KR20210131490A - A test device and method for measuring average heat transfer coefficient reduction value of the heat transfer pipe - Google Patents

Abstract

The present invention provides a test device and a test method for measuring an average heat transfer coefficient reduction value of a heat transfer enhancement pipe unit, which efficiently improve heat transfer performance. The test device for measuring an average heat transfer coefficient reduction value of a heat transfer enhancement pipe unit comprises: an evaporation unit evaporating a working fluid; a condensation unit communicating with the evaporation unit to circulate the working fluid and condense the working fluid; a communication unit connecting the evaporation unit and the condensation unit; one or more heat transfer enhancement pipe units at least partially positioned in the condensation unit, and arranged to be separated from each other; a header unit communicating with both ends of the one or more heat transfer enhancement pipe units; a sensor unit installed on the one or more heat transfer enhancement pipe units and the condensation unit to sense the pressure, temperature, and flow of cooling water flowing into the header unit and the working fluid; a flow control unit installed on the one or more heat transfer enhancement pipe units to control the flow of the cooling water; and a cooling water supply unit supplying the cooling water to the header unit. The pressure, temperature, and flow of the cooling water sensed by the sensor unit are used to calculate a reduction value of an average heat transfer coefficient in accordance with the number of the one or more heat transfer enhancement pipe units.

Description

{A test device and method for measuring average heat transfer coefficient reduction value of the heat transfer pipe}

The present invention relates to a test apparatus and a test method for measuring the reduction value of the average heat transfer coefficient of the heat transfer pipe part, and more particularly, the average heat transfer of the heat transfer pipe part for calculating the reduction value of the average heat transfer coefficient according to the number of heat cut promoter parts It relates to a test apparatus and a test method for measuring the coefficient reduction value.

After the Fukushima nuclear accident in which the cooling function of the nuclear reactor was lost for a long time due to the shutdown of the external power supply caused by the great northeast earthquake and tsunami in Japan, and a large amount of radioactive material was released to the outside, the importance of mitigating the nuclear accident by containment evacuation is important. emerged as an issue.

The passive containment cooling system is a passive electric system to remove the energy released to the containment vessel through condensed heat transfer and maintain the integrity of the nuclear power plant in the event of an accident such as loss of coolant or breakage of the chief complaint engine. In a Korean nuclear power plant that employs a concrete containment vessel, a heat exchanger composed of a separate vertical tube bundle is installed inside the containment vessel and a cooling water tank is installed outside the containment building to cool the containment vessel using natural circulation. .

Atmospheric pressure air exists inside the containment vessel, and in the event of a nuclear reactor accident, the vapor released from the reactor coolant system mixes with the containment air to form a gas mixture. In addition, if the core cooling fails, when the cladding surrounding the nuclear fuel reacts with high-temperature steam, hydrogen, a combustible gas, is generated and accumulated at the top of the containment vessel.

Inside the containment vessel, steam is discharged from the bottom and condensed and cooled on the outer wall of the condensing pipe of the passive containment cooling system at the top to form a natural circulation flow of the gas mixture. When non-condensable gases such as air or hydrogen are mixed with steam, they accumulate in a high fraction around the condensing tube and act as a large thermal resistance, reducing the condensing heat transfer.

Existing experimental studies on condensing heat transfer are mostly focused on condensation occurring on the inner wall of a vertical tube or condensation occurring on the inner and outer walls of a horizontal tube. On the other hand, experimental equipment in which the vapor-air mixture is condensed on the surface of the condensing tube according to the vertical or angle, such as the condensing tube of the cooling system of the passive containment, is found very limited.

In the existing experimental devices, steam was generated by evaporating water using an electric heater at the bottom of a long cylindrical pressure vessel, and cooling water was injected into the vertical cooling tube inside the pressure vessel to form a cold outer wall temperature condition. The steam generated at the bottom of the pressure vessel is mixed with the non-condensable gas present at the top or injected from the outside to form a gas mixture, and the inside of the pressure vessel is naturally circulated. The vapor of the gas mixture condenses on the outer wall of the cold condensing tube to form a liquid film, which flows down the condensing tube by gravity and is collected at the bottom of the pressure vessel. The amount of steam generated in the pressure vessel and the amount of steam condensed on the outer wall of the condensing tube to change phase are balanced, and the conditions inside the pressure vessel form a steady state.

In general, the method of evaluating the performance of a heat transfer tube based on one heat transfer tube is mainly used.

In addition, the bundle effect, which is a decrease in the average heat transfer coefficient according to the number of heat transfer tubes in the vertical direction, is known to decrease the average outer heat transfer coefficient as the number of heat transfer tubes in the lower direction increases in the case of the heat transfer tubes arranged in the vertical direction.

Therefore, it is necessary to accurately know the reduction value, which is the degree of decrease in the outer heat transfer coefficient according to the number of heat transfer in the vertical direction for each heat transfer accelerator.

(Patent Document 1) Registered Patent Publication No. 10-1557317 (2015.09.25.)

(Patent Document 2) Registered Patent Publication No. 10-0675479 (Jan. 22, 2007)

It is an object of the present invention to solve the above problems by calculating the reduction value of the average heat transfer coefficient based on information obtained by installing at least one heat transfer facilitating tube part perpendicular to the condensing part and a sensor part in the condensing part, so that more efficient heat transfer It is to provide a test apparatus and test method for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerating tube part that improves the performance.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. There will be.

The configuration of the present invention for achieving the above object is an evaporator for evaporating the working fluid; a condensing unit communicating with the evaporator to circulate the working fluid and condensing the working fluid; a communication unit for communicating the evaporator and the condensing unit; at least one heat transfer facilitating tube part, at least a portion of which is located inside the condensing part and disposed to be spaced apart from each other; a header portion communicating with both ends of the at least one heat transfer facilitating tube portion; a sensor unit installed in the at least one heat transfer promoting tube unit and the condensing unit to sense the pressure, temperature, and flow rate of the working fluid and cooling water flowing into the header unit; a flow rate control unit installed in the at least one heat transfer promoting tube unit to adjust a flow rate of the cooling water; and a cooling water supply unit for supplying the cooling water to the header unit, using the pressure, temperature, and flow rate of the cooling water sensed by the sensor unit. It provides a test device for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerator part, characterized in that for calculating

In an embodiment of the present invention, the average heat transfer coefficient is,

은 평균열전달계수,

은 전열촉진관부의 개수,

,

는 온도,

는 특성길이,

는 질량,

,

는 밀도,

는 경막 열전달계수,

는 점성계수)의 수식에 의해 계산되는 것을 특징으로 할 수 있다.(

is the average heat transfer coefficient,

is the number of heat transfer facilitating tube parts,

,

is the temperature,

is the characteristic length,

is the mass,

,

is the density,

is the dural heat transfer coefficient,

may be characterized in that it is calculated by the formula of the viscosity coefficient).

In an embodiment of the present invention, the at least one heat transfer accelerating tube portion may be arranged to be perpendicular to the standing condensing portion.

In an embodiment of the present invention, the condensing unit includes: a condenser body configured to receive the evaporating gas evaporated in the evaporator and condensed into condensed water; an evaporative gas inlet in communication with an upper portion of the condenser body through which the evaporating part and the evaporating gas passing through the communicating part are introduced; a condensate receiving unit communicating with a lower portion of the condenser body to receive the condensed water; and a confirmation window formed in a central axis direction of the condenser body and made of a permeable material perpendicular to the at least one heat transfer accelerating tube portion.

In an embodiment of the present invention, the communication unit includes a first communication member for communicating the evaporator and the evaporative gas inlet, and the first communication member transfers the evaporator moving from the evaporator to the evaporator. It may be characterized by moving to the inlet.

In an embodiment of the present invention, the communication unit includes a second communication member for communicating the evaporator and the condensed water accommodating unit, and the second communication member is moved from the condensed water accommodating unit and accommodated in the condensed water receiving unit. It may be characterized in that the condensed water is moved to the evaporator.

In an embodiment of the present invention, the header portion may include: an inlet header having one end communicating with the cooling water supply unit and communicating with one end of the at least one heat transfer facilitating tube portion; an inlet formed at one side of the inlet header through which the cooling water is introduced; an outlet header communicating with the other end of the at least one heat transfer pipe unit; and an outlet formed at one side of the outlet header through which the cooling water is discharged, wherein the inlet header introduces the cooling water supplied from the cooling water supply unit through the suction port into the at least one heat transfer pipe facilitating tube, and the outlet The header may discharge the cooling water flowing in from the at least one heat transfer pipe facilitating tube part to the outlet.

In an embodiment of the present invention, the sensor unit may include: at least one flow meter installed in the at least one heat transfer pipe unit to measure a flow rate of the cooling water flowing into the at least one heat transfer pipe unit; It is installed in the evaporative gas inlet part and the at least one heat transfer facilitating tube part to measure the temperature of the evaporating gas inside the evaporative gas inlet part and the temperature of the cooling water flowing into the at least one heat transfer facilitating tube part. one thermometer; and a pressure gauge installed in the evaporative gas inlet to measure the pressure of the evaporating gas inside the evaporating gas inlet, wherein two thermometers among the at least one thermometer are at both sides of the at least one heat transfer facilitating tube part It may be installed in the at least one heat transfer promoting tube to measure the temperature of the cooling water at the inlet and the outlet.

On the other hand, the configuration of the present invention for achieving the above object comprises the steps of: (a) evaporating the working fluid by the evaporator to change the phase into evaporative gas; (b) at least one heat transfer facilitating pipe unit is supplied from the cooling water supply unit, and the cooling water passing through the inlet header is moved to the outlet header; (c) condensing the evaporator gas supplied from the evaporator by a condensing unit to change the phase to condensed water; (d) sensing the pressure, temperature, and flow rate of the working fluid and the coolant flowing into the inlet header and the outlet header by a sensor installed in the at least one heat transfer facilitating tube portion and the condensing portion; and (e) the evaporator receiving the condensed water; and an average heat transfer coefficient according to the number of the at least one heat transfer facilitating tube unit using the pressure, temperature and flow rate of the cooling water sensed by the sensor unit. It provides a test method for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerator part, characterized in that the reduction value is calculated.

In an embodiment of the present invention, the average heat transfer coefficient is,

은 평균열전달계수,

은 전열촉진관부의 개수,

,

는 온도,

는 특성길이,

는 질량,

,

는 밀도,

는 경막 열전달계수,

는 점성계수)의 수식에 의해 계산되는 것을 특징으로 할 수 있다.(

is the average heat transfer coefficient,

is the number of heat transfer facilitating tube parts,

,

is the temperature,

is the characteristic length,

is the mass,

,

is the density,

is the dural heat transfer coefficient,

may be characterized in that it is calculated by the formula of the viscosity coefficient).

In an embodiment of the present invention, the step (d) includes: (d1) receiving the cooling water from the cooling water supply unit by the intake header; (d2) moving the cooling water supplied from the inlet header to the outlet header by the at least one heat transfer accelerator; and (d3) discharging, by the outlet header, the cooling water supplied from the at least one heat transfer facilitating tube part to the outside.

The effect of the present invention according to the above configuration is more efficient heat transfer performance by calculating the reduction value of the average heat transfer coefficient based on information obtained by installing at least one heat transfer facilitating tube part perpendicular to the condensing part and the sensor part in the condensing part. can improve

It should be understood that the effects of the present invention are not limited to the above-described effects, and include all effects that can be inferred from the configuration of the invention described in the detailed description or claims of the present invention.

1 is a conceptual diagram illustrating a test apparatus for measuring an average heat transfer coefficient decrease value of a heat transfer accelerator part according to an embodiment of the present invention.
FIG. 2 is a view showing the flow of the working fluid and cooling water of FIG. 1 .
3 is a graph necessary when designing or evaluating a condensing unit using a test apparatus for measuring an average heat transfer coefficient reduction value of a heat transfer accelerator according to an embodiment of the present invention.
4 (a), (b), and (c) are diagrams showing the number of heat transfer accelerator tube parts of a test apparatus for measuring the average heat transfer coefficient decrease value of the heat transfer tube part according to an embodiment of the present invention. .
5 is a graph exemplarily showing an average heat transfer coefficient according to the number of heat transfer accelerator tube parts of a test apparatus for measuring an average heat transfer coefficient decrease value of a heat transfer pipe part according to an embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be embodied in several different forms, and thus is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part is said to be “connected (connected, contacted, coupled)” with another part, it is not only “directly connected” but also “indirectly connected” with another member interposed therebetween. "Including cases where In addition, when a part "includes" a certain component, this means that other components may be further provided without excluding other components unless otherwise stated.

The terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In this specification, terms such as "comprises" or "have" are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

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

1 is a conceptual diagram illustrating a test apparatus for measuring an average heat transfer coefficient reduction value of a heat transfer accelerator part according to an embodiment of the present invention. FIG. 2 is a view showing the flow of the working fluid and cooling water of FIG. 1 .

The test apparatus 100 for measuring the reduction value of the average heat transfer coefficient of the heat transfer pipe unit according to an embodiment of the present invention includes an evaporation unit 110 , a condensing unit 120 , a communication unit 130 , and a heat transfer pipe unit 140 . , a header unit 150 , a sensor unit 160 , a flow rate control unit 170 , and a cooling water supply unit 180 , and at least one It is characterized in that the reduction value of the average heat transfer coefficient according to the number of heat transfer facilitating tube parts 140 is calculated.

The evaporator 110 is a device for refrigeration by heat absorption by liquid evaporation by introducing a liquid refrigerant decompressed to low temperature and low pressure through an expansion valve and exchanging heat with a surrounding space or an object to be cooled. evaporate.

In particular, the present invention can be used as the test apparatus 100 for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerator for refrigerant condensation.

For this, the upper and side portions of the evaporator 110 communicate with the communication unit 130 as shown in FIGS. 1 and 2 .

The working fluid F in the evaporator 110 is vaporized by the evaporator 110 and phase-changed into evaporative gas and moves to the condensing unit 120 along the communication unit 130 .

In addition, the evaporative gas introduced into the condensing unit 120 is phase-changed into condensed water by the condensing unit 120 and moves to the evaporating unit 110 through the communication unit 130 .

The condensing unit 120 is a device for condensing and condensing the steam by cooling the steam, and communicates with the evaporator 110 to circulate the working fluid (F) and condense the working fluid (F).

For this purpose, the condensing unit 120 includes a condenser body 121 , an evaporative gas inlet 122 , a condensed water receiving unit 123 , and a confirmation window 124 .

The condenser body 121 may be a condenser used in general, and receives the vaporized gas evaporated from the evaporator 110 and condenses it into condensed water.

The evaporative gas inlet 122 communicates with the upper portion of the condenser body 121 , and the evaporative gas passing through the evaporator 110 and the communicating part 130 is introduced. For this purpose, the evaporative gas inlet 122 is formed to correspond to the condenser body 121 and is coupled to the upper portion of the condenser body 121 .

In addition, the upper portion of the evaporative gas inlet 122 is connected to communicate with the communication unit 130 .

The condensate accommodating part 123 communicates with the lower part of the condenser body 121 to receive condensed water. For this purpose, the condensate receiving part 123 is formed to correspond to the condenser body 121 and is coupled to the lower portion of the condenser body 121 .

In addition, the lower portion of the condensed water accommodating part 123 is connected to communicate with the communication part 130 .

The confirmation window 124 is formed of a central axis of the condenser body 121 and may be made of a permeable material perpendicular to the at least one heat transfer facilitating tube 140. Accordingly, the operator can also check the window ( Through 124), it can be visually confirmed whether the evaporator is condensed with condensed water inside the condenser body 121 .

The communication unit 130 communicates with the evaporator 110 and the condensing unit 120 , and through this, the working fluid F, the evaporating gas, and the condensed water circulate between the evaporating unit 110 and the condensed water 120 . .

The communication part 130 includes a first communication member 131 and a second communication member 132 .

The first communication member 131 communicates with the evaporator 110 and the evaporator gas inlet 122 . Specifically, one end of the first communication member 131 communicates with the upper portion of the evaporator 110 , and the other end of the first communication member 131 communicates with the upper portion of the evaporator gas inlet 122 .

The first communication member 131 serves to move the evaporating gas moving from the evaporator 110 to the evaporating gas inlet 122 .

The second communication member 132 communicates with the evaporator 110 and the condensed water accommodating part 123 . Specifically, referring to FIGS. 1 and 2 , one side of the second communication member 132 communicates with the side of the evaporator 110 , and the other side of the second communication member 132 is the side of the condensate receiving unit 123 . communicate with

The second communication member 132 moves from the condensed water accommodating part 123 to move the condensed water accommodated in the condensed water accommodating part 123 to the evaporating part 110 .

At least a portion of the heat transfer accelerating tube 140 is located inside the condensing unit 120 and is disposed to be spaced apart from each other. Referring to FIGS. 1 and 2 , the heat transfer accelerating tube unit 140 may be disposed perpendicular to the standing condensing unit 120 , and at least one may be formed.

At least one heat transfer facilitating tube unit 140 is disposed to be spaced apart from each other by a predetermined distance, and preferably may be spaced apart from each other at equal intervals.

In addition, both ends of the at least one heat transfer facilitating tube unit 140 are coupled to and communicate with the header unit 150 .

The at least one heat transfer accelerating tube unit 140 is arranged to be perpendicular to the standing condensing unit 120 .

The header unit 150 communicates with both ends of the at least one heat transfer promoting tube unit 140 . The header unit 150 includes an inlet header 151 , an inlet 152 , an outlet header 153 , and an outlet 154 .

One side of the inlet header 151 communicates with the cooling water supply unit 180 to communicate with one end of the at least one heat transfer promoting pipe unit 140 . The inlet header 151 introduces the cooling water supplied from the cooling water supply unit 180 through the suction port 152 into the at least one heat transfer tube facilitating tube unit 140 .

The inlet 152 is formed on one side of the inlet header 151 and is an inlet through which the coolant flows.

The outlet header 153 communicates with the other end of the at least one heat transfer promoting tube 140 . The outlet header 153 discharges the coolant flowing in from the at least one heat transfer pipe facilitating tube 140 to the outlet 154 .

The outlet 154 is formed on one side of the outlet header 153 and is an outlet through which the coolant is discharged.

The sensor unit 160 is installed in at least one heat transfer accelerating tube unit 140 and the condensing unit 120 to sense the pressure, temperature, and flow rate of the working fluid F and the coolant flowing into the header unit 150 . The sensor unit 160 for this purpose includes a flow meter 161 , a thermometer 162 , and a pressure gauge 163 .

The flow meter 161 is installed in the at least one heat transfer pipe unit 140 to measure the flow rate of the coolant flowing into the at least one heat transfer pipe unit 140 . Specifically, as shown in FIGS. 1 and 2 , the flow meter 161 is installed at the other end of the at least one heat transfer facilitating tube 140 to sense and measure the flow rate of the coolant.

The thermometer 162 is installed in the evaporative gas inlet 122 and at least one heat transfer facilitating tube 140 to determine the temperature of the evaporating gas in the evaporating gas inlet 122 and at least one heat transfer facilitating tube 140. Measure the temperature of the coolant flowing into the

Specifically, any one of the at least one thermometer 162 may be installed above the evaporative gas inlet 122 .

In addition, two thermometers 162 of the at least one thermometer 162 are installed on both sides of the at least one heat transfer pipe unit 140 to measure the temperature of the cooling water at the inlet and outlet of the at least one heat transfer pipe unit 140 . measure

The pressure gauge 163 is installed in the evaporator inlet 122 to measure the pressure of the evaporator in the evaporator inlet 122 .

The flow rate control unit 170 is installed in the at least one heat transfer promoting pipe unit 140 to adjust the flow rate of the cooling water.

The cooling water supply unit 180 may be, for example, a water pump, and supplies cooling water to the header unit 150 .

An average heat transfer coefficient is calculated based on the information obtained according to the above components.

The average heat transfer coefficient may be calculated by the following [Equation 1].

[Equation 1]

은 평균열전달계수,

은 전열촉진관부의 개수,

,

는 온도,

는 특성길이,

는 질량,

,

는 밀도,

는 경막 열전달계수,

는 점성계수)(

is the average heat transfer coefficient,

is the number of heat transfer facilitating tube parts,

,

is the temperature,

is the characteristic length,

is the mass,

,

is the density,

is the dural heat transfer coefficient,

is the viscosity coefficient)

3 is a graph necessary when designing or evaluating a condensing unit using a test apparatus for measuring an average heat transfer coefficient reduction value of a heat transfer pipe part according to an embodiment of the present invention. In general, according to the number of heat transfer pipe parts in the vertical direction It represents the average heat transfer number.

The refrigerant gas flowing into the condensing unit 120 starts condensing while meeting at least one heat transfer facilitating tube unit 140 inside the condensing unit 120, and is condensed in the uppermost at least one heat transfer accelerating tube unit 140 The refrigerant liquid falls onto the heat transfer facilitating tube 140 located at the bottom.

Accordingly, the average heat transfer coefficient of the heat transfer facilitating tube 140 at the lower portion tends to decrease due to the refrigerant liquid falling from the upper portion.

4 (a), (b), and (c) are diagrams showing the number of heat transfer accelerator tube parts of a test apparatus for measuring the average heat transfer coefficient decrease value of the heat transfer tube part according to an embodiment of the present invention. .

If you look at the figure 'Example of the number of heat transfer tubes in the vertical direction', it shows the case where there are 2 to 4 heat transfer tubes in the vertical direction. At this time, if Equation 1 or a graph, which is a correlation expression that can represent the average heat transfer coefficient according to the number of heat transfer tubes arranged in the vertical direction, is included, it can be used when evaluating and designing the condensing unit.

5 is a graph exemplarily showing an average heat transfer coefficient according to the number of heat transfer accelerator tube parts of a test apparatus for measuring an average heat transfer coefficient decrease value of a heat transfer pipe part according to an embodiment of the present invention.

As shown in FIG. 5 , it can be confirmed that the average heat transfer coefficient tends to decrease as the number of heat transfer facilitating tube parts increases.

Accordingly, the reduction value (bundle effect) of the average heat transfer coefficient is calculated by subtracting the smaller heat transfer coefficient from the larger average heat transfer coefficient among the two average heat transfer coefficients shown in FIG. 5 .

Hereinafter, a test method for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerator part according to an embodiment of the present invention will be described.

The test method for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerating tube part according to an embodiment of the present invention includes the steps of (a) the evaporator 110 evaporating the working fluid F to change the phase into evaporative gas, (b) ) at least one heat transfer facilitating pipe unit 140 is supplied from the cooling water supply unit 180 to move the cooling water (W) passing through the inlet header 151 to the outlet header 152, (c) the condensing unit 120 The step of condensing the evaporator gas supplied from the temporary evaporator 110 and changing the phase to condensed water, (d) at least one heat transfer facilitating tube 140 and the sensor unit 160 installed in the condensing unit 120 are the working fluid (F) and the step of sensing the pressure, temperature and flow rate of the coolant flowing into the inlet header 151 and the outlet header 152, and (e) the evaporator 110 receiving the condensed water 120, and , a decrease value of the average heat transfer coefficient according to the number of the at least one heat transfer facilitating tube unit 140 is calculated using the pressure, temperature, and flow rate of the cooling water W sensed by the sensor unit 160 .

The average heat transfer coefficient is calculated by [Equation 1] as described above.

In the step (d), (d1) the intake header 151 receives cooling water from the cooling water supply unit 180, (d2) the at least one heat transfer facilitating tube unit 140 is supplied with the cooling water from the intake header 151 (W) moving to the outlet header 152, and (d3) the outlet header 152 discharging the coolant (W) supplied from the at least one heat transfer facilitating pipe unit 140 to the outside.

According to the present invention as described above, it is possible to visually confirm whether the condensation of the evaporative gas is made from the outside through the transparent confirmation window.

In addition, the present invention calculates the average heat transfer coefficient by obtaining the main factors necessary in [Equation 1] for calculating the reduction value of the average heat transfer coefficient, and as shown in FIG. 5 , the larger of the two average heat transfer coefficients The decrease in the average heat transfer coefficient (bundle effect) is calculated by subtracting the small heat transfer coefficient from the average heat transfer coefficient.

Accordingly, the present invention can improve more efficient heat transfer performance based on the calculated reduction value of the average heat transfer coefficient.

The above description of the present invention is for illustration, and those of ordinary skill in the art to which the present invention pertains can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a dispersed form, and likewise components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention.

100: Test device for measuring the reduction value of the average heat transfer coefficient of the heat transfer pipe part
110: evaporator
120: condensing unit
121: condenser body
122: evaporative gas inlet
123: condensate receiver
124: confirmation window
130: communication unit
131: first communication member
132: second communication member
140: heat transfer promotion tube part
150: header part
151: inlet header
152: intake
153: outlet header
154: outlet
160: sensor unit
161: flow meter
162: thermometer
163: pressure gauge
170: flow control unit
180: coolant supply

Claims (11)

an evaporator for evaporating the working fluid;
a condensing unit communicating with the evaporator to circulate the working fluid and condensing the working fluid;
a communication unit for communicating the evaporator and the condensing unit;
at least one heat transfer facilitating tube part, at least a portion of which is located inside the condensing part and disposed to be spaced apart from each other;
a header portion communicating with both ends of the at least one heat transfer promoting tube portion;
a sensor unit installed in the at least one heat transfer promoting tube unit and the condensing unit to sense the pressure, temperature, and flow rate of the working fluid and cooling water flowing into the header unit;
a flow rate control unit installed in the at least one heat transfer facilitating tube unit to adjust a flow rate of the cooling water; and
a cooling water supply unit supplying the cooling water to the header unit;
The average heat transfer coefficient reduction value of the heat transfer accelerator tube part, characterized in that the reduction value of the average heat transfer coefficient according to the number of the at least one heat transfer accelerator tube part is calculated using the pressure, temperature, and flow rate of the coolant sensed by the sensor part Test equipment for measurement.
According to claim 1,
The average heat transfer coefficient is,

(

is the average heat transfer coefficient,

is the number of heat transfer facilitating tube parts,

,

is the temperature,

is the characteristic length,

is the mass,

,

is the density,

is the dural heat transfer coefficient,

is the viscosity coefficient)
A test apparatus for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerator part, characterized in that it is calculated by the formula of
According to claim 1,
The at least one heat transfer accelerator tube portion is a test apparatus for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerator tube portion, characterized in that it is arranged to be perpendicular to the standing condensing portion.
According to claim 1,
The condensing unit,
a condenser body receiving the vaporized gas evaporated from the evaporator and condensing it into condensed water;
an evaporative gas inlet in communication with an upper portion of the condenser body through which the evaporating part and the evaporating gas passing through the communicating part are introduced;
a condensate receiving unit communicating with a lower portion of the condenser body to receive the condensed water; and
A test apparatus for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerator tube, characterized in that it comprises a; .
5. The method of claim 4,
The communication unit includes a first communication member for communicating the evaporation unit and the evaporation gas inlet;
The first communication member is a test apparatus for measuring the reduction value of the average heat transfer coefficient of the heat transfer facilitating tube, characterized in that the evaporating gas moving from the evaporating part is moved to the evaporating gas inlet.
5. The method of claim 4,
The communication unit includes a second communication member for communicating the evaporator and the condensed water accommodating unit;
The second communication member moves from the condensed water receiving unit to move the condensed water accommodated in the condensed water receiving unit to the evaporating unit.
According to claim 1,
The header part,
an inlet header having one side communicating with the cooling water supply unit and communicating with one end of the at least one heat transfer facilitating tube unit;
an inlet formed at one side of the inlet header through which the cooling water is introduced;
an outlet header communicating with the other end of the at least one heat transfer pipe unit; and
and an outlet formed on one side of the outlet header through which the cooling water is discharged;
the inlet header introduces the cooling water supplied from the cooling water supply unit through the suction port into the at least one heat transfer pipe facilitating pipe unit;
and the outlet header discharges the cooling water flowing in from the at least one heat transfer pipe accelerator to the outlet.
5. The method of claim 4,
The sensor unit,
at least one flow meter installed in the at least one heat transfer pipe unit to measure a flow rate of the cooling water flowing into the at least one heat transfer pipe unit;
It is installed in the evaporative gas inlet part and the at least one heat transfer facilitating tube part to measure the temperature of the evaporating gas inside the evaporative gas inlet part and the temperature of the cooling water flowing into the at least one heat transfer facilitating tube part. one thermometer; and
a pressure gauge installed in the evaporative gas inlet to measure the pressure of the evaporating gas inside the evaporating gas inlet;
Two thermometers among the at least one thermometer are installed on both sides of the at least one heat transfer accelerator part to measure the temperature of the cooling water at the inlet and outlet of the at least one heat transfer accelerator part. A test device for measuring the mean heat transfer coefficient reduction value.
(a) evaporating the working fluid by the evaporator to change the phase into evaporative gas;
(b) at least one heat transfer facilitating pipe unit is supplied from the cooling water supply unit, and the cooling water passing through the inlet header is moved to the outlet header;
(c) condensing the evaporator gas supplied from the evaporator by a condensing unit to change the phase to condensed water;
(d) sensing the pressure, temperature, and flow rate of the working fluid and the coolant flowing into the inlet header and the outlet header by a sensor installed in the at least one heat transfer facilitating tube portion and the condensing portion; and
(e) receiving the condensed water by the evaporator; including,
The average heat transfer coefficient reduction value of the heat transfer accelerator tube part, characterized in that the reduction value of the average heat transfer coefficient according to the number of the at least one heat transfer accelerator tube part is calculated using the pressure, temperature, and flow rate of the coolant sensed by the sensor part Test method for measurement.
10. The method of claim 9,
The average heat transfer coefficient is,

(

is the average heat transfer coefficient,

is the number of heat transfer facilitating tube parts,

,

is the temperature,

is the characteristic length,

is the mass,

,

is the density,

is the dural heat transfer coefficient,

is the viscosity coefficient)
A test apparatus for measuring the reduction value of the average heat transfer coefficient of the heat transfer accelerator part, characterized in that it is calculated by the formula of
10. The method of claim 9,
Step (d) is,
(d1) the intake header receiving the cooling water from the cooling water supply unit;
(d2) moving the cooling water supplied from the inlet header to the outlet header by the at least one heat transfer accelerator; and
(d3) the outlet header discharging the cooling water supplied from the at least one heat transfer pipe unit to the outside;

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