KR101041842B1 - System for inspecting performance of wet thermal insulation - Google Patents

Abstract

PURPOSE: A system for inspecting the performance of a wet insulation material is provided to prevent flowing fluid from being discharged to the outside through a temperature measurement unit. CONSTITUTION: A system(100) for inspecting the performance of a wet insulation material comprises a chamber(110), a flow path(150), a wet insulation material, and a temperature measurement unit. The chamber accepts a heating source. Flowing fluid flows in the flow path. The wet insulation material is arranged between the heating source and the flowing fluid and prevents heat from being transferred from the heating source to the flowing fluid. The temperature measurement unit measures the temperature of the flowing fluid.

Description

Wet Insulation Performance Inspection System {SYSTEM FOR INSPECTING PERFORMANCE OF WET THERMAL INSULATION}

The present invention relates to a wet insulation performance test system, and more particularly, by measuring the temperature change of the flow fluid is suppressed heat transfer by the heat source and the wet heat insulating material, a wet type that can inspect the thermal insulation performance of the wet heat insulating material against the fluid flowing A thermal insulation performance inspection system.

Integral pressurizer is in contact with the injection path of the pressurizer and the coolant of the reactor due to the characteristics of the unitary reactor, and there is a problem that the heat is continuously lost in the pressurizer due to the temperature difference between the contacted fluid. In order to minimize the heat exchange by placing the wet insulation between the fluid.

Wet heat insulating material is a heat insulating material configured to stack a plurality of iron plates spaced apart at a fine interval, and to arrange the water between the steel plates, to suppress the natural convection caused by the water as much as possible and to heat transfer only by heat conduction.

In the case of using such a wet heat insulating material, not only can the heat loss of the pressurizer be reduced, but also the stratification of water in the pressurizer is reduced. Reducing the heat loss of the pressurizer by the wet insulation material minimizes the size of the heater that is always driven, and can also reduce the rapid temperature change in the water surface of the pressurizer due to the reduction of stratification of water in the pressurizer.

Therefore, it is necessary to test the heat transfer characteristics of the wet insulation before the application to the reactor, and to test the performance of the insulation along with the necessity of the test and to simulate the environment of the wet insulation applied to the reactor is essential.

However, there is a need to develop a performance test system of a wet heat insulating material used for the purpose of suppressing heat transfer between a heat source and a fluid, in particular, a system capable of checking a temperature change characteristic in a flowing fluid.

Accordingly, an object of the present invention is to provide a wet insulation performance tester capable of inspecting the performance of a wet insulation material under conditions for suppressing heat transfer between a heat source and a flowing fluid.

The object is, according to the present invention, a chamber portion for receiving a heat source received therein; A flow path portion in which a flow path is formed to flow the fluid in a non-contact state with the heat source; A wet heat insulating material disposed between the heat source and the fluid to suppress heat transfer between the heat source and the fluid; It is achieved by a wet insulation performance test system comprising a; temperature measuring unit for measuring the temperature of the flow fluid.

In addition, the chamber part is partitioned, the heat source is accommodated in one region, the wet heat insulating material is disposed in the other region, the contact surface is formed on the opposite side on which the heat source is disposed based on the wet heat insulating material, the flow path portion is the contact surface It may be arranged to be in contact with the flow fluid.

In addition, the contact surface is one end surface in contact with the wet heat insulating material and the other end receiving plate is formed receiving portion; And a cover plate covering at least a portion of the accommodating part to seal the accommodating part space from the outside, wherein the temperature measuring part may be accommodated in a space of the accommodating part.

The temperature measuring unit may include a sensing unit accommodated in the accommodation unit to sense a temperature; Is configured in the form of a wire, one end is electrically connected to the sensing unit to receive the temperature information, and transmits the received temperature information to the outside through the other end, the flow fluid flowing along the sensing unit is not discharged to the outside It may include; a joint portion that is sealed at both ends of at least a portion so as to seal.

In addition, the joint portion may be sealed in a state where at least a portion of the joint is peeled off.

In addition, the sensing unit may be provided in a plurality spaced apart from each other along the flow direction of the flow fluid.

In addition, the sensing unit may be provided in a plurality spaced apart from each other along a direction perpendicular to the flow direction of the flow fluid.

In addition, the temperature measuring unit may be a thermocouple.

The apparatus may further include a pressure inducing member for generating a pressure difference to allow the flow fluid to flow in the flow path part.

In addition, the pressure inducing member may be a pressure pump.

According to the present invention, there is provided a wet insulation performance tester that can easily inspect the heat exchange blocking performance between the heat source and the fluid flowing with respect to any wet insulation.

In addition, the temperature measuring unit can be prevented from contacting the flow fluid to be the temperature measurement.

In addition, the portion of the temperature measuring unit connected to the external information processing device is sealed so that the fluid flow is not discharged to the outside through the temperature measuring unit.

In addition, by removing the coating of a part of the sealed portion of the temperature measuring unit, it is possible to prevent the fluid from being discharged to the outside by riding the electric wire in the coating.

1 is a perspective view of a wet insulation performance test system according to an embodiment of the present invention,
FIG. 2 is a cross-sectional view taken along the line II-II 'of the wet insulation performance test system of FIG.
3 is a perspective view of the chamber portion of the wet insulation performance test system of FIG.
Figure 4 is a bottom exploded perspective view of the chamber portion of the wet insulation performance test system of Figure 1,
5 is a cross-sectional view of the wet insulation of the wet insulation performance test system of FIG.
FIG. 6 is a view illustrating a sealing part of the wet insulation performance test system of FIG. 1;
7 is a perspective view of the flow path portion and the pressure inducing member of the wet insulation performance test system of FIG.
FIG. 8 illustrates the arrangement of the wet insulation performance inspection system of FIG. 1 in a direction perpendicular to the direction of gravity.

Hereinafter, the wet insulation performance test system 100 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a wet insulation performance test system according to an embodiment of the present invention, Figure 2 is a cross-sectional view taken along the line II-II 'of the wet heat insulation performance test system of FIG.

1 and 2, the wet insulation performance test system 100 according to an embodiment of the present invention may include a chamber unit 110, a wet insulation unit 130, a temperature measuring unit 140, and a flow path unit 150. And a pressure inducing member 160.

3 is a perspective view of a chamber portion of the wet insulation performance test system of FIG. 1, and FIG. 4 is a bottom exploded perspective view of the chamber portion of the wet insulation performance test system of FIG. 1.

Referring to FIG. 3, the chamber part 110 is mounted on the upper surface of the flow path part 150, which will be described later, so that the heat source 10 is separated from the flow fluid 20 flowing through the flow path part 150. As a member for accommodating, it is provided in the form of a rectangular parallelepiped in which an accommodating space is formed, and includes a sidewall surface 111, an upper surface 112, a contact surface 113, a cover surface 117, and a fixing portion 118 and a lower surface ( 121).

The side wall surface 111 is formed of four vertical surfaces to form an accommodating space therein, and is made of a transparent acrylic material so that the accommodating space inside the chamber part 110 can be seen from the outside of the chamber part 110. However, the present invention is not limited thereto.

The upper surface 112 is formed of a panel that protrudes from the inner and outer sides of the upper end portion of the side wall surface 111 by a predetermined length, respectively, and the center portion of the upper surface 112 is provided to penetrate through. Therefore, due to the region of the upper surface 112 penetrating the center of the receiving space formed inside the chamber 110 is not completely closed, but open, the performance of the wet insulation 130 by the cover surface 117 to be described later At the time of receiving the interior of the chamber 110 may be selectively sealed completely.

Referring to FIG. 4, the contact surface 113 is a member constituting an area in direct contact with the flow fluid, and includes a receiving plate 114 and a cover plate 116.

The receiving plate 114 is a plate-shaped member that is in contact with the lower surface of the wet heat insulating material 130 and the rear surface is in contact with the cover plate 116 to be described later, the receiving portion for receiving the sensing unit 141 ( 115 is formed to be recessed.

In the sensing unit 141 accommodated in the receiving unit 115, different types of metal wires 142 are bonded to each other at an end to form a junction 143, thereby receiving one sensing unit 141. The receiving part 115 is formed to be recessed into a space in which the joint part 143 and the pair of metal wires 142 can be inserted.

On the other hand, since the sensing unit 141 to be described later is to measure the temperature of the flow fluid 20 in the region where the junction 143 is located, in order to measure the temperature change of the flow fluid 20 flowing at different points On the receiving plate 114, a plurality of receiving portions 115 are provided.

On the receiving plate 114 of the present embodiment, a plurality of accommodating parts 115 are formed in a checkerboard-like arrangement, which is spaced apart from each other along a direction in which the flow fluid 20 flows and a direction perpendicular thereto, but the accommodating part 115 ) Is not limited thereto.

The cover plate 116 is a member sealing the rear surface of the receiving plate 114 so that the flow fluid 20 does not flow into the receiving portion 115 of the receiving plate 114.

On the other hand, the contact surface 113 including the receiving plate 114 and the cover plate 116 is made of a plate of a high thermal conductivity material, the thin so that heat exchange between the fluid 20 and the wet insulation 130 occurs well It is preferable that it is provided in plate shape of thickness.

The cover surface 117 is a member for sealing the receiving space of the chamber unit 110 from the outside by closing the through area of the upper surface.

The fixing part 118 is to fix the wet heat insulating material 130 disposed inside the chamber part 110 so as not to be separated from a predetermined position, and includes a length adjusting member 119 and a separation preventing member 120.

The length adjusting member 119 extends to the receiving space side through the upper surface 112 of the chamber part 110, is configured to be vertically adjustable in length, and is provided in a form that can be fixed at an arbitrary position.

The length adjusting member 119 in the present embodiment is configured in the form of a screw is fastened with the upper surface 112 of the chamber portion 110, so that it can move up and down in the rotational direction.

The detachment preventing member 120 is formed along the inner surface of the side wall surface 111 of the chamber part 110 in the longitudinal direction, and is disposed in contact with the lower surface of the length adjusting member 119. Therefore, the separation preventing member 120 may be maintained in a fixed state by the length adjusting member 119.

On the other hand, the fixing portion including the length adjusting member 119 and the separation prevention member 120 is provided so that a pair of opposing to the upper side of the wet heat insulating material (130).

The lower surface 121 extends outward from the edge of the contact surface 113 and is configured in a stepped shape, and the chamber part 110 is mounted on the flow path part 150 by being accommodated in the mounting part 151 which will be described later. Be sure to

The lower surface 121 is configured to cover both the contact surface 113 and the side wall surface 111 to prevent the flow fluid 20 from flowing into the space between the contact surface 113 and the side wall surface 111.

The wet heat insulating material 130 is provided in the receiving space in the chamber part 110, and the bottom surface of the wet heat insulating material 130 is disposed to contact the front surface of the cover plate 116, and is fixed by the upper fixing part 118. It is fixed in the chamber 110.

FIG. 5 illustrates a cross section of the wet insulation of the wet insulation performance testing system of FIG. 1.

Referring to FIG. 5A, the wet heat insulating material 130 includes a plurality of film members 131 and a heat insulating member 133 between the film members 131 spaced apart from each other.

The film member 131 maintains a separation distance from the neighboring film member 131 through the spacer member 132a which is formed to protrude, and is filled between the plurality of film members 131 and the film member 131 which are stacked. The heat insulating member 133 is combined to form a wet heat insulating material 130.

 At this time, the film member 131 may be a thin film stainless steel (Stainless-Steel) having excellent corrosion resistance and rigidity, and water may be used as the heat insulating member 133, but the film member 131 and the heat insulating member ( The material of 133 is not limited thereto.

The heat source 10 is accommodated in the space in the upper chamber part 110 of the wet heat insulator 130, the heat source 10 is maintained insulated with the flow fluid 20 by the wet heat insulator (130).

On the other hand, the spacer member 132a in the present embodiment is a projection-shaped spacer member 132a is formed integrally with the film member 131, referring to Figure 5 (b), in another modification separate spacer member The wet heat insulating material 130 may be configured in a form in which the 132 b is disposed between the film members 131.

A high temperature heat source fluid may be used as the heat source 10 accommodated in the chamber part 110, or a predetermined heating element capable of heating the upper surface of the wet heat insulating material may be used.

In this embodiment, a heat source 10 in the form of heating the heat source fluid 11 using a predetermined temperature control member 12 is used.

FIG. 6 is a view illustrating a sealing part of the wet insulation performance test system of FIG. 1.

4 and 6, the temperature measuring unit 140 is a member for measuring the thermal change of the wet heat insulating material 130 by measuring the temperature change of the flow fluid 20, the joint with the sensing unit 141 The part 144 and the sealing part 147 are included.

The sensing unit 141 is inserted into the receiving unit 115 of the receiving plate 114 to measure the temperature change of the flow fluid 20 at various positions, and is coated with different types of metal wires 142. And a thermocouple comprising a junction 143 where the pair of sheathed metal wires 142 are in contact with each other.

On the other hand, the sensing unit 141 provided in the form of a thermocouple measures the temperature of the fluid 20 at the junction 143 position, and is inserted and accommodated in the receiving portion 115 of the checkerboard arrangement described above.

The sensing unit 141 is inserted into the receiving unit 115 in the receiving plate 114, and the receiving plate 115 is closed by the cover plate 116 covering the receiving plate 114 to sense the flow fluid 20. Do not directly contact the portion 141.

The joint 144 is a medium for receiving the temperature information of the flow fluid 20 sensed by the sensing unit 141 and transmitting the temperature information to the outside. It consists of the uncovered area | region 146 which the copper wire is not coat | covered.

One end of the joint 144 covering region 145 is electrically connected to the opposite end where the junction 143 of the sensing unit 141 is located.

Meanwhile, one end of the uncovered area 146 is connected to the other end of the covered area 145, and the other end of the uncovered area 146 is electrically connected to an external information processing device to provide temperature information to the information processing device. Make it available.

At this time, the boundary portion between the covering area 145 and the uncovered area 146 of the joint 144 is sealed or sealed from the outside by the sealing part 147, which will be described later.

The sealing part 147 is for sealing a partial region of the above-described joint 144, and includes a housing 148 and a blocking part 149.

The housing 148 has a cylindrical shape and a space for accommodating the blocking portion 149 is formed therein, and the side wall surface 111 of the chamber portion 110 is not in contact with the flow fluid 20. Is attached to. Meanwhile, the joint 144 is disposed to pass through the inner space of the housing 148.

The blocking part 149 is configured to block the boundary between the covered area 145 and the uncovered area 146 of the joint 144 from the outside, and is accommodated in the housing 148.

That is, the joint 144 passes through the interior of the housing 148, and a boundary including a portion of the covering region 145 and the uncovered region 146 of the joint 144 is formed inside the housing 148. It is accommodated in the space and sealed from the outside by the blocking portion 149.

In the present exemplary embodiment, the blocking part 149 includes a part of the covering area 145 and the uncovered area 146 by filling the liquid silicon with the joint part 144 accommodated inside the housing 148 and curing the silicon. The joint 144 is blocked from the outside.

7 is a perspective view of the flow path portion and the pressure inducing member of the wet insulation performance test system of FIG.

Referring to FIG. 7, the flow path part 150 is a space in which the flow fluid 20 to be measured temperature flows, and a passage of the flow fluid 20 is formed therein and includes a tube having a rectangular cross section. do.

On the upper surface of the flow path part 150, a mounting part 151 to which the chamber part 110 is mounted is formed such that the contact surface 113 is in contact with the flow fluid 20. Therefore, the chamber part 110 is installed in the flow path part 150 through the mounting part 151, and the contact surface 113 of the chamber part 110 has a flow fluid 20 which flows inside the flow path part 150. Direct contact.

The pressure inducing member 160 causes a pressure difference at any two points in the flow path portion to cause forced flow of the fluid, and includes a pressure pump 161 and a circulation pipe 162.

The pressure pump 161 is attached to the end of the flow path portion 150 is a member for forcibly circulating the flow fluid 20 by receiving power.

One end of the circulation pipe 162 is connected to the pressure pump 161, and the other end of the circulation pipe 162 is connected to an end portion of the flow path part 150 so that the flow fluid 20 exiting the flow path part 150 again flows through the flow path part 150. It acts as a flow path to be circulated by flowing with).

According to the pressure inducing member 160 it is possible to induce a cyclic movement of the flow fluid in the flow path portion.

The operation of one embodiment of the wet insulation performance test system 100 described above will now be described.

First, in the present embodiment, a combination of a predetermined heat source fluid 11 and a temperature control member 12 for controlling the temperature of the heat source fluid 11 is used as the heat source 10, and the heat source 10 is a chamber part ( The operation of the wet insulation performance test system 100 as described above will be described.

The wet heat insulating material 130 is disposed in contact with the front surface of the receiving plate 114 of the chamber part 110, and the length adjusting member 119 is disposed after the release preventing member 120 is disposed above the wet heat insulating material 130. The wet insulating material 130 is fixed by pressing the release preventing member 120 downward.

The heat source fluid 11 is accommodated in the receiving space above the wet heat insulating material 130 in the chamber part 110, and the heat source 10 is installed by arranging the temperature regulating member 12 in the heat source fluid 11.

After the predetermined flow fluid 20 is injected into the flow path part 150, the chamber part 110 is mounted on the mounting part 151 of the flow path part 150 so that the contact surface 113 is in contact with the flow fluid 20. Let's do it. At this time, by fixing the chamber part 110 and the flow path part 150 using a separate fastening member, the chamber part 110 may be prevented from being separated from the flow path part 150 by an unintended external force.

By operating the pressure inducing member 160 to force the circulating fluid 20, the temperature of the heat source fluid 11 is changed by operating the temperature regulating member 12 above the wet insulator 130.

At this time, by measuring the temperature change of the fluid 20 using the sensing unit 141 arranged in the form of a checker board, and transmits such a temperature change information to the external processing device through the joint 144, and wet, The thermal insulation performance by the heat insulating material 130 can be inspected.

Meanwhile, the sensing unit 141 is inserted into the receiving unit 115 of the receiving plate 114 and the receiving unit 115 is closed by the cover plate 116, so that the sensing unit 141 in which the airtight state is maintained flows. Prevents direct contact with the fluid 20.

However, when the sealing plate 114 and the cover plate 116 are not completely sealed, the flow fluid 20 flows into the inside of the accommodating part 115 so that the sensing part 141 flows. It may be partially exposed to the fluid 20.

The flow fluid 20 may not only flow through the sheath of the thermocouple constituting the sensing unit 141 but also may enter the interior of the sheath and be transferred to the joint 144 through the metal wire.

The flow fluid delivered to the joint 144 by the outside of the coating is blocked by external discharge by a blocking part 149 made of silicon in the housing 148. In addition, since the part of the joint 144 is sealed by the shielding part 149 with the coating peeled off, even in the case of the fluid flowing through the inside of the coating from the sensing part, the external discharge is prevented by the blocking part 149. Can be blocked.

FIG. 8 illustrates the arrangement of the wet insulation performance inspection system of FIG. 1 in a direction perpendicular to the direction of gravity.

As described above, the chamber part 110 and the flow path part 150 may be disposed such that the contact surface 113 is parallel to the ground. However, as shown in FIG. 8, the chamber part 110 is perpendicular to the ground. By arranging and the flow path 150, the flow direction of the fluid 20 can be changed in various ways, so that the performance of the wet heat insulating material 130 can be inspected within various conditions.

The scope of the present invention is not limited to the above-described embodiment, but may be embodied in various forms of embodiments within the scope of the appended claims. Without departing from the gist of the invention claimed in the claims, it is intended that any person skilled in the art to which the present invention pertains falls within the scope of the claims described herein to various extents that can be modified.

100: wet insulation performance test system according to an embodiment of the present invention
10: heat source 140: temperature measuring unit
20: fluid fluid 141: sensing unit
110: chamber portion 144: joint portion
113: contact surface 147: sealing portion
130: wet insulation 150: flow path

Claims (10)

A chamber part accommodating a heat source accommodated therein;
A flow path portion in which a flow path is formed to flow the fluid in a non-contact state with the heat source;
A wet heat insulating material disposed between the heat source and the fluid to suppress heat transfer between the heat source and the fluid;
Wet insulation performance test system comprising a; temperature measuring unit for measuring the temperature of the fluid flow. The method of claim 1,
The chamber part is partitioned, the heat source is accommodated in one region and the wet heat insulating material is disposed in the other region, and includes a contact surface formed on the opposite side on which the heat source is disposed based on the wet heat insulating material,
The flow path portion is a wet insulation performance test system, characterized in that the contact surface is arranged so as to contact the flow fluid. The method of claim 2,
The contact surface is one end surface is in contact with the wet heat insulating material and the other end receiving plate is formed receiving portion; And a cover plate covering at least a portion of the accommodating part to seal the accommodating part space from the outside.
At least a portion of the temperature measuring part is accommodated in a space of the receiving part. The method of claim 3,
The sensing unit for sensing the temperature is accommodated in the receiving portion; Is configured in the form of a wire, one end is electrically connected to the sensing unit to receive the temperature information, and transmits the received temperature information to the outside through the other end, the flow fluid flowing along the sensing unit is not discharged to the outside A wet insulation performance test system comprising a; a joint portion that is sealed at both ends of at least a portion so as not to seal. The method of claim 4, wherein
The joint is at least a portion of the wet insulation material inspection system, characterized in that the covering is peeled off. The method according to claim 4 or 5,
The sensing unit is a wet insulation performance test system, characterized in that a plurality is provided spaced apart from each other along the flow direction of the flow fluid. The method according to claim 4 or 5,
The sensing unit is a wet insulation performance test system, characterized in that a plurality is provided spaced apart from each other along a direction perpendicular to the flow direction of the flow fluid. The method of claim 3,
The temperature measuring unit is a thermocouple (thermocouple) characterized in that the wet insulation performance test system. The method of claim 1,
And a pressure inducing member for generating a pressure difference to allow the flow fluid to flow in the flow path part. The method of claim 8,
The pressure inducing member is a wet insulation performance test system, characterized in that the pressure pump.

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