly pressed in a ring shape so that both ends are clamped in a bolt manner to maintain a clamping state.

The heat insulating structure of the heating furnace according to the present invention is configured in such a manner that the outer surface of the heat transfer tube 20 is tightly enclosed so that the heat radiated from the heat transfer tube 20 is prevented from being transmitted to the heat insulating pack 42 side And a cover (22).

According to the heat insulating structure of the heating furnace according to the present invention constructed as described above, the working fluid in the heating furnace 10 on the boundary portion where the heating furnace 10 and the heat transfer tube 20 are in contact with each other by the expansion and contraction of the heat transfer tube 20 Since the leaked working fluid is blocked by the heat insulating unit 40, the working fluid does not come into direct contact with the bellows cover 30, thereby preventing the bellows cover 30 from being deteriorated.

Since the heat insulating unit 40 is composed of a plurality of the heat insulating packs 42 in combination to form a multilayered ply, the heat insulating operation from the innermost heat insulating pack 42 to the outermost heat insulating pack 42 is sequentially So that excellent heat insulating performance is exhibited.

The pocket cover 421 is made of a material excellent in chemical resistance and the heat insulating filler 422 is made of a material excellent in chemical resistance as described above because of the characteristics of the heat insulating unit 40 in which the heat insulating filler 422 is filled in the pocket cover 421. [ Is made of a material having excellent heat insulating property, the heat insulating function is satisfied by the heat insulating filler 422 having excellent heat insulating performance, and at the same time, Deterioration phenomena such as corrosion and hardening are suppressed to the utmost.

Further, even if the physical properties of the innermost heat insulating pack 42 are deteriorated by the continuous contact with the working fluid to thereby lose the heat insulating function, the heat insulating packs 42 disposed outside the heat insulating packs 42 sequentially maintain the function as the heat insulating means, Lt; / RTI >

On the contrary, assuming that the heat insulating unit 40 is composed of only one heat insulating pack 42, although the thickness and the material of the heat insulating pack 42 are the same as the heat insulating pack 42 of the multilayered structure of the present invention Even if the pocket cover 421 is ruptured, the heat insulating filler 422 in the pocket cover 421 may be in contact with the working fluid and rapidly deteriorate.

According to the present invention, the lower end and the upper end of the bellows cover 30 surround the lower support wall 54 of the lower casing 50 and the upper support wall 64 of the upper cover panel 60, And the upper clamp 66. As shown in Fig.

That is, since the method of mounting the bellows cover using a fastening bolt or the like penetrating through the bellows cover is not used, there is no problem of leakage of the working fluid due to the bolt hole.

According to the present invention, since the heat radiated from the heat transfer tube 20 is significantly blocked by the heat insulating cover 22 which closely surrounds the outer surface of the heat transfer tube 20, the heat insulating effect is enhanced.

10: Heating furnace 20: Heat transfer pipe
22: Insulation cover 30: Bellows cover
40: adiabatic unit 42: adiabatic pack
421: Pocket cover 422: Insulating filler
50: lower casing 60: upper cover panel

Claims (6)

A bellows cover configured to surround a side surface of the heat transfer tube drawn out from the inside of the heating furnace to the outside,
A shielding means interposed between the heat transfer tube and the bellows cover for preventing the bellows cover from being deteriorated by blocking a working fluid leaked from the heating furnace,
And a heat insulating structure for the heating furnace.
The method according to claim 1,
Wherein the shielding means comprises a heat insulating unit in which a plurality of heat insulating packs surrounding the side of the heat transfer tube are combined in a circumferentially overlapping manner.
3. The method of claim 2,
Each of the heat insulating packs constituting the heat insulating unit is composed of a pocket cover made of a fabric material excellent in chemical resistance and a heat insulating filler made of fibrous material excellent in heat insulating property
And the heat insulating structure of the heating furnace.
3. The method of claim 2,
The lower end of the heat insulating unit is supported in a form wrapped by a lower casing attached to the upper surface of the heating furnace and the upper end is supported by an upper cover panel attached to the heat transfer pipe
And the heat insulating structure of the heating furnace.
5. The method of claim 4,
Wherein the lower casing is formed in such a manner that a lower support wall having a predetermined length is protruded upward from an upper surface thereof and an upper support wall having a predetermined length protrudes downward on a bottom surface of the upper cover panel,

The bellows cover
The lower end of which surrounds the lower support wall of the lower casing and is bound by the lower clamp, the upper end of which surrounds the upper support wall of the upper cover panel and is bound by the upper clamp
And the heat insulating structure of the heating furnace.

3. The method of claim 2,
And a side surface of the heat transfer tube is tightly enclosed so that the heat radiated from the heat transfer tube is not transmitted to the heat insulating unit side.
And a heating furnace.

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