KR20110035400A - Thermal deformation absorption structure of gpv-wao reactor - Google Patents

Abstract

PURPOSE: A thermal deformation absorbent type gravity pressure vessel-wet air oxidation reactor is provided to prevent the generation of damage in the reactor due to thermal deformation. CONSTITUTION: A thermal deformation absorbent type gravity pressure vessel-wet air oxidation reactor includes a coolant chamber, an external pipe(200), an internal pipe(300), and an oxidizer supplying pipe(400). The upper side of the coolant chamber is protruded through the ground. The lower side of the external pipe is inserted through the upper side of the coolant chamber. The lower side of the internal pipe is inserted through the upper side of the external pipe. The oxidizer supplying pipe passes through the upper side of the internal pipe and is expanded to the lower side of the internal pipe. An oxidizer is supplied through the oxidizer supplying pipe.

Description

Thermal Deformation Absorption Structure of GPV-WAO Reactor

The present invention relates to a heat deformation absorbing structure of a gravity wet oxidation reactor, and more particularly, when the temperature inside the gravity wet oxidation reactor rises so that the heat deformation occurs, the deformation is freely stretched to the ground so that the gravity wet oxidation reactor heat deformation. Characterized in that can be protected from.

In the case of the conventional ground pressurized tank type wet oxidation system as shown in FIG. 1, in order to promote the oxidation reaction during the oxidation treatment of waste, it is necessary to maintain a high temperature and high pressure environment inside the reactor. A pressurization system must be provided.

In this case, there is a problem that a high cost is involved in the initial installation and operation, maintenance for the maintenance of high temperature, high pressure of the wet oxidation reactor.

In order to improve the problems of the conventional wet oxidation reactor, a gravity wet oxidation reactor as shown in FIG. 2 is presented. (Oxygen and liquid waste are supplied to separate passages under the reactor and are provided at the top of the reactor after the wet oxidation reaction is performed.) In the case of a gravity wet oxidation reactor, a temperature change of several hundred degrees Celsius or more occurs inside a reactor buried at a depth of several hundreds to thousands of meters, so that the thermal deformation of several meters in the longitudinal direction (temperature rise) Length elongation) occurs, and failure to absorb such heat deformation effectively causes damage to the gravity wet oxidation reactor.

Therefore, there is an urgent need to introduce a structure that can effectively absorb such heat deformation to protect the gravity wet oxidation reactor.

The present invention created to solve the above problems is to protect the gravity wet oxidation reactor by effectively absorbing the heat deformation according to the temperature inside the gravity pressure vessel.

Technical composition of the present invention created to achieve the above object is as follows.

The present invention is an overall open top, the bottom surface is sealed and elongated in the vertical direction, the bottom surface is fixed to the bottom surface of the core (99) perforated on the ground and the cooling water chamber 100 is protruded to the ground ); As a whole, the upper part is opened, the lower surface is closed, and is elongated in the vertical direction, and the closed lower surface is inserted through the upper part of the cooling water chamber 100 so that the cooling water chamber ( An external pipe 200 which is spaced apart from the lower surface of the 100 and has an upper end protruding to an upper portion of the cooling water chamber 100; As a whole, the upper surface is sealed and the lower surface is open and elongated in the vertical direction, the lower end is inserted through the upper portion of the outer pipe 200, the outer pipe 200 in the inner lower portion of the outer pipe 200 Maintaining a state spaced apart from the lower surface of the, the closed upper surface is an inner pipe 300 is installed to protrude to the upper portion of the outer pipe (200); And an oxidant supply pipe (400) extending through the upper surface of the inner pipe (300) to the lower portion of the inner pipe (300) and serving as a supply passage for the oxidant. The coolant chamber (100) The cooling water supply port 110 is provided on one side of the lower side and the cooling water outlet 120 is provided on one side of the upper side, the liquid waste discharge port 210 is provided on the upper side of the outer pipe 200, the liquid waste discharge port ( The lower portion of the 210 is provided with an outer pipe support 220 along the outer circumference of the outer pipe 200, the upper side of the inner pipe 300 is provided with a liquid waste supply port 310, the liquid waste A lower portion of the supply port 310 is provided with an inner pipe support part 320 along an outer circumference of the inner pipe 300, and the coolant chamber upper group connection part 130 formed along an upper edge of the coolant chamber 100. The external pipe support 220 is watertight Is coupled to resin, it characterized in that the external pipe coupling the upper connection part 230 and the inner pipe supporting portion 320 formed along an upper end edge of the outer pipe 200 is to maintain the water-tightness.

According to the configuration of the present invention it is possible to effectively protect the gravity wet oxidation reactor by absorbing the heat deformation (length extension according to the temperature rise).

In other words, if the heat deformation occurs due to the temperature rise of the coolant chamber 100, the lower surface of the coolant chamber 100 is fixed to the bottom surface of the core (99) so that the upper end of the coolant chamber 100 rises due to thermal deformation. As a result, the external pipe 200 is also raised together.

As such, when the outer pipe 200 rises, the distance between the lower surface of the outer pipe 200 and the lower surface of the coolant chamber 100 is farther away, thereby absorbing heat deformation of the outer pipe 200 ( Length) can be obtained more.

In addition, the lower end of the inner pipe 300 is spaced apart from the lower surface of the outer pipe 200 bar, the inner pipe 300 is to be coupled to the external pipe on the group connection 230 is mounted.

Therefore, when the upper end of the external pipe 200 rises due to heat deformation due to the temperature rise of the cooling water chamber 100 or the external pipe 200, the internal pipe 300 also rises together, and the internal pipe 300 of the The distance between the lower surface and the lower surface of the outer pipe 200 is farther away, thereby further securing an area (length) capable of absorbing heat deformation of the inner pipe 300.

The lower end of the oxidant supply pipe 400 also maintains an interval greater than or equal to the bottom surface of the outer pipe 200 in the vertical direction maximum heat deformation length of the oxidant supply pipe 400, even if the oxidant supply pipe 400 extends as much as possible. The lower end does not contact the lower surface of the outer pipe 200.

As the external pipe 200, the internal pipe 300, and the oxidant supply pipe 400 are provided in the cooling water chamber 100 in the above-described manner, the temperature is increased to allow the coolant chamber 100, the external pipe 200, and the internal pipe. Even if the 300 or the oxidant supply pipe 400 is extended, the increased length is absorbed by the cooling water chamber 100, the external pipe 200, the internal pipe 300, and the oxidant supply pipe 400 to each other to be thermally deformed. Damage to the device can be prevented.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 illustrates a state in which each component is freely stretched vertically upward so as to absorb heat deformation (length elongation due to temperature rise) as a specific embodiment of the present invention.

The coolant chamber 100 has a cylindrical shape (that is, a lower surface of the tube is enclosed in shape) that extends in the vertical direction and is opened in the upper part, and the lower surface is closed, and the lower portion is provided on the bottom surface of the core core 99 perforated in the ground. The face is fixed and the upper part protrudes to the ground.

The length of the cooling water chamber 100 is not particularly limited, but may range from several hundred meters to several thousand meters.

The coolant chamber 100 generally has a cylindrical shape, but is not necessarily limited to the cylindrical shape, and various cross sections may be used as necessary.

The coolant chamber 100 has a coolant supply port 110 at a lower side thereof and a coolant outlet 120 at an upper side of the coolant chamber 100.

That is, the cooling water introduced to the lower portion of the cooling water chamber 100 cools the external pipe 200 while the temperature rises, and the cooling water is discharged to the outside through the cooling water discharge port 120 provided at the upper portion of the cooling water chamber 100. do.

In addition, the cooling water supply port 110 is installed side by side in the vertical direction cooling water supply pipe 115 connected from the ground.

Cooling water chamber support 500 is composed of a support leg 510 and a guide 520, the support leg 510 is installed on the ground around the core 99, the guide 520 is the upper portion of the support leg 510 It is provided in the support for the outer surface protruding to the ground of the coolant chamber 100 which is raised and lowered by the thermal deformation so that the coolant chamber 100 is not inclined in any one direction.

That is, the guide 520 is not integrally coupled to the outer surface of the coolant chamber 100 but merely serves to support it.

The guide 520 may be in the form of a ring that completely surrounds the outer circumference of the coolant chamber 100, but is not necessarily limited thereto, and a portion of the outer surface of the coolant chamber 100 may be spaced at regular intervals. It may be in a form of support.

The first slip-shaped support 11 is installed to protrude toward the center of the core tablet 99 along the inner surface of the core tablet 99 perforated in the ground, and the outer surface of the coolant chamber 100 which is raised and lowered by thermal deformation. Support so that the coolant chamber does not tilt in either direction.

The cooling water chamber support unit 500 and the first slip-shaped support 11 are similar in function, but only one of the two may be provided, or both may be provided.

The outer pipe 200 has a tubular shape (that is, the lower end of the pipe is closed shape) which is opened in its entirety and the bottom surface is sealed and elongated in the vertical direction.

The closed lower surface of the outer pipe 200 is inserted through the upper portion of the coolant chamber 100 to reach the inner lower portion of the coolant chamber 100. The closed lower surface of the outer pipe 200 and the coolant chamber 100 are closed. The lower surface of the to maintain a spaced state, the upper end of the outer pipe 200 is installed to protrude to the upper portion of the cooling water chamber (100).

Here, the lower surface of the outer pipe 200 preferably maintains a gap of the lower surface of the cooling water chamber 100 and the maximum heat deformation length in the vertical direction of the outer pipe 200.

That is, even if the outer pipe 200 is stretched as much as possible, the lower surface of the outer pipe 200 should be spaced apart so as not to contact the lower surface of the cooling water chamber 100.

The upper one side of the outer pipe 200 is provided with a liquid waste outlet 210 serves as a passage for discharging the liquid waste is complete the wet oxidation reaction to the outside.

The outer pipe support 220 is provided at the lower portion of the liquid waste discharge port 210, it may be in the form of an annular band attached along the outer circumference of the outer pipe (200).

3 or 4, the coolant chamber 100 is provided with a coolant chamber upper unit 130 having a shape corresponding to the outer pipe support 220 along an upper edge of the upper pipe, as shown in FIG. Cooling chamber top group engaging portion 130 is integrally coupled to maintain watertightness.

That is, the lower surface of the outer pipe 200 is spaced apart from the lower surface of the coolant chamber 100 so that the outer pipe 200 is coupled to and mounted on the coolant chamber group unit 130. .

Therefore, when the heat deformation of the coolant chamber 100 occurs, the lower surface of the coolant chamber 100 is fixed to the bottom surface of the core core 99, so that the upper end of the coolant chamber 100 rises to thermal deformation, thereby causing external piping. 200 will also rise.

As such, when the outer pipe 200 rises, the distance between the lower surface of the outer pipe 200 and the lower surface of the coolant chamber 100 is farther away, thereby absorbing heat deformation of the outer pipe 200 ( Length) can be obtained more.

The inner pipe 300 is a tubular shape (that is, the upper end of the pipe is sealed) that is elongated in the vertical direction and the upper surface is sealed and the lower surface as a whole.

The lower end of the inner pipe 300 is inserted through the upper portion of the outer pipe 200 to reach the inner lower portion of the outer pipe 200, the lower end of the inner pipe 300 is spaced apart from the lower surface of the outer pipe 200 Maintaining the state, the closed upper surface of the inner pipe 300 is installed to protrude to the top of the outer pipe (200).

Here, the lower surface of the inner pipe 300 preferably maintains a gap greater than or equal to the maximum longitudinal deformation length of the lower surface of the outer pipe 200 and the inner pipe 300.

That is, even if the inner pipe 300 is stretched as much as possible, the lower surface of the inner pipe 300 should be spaced apart so as not to contact the lower surface of the outer pipe 200.

The upper one side of the inner pipe 300 is provided with a liquid waste supply port 310 serves as a passage through which the liquid waste to be wet oxidized is introduced.

The lower portion of the liquid waste supply port 310 may be provided with an inner pipe support 320 along an outer circumference of the inner pipe 300 in an annular band shape.

As shown in FIG. 3, the external pipe 200 has an external pipe group connection unit 230 having a shape corresponding to the internal pipe support unit along the upper edge thereof, and has an external pipe group connection unit 230 and an internal pipe support unit ( 320 is integrally combined to maintain watertightness (not shown separately, but similar to that of FIG. 4).

That is, the lower end of the inner pipe 300 is spaced apart from the bottom surface of the outer pipe 200, the inner pipe 300 is to be coupled to the outer pipe on the group 230 to be mounted.

Therefore, when the upper end of the external pipe 200 rises due to thermal deformation of the cooling water chamber 100 or the external pipe 200, the internal pipe 300 also rises together.

As such, when the inner pipe 300 rises, the distance between the lower surface of the inner pipe 300 and the lower surface of the outer pipe 200 is farther away, thereby absorbing heat deformation of the inner pipe 300 ( Length) can be obtained more.

The oxidant supply pipe 400 penetrates the upper surface of the inner pipe 300 and extends to the lower portion of the inner pipe 300 to supply the liquid waste oxidant introduced into the inner pipe 300 through the liquid waste supply port 310. It serves as a supply channel.

The lower end portion of the oxidant supply pipe 400 preferably maintains a gap between the lower surface of the outer pipe 200 and the maximum heat deformation length in the vertical direction of the oxidant supply pipe 400.

That is, even if the oxidant supply pipe 400 is extended as much as possible, the lower end of the oxidant supply pipe 400 should be spaced apart so as not to contact the lower surface of the outer pipe 200.

Liquid waste is mixed with the oxidizing agent in the lower portion of the inner pipe 300 to cause a wet oxidation reaction.

FIG. 5 separately illustrates the second slip support 22 provided on the outer surface of the outer pipe 200, and other components are not shown.

The second slip-shaped support 22 is installed to protrude toward the inner surface of the coolant chamber 100 along the outer surface of the outer pipe 200 so that the outer pipe 200 and the coolant chamber 100 which are lifted and lowered by heat deformation are formed. It serves as a spacer to maintain a proper distance from each other.

The specific shape of the second slip support 22 is not particularly limited, and a simple plate shape welded to the outer surface of the outer pipe 200 at regular intervals is sufficient.

The third slip-shaped support 33 is installed to protrude toward the inner surface of the outer pipe 200 along the outer surface of the inner pipe 300 so that the inner pipe 300 and the outer pipe 200 which are raised and lowered by heat deformation are formed. It serves as a spacer to maintain a proper distance from each other.

Also in the case of the third slip support 33, the specific shape is not particularly limited.

The fourth slip-shaped support 44 is installed to protrude toward the inner surface of the inner pipe 300 along the outer surface of the oxidant supply pipe 400 so that the lower and lower the oxidant supply pipe 400 and the inner pipe 300 by heat deformation. It serves as a spacer to maintain this proper interval.

Also in the case of the fourth slip support 44, the specific shape is not particularly limited.

Although specific embodiments of the present invention have been described in detail with reference to the accompanying drawings as described above, the scope of protection of the present invention is not necessarily limited to these embodiments, and various design changes within the scope of not changing the technical gist of the present invention. In addition, the addition or deletion of well-known technology, and simple numerical limitations also make it clear that they belong to the protection scope of the present invention.

1 illustrates a general wet oxidation system, in which liquid waste and oxygen (air) are supplied into a reactor to perform a wet oxidation reaction inside the reactor, and an oxide and a gas are separated and discharged to the outside. Shows.

Figure 2 shows the structure of the gravity wet oxidation reactor of the conventional gravity wet oxidation system, it shows that the means that can effectively absorb the thermal expansion is not presented in detail.

FIG. 3 illustrates a state in which each component is freely stretched vertically upward so as to absorb heat deformation (length elongation due to temperature rise) as a specific embodiment of the present invention.

Figure 4 is a separate view showing a coupling structure of the coolant chamber upper body unit 130 and the outer pipe support portion 220 formed along the upper edge of the coolant chamber 100, the illustration of the other components are omitted for convenience of understanding. It was.

FIG. 5 separately illustrates the second slip-shaped support 22 provided on the outer surface of the outer pipe 200, and other components are omitted for convenience of understanding. The third slip support 33 and the fourth slip support 44 have a similar structure and a separate illustration thereof is omitted.

<Description of the symbols for the main parts of the drawings>

100: cooling water chamber

110: cooling water supply port

115: cooling water supply pipe

120: cooling water outlet

130: Cooling water chamber award group association

200: external piping

210: liquid waste outlet

220: External piping support

230: Group connection on external piping

300: internal piping

310: liquid waste supply port

320: internal piping support

400: oxidant supply pipe

500: cooling water chamber support

510: support legs

520: Guide

11: 1st slip support

22: second slip support

33: third slip support

44: fourth slip support

99: heart

Claims (8)

As a gravity wet oxidation reactor capable of thermal deformation buffer, The upper surface is opened as a whole, the lower surface is sealed and elongated in the vertical direction, the lower surface is fixed to the bottom surface of the core core (99) perforated in the ground and the cooling water chamber 100 is protruded to the ground; As a whole, the upper part is opened, the lower surface is closed, and is elongated in the vertical direction, and the closed lower surface is inserted through the upper part of the cooling water chamber 100 so that the cooling water chamber ( An external pipe 200 which is spaced apart from the lower surface of the 100 and has an upper end protruding to an upper portion of the cooling water chamber 100; As a whole, the upper surface is sealed and the lower surface is open and elongated in the vertical direction, the lower end is inserted through the upper portion of the outer pipe 200, the outer pipe 200 in the inner lower portion of the outer pipe 200 Maintaining a state spaced apart from the lower surface of the, the closed upper surface is an inner pipe 300 is installed to protrude to the upper portion of the outer pipe (200); And, An oxidant supply pipe (400) extending through the upper surface of the inner pipe (300) and extending to a lower portion of the inner pipe (300) and serving as an oxidant supply passage; Consists of including The cooling water chamber 100 is provided with a cooling water supply port 110 on one side of the lower side and the cooling water discharge port 120 on the one side of the upper side, The upper one side of the outer pipe 200 is provided with a liquid waste outlet 210, the lower portion of the liquid waste outlet 210 is provided with an outer pipe support 220 along the outer circumference of the outer pipe 200. , An upper portion of the inner pipe 300 is provided with a liquid waste supply port 310, and a lower portion of the liquid waste supply port 310 is provided with an inner pipe support part 320 along an outer circumference of the inner pipe 300. Equipped, The coolant chamber upper group engaging portion 130 and the outer pipe support portion 220 formed along the upper edge of the coolant chamber 100 are coupled to maintain watertightness, Heat deformation buffered gravity wet oxidation reactor, characterized in that coupled to the outer pipe formed on the upper edge of the outer pipe 200, 230 and the inner pipe support portion 320 to maintain water tightness. In claim 1, A lower end portion connected to the cooling water supply port 110 and an upper end portion extending vertically along the cooling water chamber 100 to protrude to the ground; Gravity-type wet oxidation reactor capable of buffering heat, characterized in that it further comprises. The method of claim 1 or 2, A first slip-shaped support 11 installed to protrude toward the center of the core tablet 99 along the inner surface of the core tablet 99 perforated in the ground to support the outer surface of the coolant chamber 100 that is elevated by the thermal deformation. ); Gravity-type wet oxidation reactor capable of buffering heat, characterized in that it further comprises. The method of claim 1 or 2, A support leg 510 installed on the ground around the core 99 and an upper portion of the support leg 510 are provided to support the outer surface protruding to the ground of the coolant chamber 100 which is elevated by the heat deformation. A coolant chamber support part 500 formed of a guide 520; Gravity-type wet oxidation reactor capable of buffering heat, characterized in that it further comprises. The method of claim 1 or 2, It is installed to protrude toward the inner surface of the coolant chamber 100 along the outer surface of the outer pipe 200 to maintain a gap between the outer pipe 200 and the coolant chamber 100 which is raised and lowered by heat deformation. A second slip-shaped support 22; Gravity-type wet oxidation reactor capable of buffering heat, characterized in that it further comprises. The method of claim 1 or 2, It is installed to protrude toward the inner surface of the outer pipe 200 along the outer surface of the inner pipe 300 to maintain a gap between the inner pipe 300 and the outer pipe 200 which is raised and lowered by heat deformation. A third slip support 33; Gravity-type wet oxidation reactor capable of buffering heat, characterized in that it further comprises. The method of claim 1 or 2, It is installed to protrude toward the inner surface of the inner pipe 300 along the outer surface of the oxidant supply pipe 400 to maintain a gap between the oxidant supply pipe 400 and the inner pipe 300 which is raised and lowered by heat deformation. A fourth slip-shaped support 44; Gravity-type wet oxidation reactor capable of buffering heat, characterized in that it further comprises. The method of claim 1 or 2, The lower surface of the outer pipe 200 maintains a gap of the lower surface of the cooling water chamber 100 and the maximum heat deformation length in the vertical direction of the outer pipe 200, The lower end of the inner pipe 300 maintains a gap of the lower surface of the outer pipe 200 and the length of the maximum vertical deformation of the inner pipe 300 in the vertical direction, The lower end of the oxidant supply pipe 400 is a gravity wet oxidation capable of buffering heat deformation, characterized in that to maintain the interval between the lower surface of the outer pipe 200 and the vertical maximum heat deformation length of the oxidizer supply pipe 400. Reactor.

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