CN112146494B - Rotational symmetry's control by temperature change vibration loop heat pipe - Google Patents

Abstract

The invention provides a loop heat pipe which comprises a middle evaporation pipe, a left collecting pipe, a right collecting pipe and a pipe group, wherein the pipe group comprises the left pipe group and the right pipe group; the loop heat pipe is internally provided with a temperature sensing element for detecting the temperature inside the loop heat pipe, the temperature sensing element is in data connection with the controller, and the controller controls whether the heat source heats or not according to the detected temperature. Thereby controlling stack vibration. The loop heat pipe can judge whether the loop heat pipe reaches a stable state or not according to the internal temperature, and then intelligently controls the heating of the heat source according to the internal temperature, so that the internal fluid can realize frequent vibration, and good descaling and heating effects are realized.

Description

Rotational symmetry's control by temperature change vibration loop heat pipe

Technical Field

The invention relates to a loop heat pipe, in particular to an elastic vibration descaling loop heat pipe.

Background

The heat pipe technology is a heat transfer element called a heat pipe invented by George Grover (George Grover) of national laboratory of Los Alamos (Los Alamos) in 1963, fully utilizes the heat conduction principle and the rapid heat transfer property of a phase change medium, quickly transfers the heat of a heating object to the outside of a heat source through the heat pipe, and the heat conduction capability of the heat transfer element exceeds the heat conduction capability of any known metal.

The heat pipe technology is widely applied to the industries of aerospace, military industry and the like, and since the heat pipe technology is introduced into the radiator manufacturing industry, the design idea of the traditional radiator is changed for people, the single heat radiation mode that a high-air-volume motor is used for obtaining a better heat radiation effect is avoided, the heat pipe technology is adopted for enabling the radiator to obtain a satisfactory heat exchange effect, and a new place in the heat radiation industry is opened up. At present, the heat pipe is widely applied to various heat exchange devices, including the field of nuclear power, such as the utilization of waste heat of nuclear power.

Current heat pipes, particularly multi-tube loop heat pipes, such as the loop heat pipe described in FIG. 1, include dual headers, one header evaporating and one header condensing, thereby forming a vibrating descaled heat pipe. Thereby improving the heat exchange efficiency of the heat pipe and reducing scaling. However, the heat pipe has insufficient uniformity of heat exchange, only one side is used for condensation, and the heat exchange amount is small, so that improvement is needed to develop a heat pipe system with a novel structure.

However, in applications where it is found that continuous heating from a heat source results in fluid stability of the internal electrical heating device, i.e., the fluid is not flowing or is flowing very little, or the flow is stable, resulting in a much reduced vibration performance of the coil, which can affect the efficiency of the coil for descaling and heating.

However, in practice it has been found that adjusting the vibration of the tube bundle by a fixed periodic variation can result in hysteresis and excessively long or short periods. Therefore, the invention improves the previous application and intelligently controls the vibration, so that the fluid in the fluid can realize frequent vibration, and good descaling and heating effects can be realized.

The application is an improvement to projects developed jointly by a plurality of previous units.

Disclosure of Invention

The invention provides an elastic heat pipe with a novel structure aiming at the defect of elasticity in the prior art. The elastic heat pipe can improve the descaling and heat exchange effects according to parameter detection.

In order to achieve the purpose, the invention adopts the following technical scheme:

a loop heat pipe comprises a middle evaporation pipe, a left collecting pipe, a right collecting pipe and pipe groups, wherein the pipe groups comprise a left pipe group and a right pipe group, the left pipe group is communicated with the left collecting pipe and the middle evaporation pipe, the right pipe group is communicated with the right collecting pipe and the middle evaporation pipe, so that the middle evaporation pipe, the left collecting pipe, the right collecting pipe and the pipe groups form heating fluid closed circulation, and a heat source is arranged in the middle evaporation pipe; the loop heat pipe is internally provided with a temperature sensing element for detecting the temperature inside the loop heat pipe, the temperature sensing element is in data connection with the controller, and the controller controls whether the heat source heats or not according to the detected temperature. Thereby controlling stack vibration.

Preferably, the controller controls the heat source to stop heating if the temperature detected by the temperature sensing element is higher than a certain value, and controls the heat source to heat if the temperature detected by the temperature sensing element is lower than a certain value.

Preferably, the temperature sensing member is provided at the upper end of the middle evaporation tube, the left header and the right header.

The invention has the following advantages:

1. the loop heat pipe can judge whether the loop heat pipe reaches a stable state or not according to the internal temperature, and then intelligently controls the heating of the heat source according to the internal temperature, so that the internal fluid can realize frequent vibration, and good descaling and heating effects are realized.

2. The invention can further improve the heating efficiency by arranging the pipe diameters and the intervals of the pipe groups in the height direction.

3. The invention optimizes the optimal relation of the parameters of the loop heat pipe through a large amount of experiments and numerical simulation, thereby realizing the optimal heating efficiency.

4. The invention designs a triangular layout diagram of a multi-loop heat pipe with a novel structure, optimizes the structural parameters of the layout, and can further improve the heating efficiency through the layout.

Description of the drawings:

FIG. 1 is a top view of a loop heat pipe of the present invention.

Fig. 2 is a front view of the loop heat pipe of the present invention.

Fig. 3 is a front view of another embodiment of a loop heat pipe of the present invention.

Fig. 4 is a schematic diagram of the dimensional structure of the loop heat pipe of the present invention.

Fig. 5 is a schematic layout of a loop heat pipe in a circular cross-section heater according to the present invention.

Fig. 6 is a control flow diagram.

In the figure: 1. tube group, left tube group 11, right tube group 12, 21, left collecting tube, 22, right collecting tube, 3, free end, 4, free end, 5, free end, 6, free end, 7, arc tube, 8, middle evaporating tube, 9, heat source, 10 first tube orifice, 13 second tube orifice, left return tube 14, right return tube 15

Detailed Description

The following detailed description of embodiments of the invention refers to the accompanying drawings.

In this document, "/" denotes division and "×", "denotes multiplication, referring to formulas, if not specifically stated.

As shown in fig. 1, a loop heat pipe comprises a middle evaporation tube 8, a left header 21, a right header 22 and a tube group 1, wherein the tube group 1 comprises a left tube group 11 and a right tube group 12, the left tube group 11 is communicated with the left header 21 and the middle evaporation tube 8, the right tube group 12 is communicated with the right header 22 and the middle evaporation tube 8, so that the middle evaporation tube 8, the left header 21, the right header 22 and the tube group 1 form a closed heating fluid circulation, the middle evaporation tube 8 is filled with a phase-change fluid, a heat source 9 is arranged in the middle evaporation tube 8, each tube group 1 comprises a plurality of arc-shaped tubes 7, the ends of the adjacent arc-shaped tubes 7 are communicated, so that the plurality of arc-shaped tubes 7 form a series structure, and the ends of the arc-shaped tubes 7 form arc-shaped tube free ends 3-6; the middle evaporation tube comprises a first tube orifice 10 and a second tube orifice 13, the first tube orifice 10 is connected with the inlet of the left tube group 11, the second tube orifice 13 is connected with the inlet of the right tube group 12, the outlet of the left tube group 11 is connected with the left header 21, and the outlet of the right tube group 12 is connected with the right header 22; the first and second nozzles 10 and 13 are arranged on opposite sides of the central evaporator tube 8.

Preferably, a left return pipe 14 is provided between the left header 21 and the middle evaporation pipe 8, and a right return pipe 14 is provided between the right header 22 and the middle evaporation pipe 8. Preferably, the return pipe is arranged at the bottom.

The fluid heats and evaporates in the middle evaporation tube 8, flows to the left and right headers 21 and 22 along the arc tube bundle, and the fluid can expand in volume after being heated, so that steam is formed, the volume of the steam is far larger than that of water, and the formed steam can flow in the coil in a quick impact manner. Because volume expansion and steam flow can induce the arc tube free end to vibrate, the vibration is transferred to the surrounding heat exchange fluid at the free end of the heat exchange tube in the vibrating process, and the fluid can also generate disturbance each other, so that the surrounding heat exchange fluid forms disturbance flow, a boundary layer is damaged, and the purpose of enhancing heat transfer is realized. The fluid is condensed and released heat in the left and right collecting pipes and then flows back to the middle evaporation pipe through the return pipe.

According to the invention, the prior art is improved, and the condensation collecting pipe and the pipe groups are respectively arranged into two pipes which are distributed on the left side and the right side, so that the pipe groups distributed on the left side and the right side can perform vibration heat exchange descaling, the heat exchange vibration area is enlarged, the vibration can be more uniform, the heat exchange effect is more uniform, the heat exchange area is increased, and the heat exchange and descaling effects are enhanced.

Preferably, the arc pipes of the left pipe group are distributed by taking the axis of the left collecting pipe as the center of a circle, and the arc pipes of the right pipe group are distributed by taking the axis of the right collecting pipe as the center of a circle. The left collecting pipe and the right collecting pipe are arranged as circle centers, so that the distribution of the arc-shaped pipes can be better ensured, and the vibration and the heating are uniform.

Preferably, the tube group is plural.

Preferably, the position of the right tube group (including the right header) is a position of the left tube group (including the left header) rotated by 180 degrees (angle) along the axis of the middle evaporation tube. Through such setting, can make the arc pipe distribution of heat transfer reasonable more even, improve the heat transfer effect.

Preferably, the headers 8, 21, 22 are provided along the height direction.

Preferably, the left tube group 21 and the right tube group 22 are staggered in the height direction, as shown in fig. 2. Through the staggered distribution, can make to vibrate heat transfer and scale removal on the not co-altitude for the vibration is more even, strengthens heat transfer and scale removal effect.

Preferably, the tube group 2 (e.g., the same side (left side or right side)) is provided in plural along the height direction of the middle evaporation tube 8, and the tube diameter of the tube group 2 (e.g., the same side (left side or right side)) becomes smaller from the top to the bottom.

Preferably, the tube diameters of the arc-shaped tubes of the tube group (for example, the same side (left side or right side)) are gradually decreased and increased along the top-down direction of the middle evaporation tube 8.

The pipe diameter range through the nest of tubes increases, can guarantee that more steam gets into through upper portion and control the box, guarantees that the distribution of all nest of tubes interior steam is even, further reinforces the heat transfer effect for whole vibration effect is even, and the heat transfer effect increases, further improves heat transfer effect and scale removal effect. Experiments show that better heat exchange effect and descaling effect can be achieved by adopting the structural design.

Preferably, the tube groups on the same side (left side or right side) are provided in plurality along the height direction of the middle evaporation tube 8, and the distance between the adjacent tube groups on the same side (left side or right side) becomes larger from the top to the bottom.

Preferably, the spacing between the tube groups on the same side (left side or right side) in the height direction of the first header is increased to a larger extent.

The interval amplitude through the nest of tubes increases, can guarantee that more steam passes through upper portion and gets into about the collector, guarantees that the distribution of all nest of tubes steam is even, further reinforces the heat transfer effect for whole vibration effect is even, and the heat transfer effect increases, further improves heat transfer effect and scale removal effect. Experiments show that better heat exchange effect and descaling effect can be achieved by adopting the structural design.

In tests, it was found that the tube diameters, distances and tube diameters of the left header 21, the right header 22, the middle evaporation tube 8 can have an influence on the heat exchange efficiency and uniformity. If the distance between the collector is too big, then heat exchange efficiency is too poor, and the distance between the arc pipe is too little, then the arc pipe distributes too closely, also can influence heat exchange efficiency, and the pipe diameter size of collector and heat exchange tube influences the volume of the liquid or the steam that hold, then can exert an influence to the vibration of free end to influence the heat transfer. Therefore, the pipe diameters and distances of the left header 21, the right header 22, the middle evaporation pipe 8 and the pipe diameters of the arc pipes have a certain relationship.

The invention provides an optimal size relation summarized by numerical simulation and test data of a plurality of heat pipes with different sizes. Starting from the maximum heat exchange amount in the heat exchange effect, nearly 200 forms are calculated. The dimensional relationship is as follows:

the distance between the center of the middle evaporation tube 8 and the center of the left header 21 is equal to the distance between the center of the middle evaporation tube 8 and the center of the right header 21, L, the tube diameter of the left header 21, the tube diameter of the middle evaporation tube 8, and the radius of the right header 22 are R, the radius of the axis of the innermost arc tube in the arc tubes is R1, and the radius of the axis of the outermost arc tube is R2, so that the following requirements are met:

R1/R2＝a*(R/L)²-b (R/L) + c; wherein a, b, c are parameters, wherein 4.834<a<4.835，1.390<b<1.391，0.5585<c<0.5590, respectively; preferably, a is 4.8344, b is 1.3906, and c is 0.5587.

Preferably, 34< R <61 mm; 114< L <191 mm; 69< R1<121mm, 119< R2<201 mm.

Preferably, the number of curved tubes of the tube set is 3-5, preferably 3 or 4.

Preferably, 0.57< R1/R2< 0.61; 0.3< R/L < 0.32.

Preferably, 0.583< R1/R2< 0.60; 0.304< R/L < 0.316.

Preferably, the radius of the arc tube is preferably 10-40 mm; preferably 15 to 35mm, more preferably 20 to 30 mm.

Preferably, the centers of the left header 21, the right header 22 and the middle evaporation tube 8 are on a straight line.

Preferably, the arc between the ends of the free ends 3, 4, centered on the central axis of the left header, is 95-130 degrees, preferably 120 degrees. The same applies to the curvature of the free ends 5, 6 and the free ends 3, 4. Through the design of the preferable included angle, the vibration of the free end is optimal, and therefore the heating efficiency is optimal.

Preferably, the loop heat pipe can be used as an immersed heat exchange assembly, immersed in a fluid to heat the fluid, for example, the loop heat pipe can be used as an air radiator heating assembly, and can also be used as a water heater heating assembly.

The heat source heating power is preferably 1000-2000W, more preferably 1500W.

Preferably, the box body has a circular cross section, and is provided with a plurality of electric heating devices, wherein one electric heating device is arranged at the center of the circular cross section and the other electric heating devices are distributed around the center of the circular cross section.

Preferably, the tube bundle of the tube bank 1 is an elastic tube bundle.

The heat exchange coefficient can be further improved by arranging the tube bundle of the tube group 1 with an elastic tube bundle.

Further preferably, the heat source is an electric heating rod.

The number of the pipe groups 1 is multiple, and the plurality of pipe groups 1 are in a parallel structure.

It has been found in research and practice that continued power-stable heating of the heat source results in fluid-forming stability of the inner loop heat pipe, i.e., no or little fluid flow, or stable flow, resulting in greatly reduced vibrational performance of the stack 1, thereby affecting the efficiency of descaling and heating the stack 1. Therefore, the loop heat pipe described above needs to be improved as follows.

In the applicant's prior application, a periodic heating regime is proposed whereby the vibration of the stack is continuously encouraged to improve heating efficiency and descaling. However, adjusting the vibration of the tube group by the fixed periodic variation may cause hysteresis and a period to be too long or too short. Therefore, the invention improves the previous application and intelligently controls the vibration, so that the fluid in the fluid can realize frequent vibration, and good descaling and heating effects can be realized.

Aiming at the defects in the technology researched in the prior art, the invention provides a novel electric heating loop heat pipe capable of intelligently controlling vibration. The heat pipe can improve the heating efficiency, thereby realizing good descaling and heating effects.

Self-regulation vibration based on pressure

Preferably, a pressure sensing element is arranged in the loop heat pipe and used for detecting the pressure in the loop heat pipe, the pressure sensing element is in data connection with the controller, and the controller controls whether the heat source heats or not according to the detected pressure.

Preferably, the controller controls the heat source to stop heating if the pressure detected by the pressure sensing element is higher than a certain value, and controls the heat source to heat if the pressure detected by the pressure sensing element is lower than a certain value.

Through the pressure that pressure sensing element detected, can satisfy under certain pressure condition, the evaporation of inside fluid has basically reached saturation, and the volume of inside fluid also basically changes little, and under this kind of condition, inside fluid is relatively stable, and the tube bank vibratility at this moment worsens, therefore needs to adjust, makes it vibrate to stop heating. So that the fluid undergoes volume reduction to thereby realize vibration. When the pressure is reduced to a certain degree, the internal fluid starts to enter a stable state again, and at the moment, the fluid needs to be heated so as to evaporate and expand again, so that a starting heat source needs to be used for heating.

Preferably, the pressure sensing element is disposed within the middle evaporation tube and/or the left header and/or the right header.

Preferably, the pressure sensing elements are disposed within the middle evaporation tube, the left header and the right header. The average value of the pressures of a plurality of headers can be selected as the regulating data.

Preferably, the pressure sensing element is disposed at the free end. Through setting up at the free end, can perceive the pressure variation of free end to realize better control and regulation.

Independently adjusting vibration based on temperature

Preferably, a temperature sensing element is arranged in the loop heat pipe and used for detecting the temperature in the loop heat pipe, the temperature sensing element is in data connection with the controller, and the controller controls whether the heat source heats or not according to the detected temperature.

Preferably, the controller controls the heat source to stop heating if the temperature detected by the temperature sensing element is higher than a certain value, and controls the heat source to heat if the temperature detected by the temperature sensing element is lower than a certain value.

The pressure detected by the temperature sensing element can basically reach saturation when the certain temperature is met, and the volume of the internal fluid is not changed greatly basically. So that the fluid undergoes volume reduction to thereby realize vibration. When the temperature is reduced to a certain degree, the internal fluid starts to enter a stable state again, and the fluid needs to be heated to evaporate and expand again, so that a starting heat source needs to be used for heating.

Preferably, the temperature sensing member is provided at an upper end of the middle evaporation tube and/or the left header and/or the right header.

Preferably, the temperature sensing member is provided at the upper end of the middle evaporation tube, the left header and the right header. The average of the temperatures of the various headers can be selected as the regulating data.

Preferably, the temperature sensing element is disposed at the free end. Through setting up at the free end, can perceive the temperature variation of free end to realize better control and regulation.

Thirdly, automatically adjusting vibration based on liquid level

Preferably, a liquid level sensing element is arranged in the middle evaporation tube and used for detecting the liquid level of the fluid in the middle evaporation tube, the liquid level sensing element is in data connection with the controller, and the controller controls whether the heat source heats or not according to the detected liquid level of the fluid.

Preferably, the controller controls the heat source to stop heating if the liquid level detected by the liquid level sensing element is lower than a certain value. The liquid level detected by the liquid level sensing element is higher than a certain value, and the controller controls the heat source to heat.

The liquid level detected by the liquid level sensing element can basically reach saturation of evaporation of the internal fluid and basically does not change much in volume of the internal fluid under the condition of meeting a certain liquid level (such as the lowest limit). So that the fluid undergoes volume reduction to thereby realize vibration. When the liquid level rises to a certain degree, the internal fluid starts to enter a stable state again, and at the moment, the fluid needs to be heated so as to evaporate and expand again, so that a starting heat source needs to be used for heating.

Fourthly, automatically adjusting vibration based on speed

Preferably, a speed sensing element is arranged in the free end of the tube bundle and used for detecting the flow speed of the fluid in the free end of the tube bundle, the speed sensing element is in data connection with the controller, and the controller controls whether the heat source heats or not according to the detected speed of the fluid.

Preferably, the controller controls the heat source to stop heating if the speed sensed by the speed sensing element is higher than a certain value. The liquid level detected by the speed sensing element is lower than a certain value, and the controller controls the heat source to heat.

The speed detected by the speed sensor element can substantially saturate the evaporation of the internal fluid to form a stable flow and the speed of the internal fluid does not substantially change when a certain speed (for example, the highest upper limit) is satisfied. So that the fluid undergoes volume reduction to thereby realize vibration. When the speed drops to a certain degree, the internal fluid starts to enter a stable state again, and the fluid needs to be heated to evaporate and expand again, so that a starting heat source needs to be used for heating.

A heater such as that shown in fig. 5, for example a water heater, has a circular cross-sectional housing within which the plurality of loop heat pipes are disposed. Preferably, three loop heat pipes are arranged in the shell, and extension lines of central connecting lines of the left header, the right header and the middle evaporation pipe of the loop heat pipes form an inscribed regular triangle with a circular cross section. Through such setting, can make and to fully reach vibrations and heat transfer purpose in can making the heater, improve the heat transfer effect.

Learn through numerical simulation and experiment, loop heat pipe's size and circular cross section's diameter have very big influence to the heat transfer effect, loop heat pipe oversize can lead to adjacent interval too little, the space that the centre formed is too big, middle heating effect is not good, the heating is inhomogeneous, on the same hand, loop heat pipe size undersize can lead to adjacent interval too big, leads to whole heating effect not good. Therefore, the invention obtains the optimal size relation through a large amount of numerical simulation and experimental research.

The distance between the centers of the left collecting box and the right collecting box is L1, the side length of the inscribed regular triangle is L2, the radius of the axis of the innermost arc pipe in the arc pipes is R1, and the radius of the axis of the outermost arc pipe is R2, so that the following requirements are met:

10*(L1/L2)＝d*(10*R1/R2)-e*(10*R1/R2)²-f; wherein d, e, f are parameters,

42.69<d<42.71,3.63<e<3.64,119.9<f<120.1；

further preferably, d is 42.702, e is 3.634, f is 122.01;

with 720< L2<1130mm preferred. Preferably 0.3< L1/L2< 0.6.

Further preferably 0.32< L1/L2< 0.4.

Preferably, the centers of the left header 21, the right header 22 and the middle evaporation tube 8 are on a straight line.

Through the layout of the three loop heat pipes with optimized structure, the whole heat exchange effect can reach the best heat exchange effect.

The heat source is preferably an electric heater.

Although the present invention has been described with reference to the preferred embodiments, it is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (3)

1. A loop heat pipe comprises a middle evaporation pipe, a left collecting pipe, a right collecting pipe and pipe groups, wherein the pipe groups comprise a left pipe group and a right pipe group, the left pipe group is communicated with the left collecting pipe and the middle evaporation pipe, the right pipe group is communicated with the right collecting pipe and the middle evaporation pipe, so that the middle evaporation pipe, the left collecting pipe, the right collecting pipe and the pipe groups form heating fluid closed circulation, and a heat source is arranged in the middle evaporation pipe; the device comprises a plurality of pipe groups, a plurality of connecting pipes and a plurality of connecting pipes, wherein each pipe group comprises a plurality of arc-shaped pipes, the end parts of the adjacent arc-shaped pipes are communicated, so that the arc-shaped pipes form a serial structure, and the end parts of the arc-shaped pipes form free ends of the arc-shaped pipes; the middle evaporation tube comprises a first tube orifice and a second tube orifice, the first tube orifice is connected with the inlet of the left tube group, the second tube orifice is connected with the inlet of the right tube group, the outlet of the left tube group is connected with the left collecting tube, and the outlet of the right tube group is connected with the right collecting tube; the first pipe orifice and the second pipe outlet are arranged on two opposite sides of the middle evaporation pipe; the position of the right tube group is the position of the left tube group which rotates 180 degrees along the axis of the middle evaporation tube; the loop heat pipe is internally provided with a temperature sensing element for detecting the temperature inside the loop heat pipe, the temperature sensing element is in data connection with the controller, and the controller controls whether the heat source heats or not according to the detected temperature so as to control the vibration of the pipe group.

2. A loop heat pipe according to claim 1 wherein the temperature sensed by the temperature sensing element is above a certain value, the controller controls the heat source to stop heating, and the controller controls the heat source to heat if the temperature sensed by the temperature sensing element is below a certain value.

3. A loop heat pipe according to claim 1 wherein the temperature sensing element is provided at an upper end of the middle evaporation tube, the left header and the right header.

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