KR101217075B1 - Temperature control system - Google Patents

Abstract

PURPOSE: A temperature control system is provided to obtain a regular radiant value without heat cycle difference at an inlet and outlet of a pipe by maintaining the temperature of a second flow pipe. CONSTITUTION: A temperature control system comprises a temperature pipe and a boiler. The boiler generates hot water by heating the water inside. The temperature control pipe comprises a first flow pipe(110), a second flow pipe(120), and a heat medium material(130). The hot water is supplied to the first flow pipe, and circulates inside. The first flow pipe is inserted into the second flow pipe, and the second flow pipe emits the heat to the outside. The heat medium material is filled in a vacuum space(140) between the first and second flow pipes. The heat medium material is evaporated by absorbing the heat around the first flow pipe, and delivers the heat to the inner wall of the second flow pipe.

Description

TEMPERATURE CONTROL SYSTEM

The present invention relates to a temperature control system having a temperature control tube having a structure capable of maximizing heating efficiency.

In general, a heating device using a heating pipe in which a boiler and hot water circulate is a structural radiant heating method that constitutes a low-temperature heat dissipation surface in a large area. The heat capacity is very large, so the preheating time is long and the inertia is large due to large inertia. There was a problem such as difficult to properly cope with the change.

The heating system using such a boiler implements the function by heating the hot water to supply hot water to the heating target area by using a general hot water pipe.

Figure 1 shows the structure of a typical heat pipe applied to such a conventional heating system.

Referring to Figure 1, in the conventional heating system in a way to efficiently dissipate the heat of hot water supplied through the boiler to the outside, as shown, the pipe 10 is formed with a flow path for flowing hot water therein and the A plurality of direction fins 20 are provided on the outside of the pipe to implement a structure that can widen the heat dissipation surface area of the pipe.

However, the hot water pipe of such a structure is operated as a heat dissipation structure using the temperature of the hot water, the heat dissipation efficiency is extremely reduced as the temperature of the hot water is gradually lowered, through the temperature of the first hot water input and the outlet after the heat dissipation The temperature of the hot water circulated is significantly different, which causes an inefficient aspect such that the boiler needs to be warmed for a long time in order to warm the circulated hot water again.

Korean Patent Registration No. 10-0867143

The present invention has been made to solve the above-described problems, an object of the present invention is to arrange a first flow tube of the structure inserted into the second flow tube forming a vacuum state, the heat medium containing alcohol as a main raw material By controlling the temperature by using a temperature control tube of filling structure, when hot water flows into the first flow tube, the working liquid absorbs heat around the first flow tube to evaporate, becomes a vapor, and moves to the second flow tube at high speed. The steam is cooled and condensed again and then circulated back to the heating section of the first flow pipe while continuously transferring heat from the first flow pipe to the second flow pipe to perform a very efficient temperature control to ensure efficient heating environmentally By implementing the temperature control system to maximize energy efficiency.

As a means for solving the above-described problems, the present invention is to arrange a first flow tube capable of moving hot water inside the second flow tube is maintained in a vacuum state, the vacuum flow space between the first flow tube and the second flow tube It fills the heat medium and transfers heat through the evaporation and condensation process of the heat medium to form heat control tube.

Through this, the temperature of the second flow pipe is maintained almost constant while the thermal conductivity is high, thereby minimizing the temperature difference between the inlet and the outlet where the hot water is introduced, and it can prevent the sudden drop in the temperature in the temperature control tube during operation. It is possible to perform a desired heating or cooling function only by supplying a heat source, so that the boiler can be miniaturized and fuel costs can be reduced.

According to the present invention, a temperature control tube having a structure in which a first flow tube having a structure inserted into a second flow tube forming a vacuum state is disposed and a thermal medium material containing alcohol as a main material is filled between the first flow tube and the second flow tube. By controlling the temperature by using the temperature, when the hot water flows into the first flow tube, the working liquid absorbs heat around the first flow tube and evaporates, becomes a steam flow and moves to the second flow tube at high speed, the steam is cooled and condensed after There is an effect to perform a very efficient temperature control by moving the heat continuously from the first flow tube to the second flow tube while repeating the operation circulating back to the heating portion of the first flow tube.

In addition, by adopting a double heat regulation system and a heat medium through a heat medium, the heat conductivity is high and the temperature of the second flow tube is almost constant, so that a uniform amount of heat dissipation can be obtained at the inlet and the outlet without difference in heat circulation. Advantages are implemented.

Furthermore, even when the hot water temperature is set to a low temperature, there is an advantage that can realize an excellent cooling effect.

In addition, it is possible to install horizontal piping, so it is possible to install long-distance horizontal structure, which eliminates the need for adopting conventional bending or bending structures for convection, which enhances the efficiency of installation. Since there is no temperature drop, the hot water temperature can be significantly lower than that of a conventional boiler, and the size of the boiler can be reduced, and the running cost can be reduced (50% of fossil fuel). have.

1 is a conceptual diagram showing the structure of a heat pipe of a conventional heating system.
2 and 3 is a conceptual view showing the main part of the structure of the temperature control tube according to the present invention.
4 is a conceptual diagram showing the principle of the temperature control system according to the present invention.
5 shows a schematic structure of a temperature control system according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation according to the present invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description with reference to the accompanying drawings, the same reference numerals denote the same elements regardless of the reference numerals, and redundant description thereof will be omitted. Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

The present invention can implement efficient heat transfer using the principle of radiating heat by heat evaporation and condensation circulation of the heat medium material by filling the heat medium material for heat conduction inside the pipe structure implemented as a double structure of the first flow pipe and the second flow pipe. The objective is to provide a temperature control system.

2 and 3 is a conceptual view showing the main part of the structure of the temperature control tube according to the present invention.

Referring to the figure, the temperature control system according to the present invention is characterized in that it comprises a boiler for heating the water flowing in the interior of the water heater and the temperature control tube 100 for moving the heated water in the boiler. .

In particular, the temperature control pipe 100 is disposed in a structure in which the first flow pipe 110 and the first flow pipe 110 are circulated therein when the hot water is supplied, and the heat of the first flow pipe is inserted. The second flow pipe 120 for dissipating to the outside is provided. That is, it implements a structure in which the first flow tube 110 is accommodated in the second flow tube 120. It is filled in the vacuum space 140 between the first flow tube 110 and the second flow tube 120, absorbs the heat around the first flow tube 110 and evaporates the second flow tube 120 It is preferably formed by further comprising a heat medium material 130 to be delivered to the inner wall of the.

Specifically, as shown in the temperature control tube 100, the first flow tube 110 is formed in a structure that is inserted into the second flow tube 120, the first flow tube 110 and the second flow tube The space between the 120, that is, the inside of the second flow tube 120 is more preferably formed in a vacuum state. The formation of such a vacuum state serves to maximize the efficient transfer of heat.

The material of the first and second flow pipes may be implemented as a corrosion-resistant metallic pipe, such as SUS, copper pipes.

In particular, the temperature control tube according to the present invention is arranged in a structure in which the first flow tube 110 is disposed below the central axis (X) of the second flow tube 120, the heat medium material 130 is filled is the first It is more preferable to be able to fill more than the height of the flow tube (110). This is implemented in such a way that the heat medium material 130 receives the heat of the first flow pipe 110 and evaporates, moves to the inner wall of the second flow pipe 120 to condense, and transfers heat to the second flow pipe 120. In order to increase the heat transfer efficiency, the heat medium material 130 is more preferably filled to cover the entire surface of the first flow tube 110.

To this end, it is apparent that the diameter (a) of the first flow tube (110) is formed smaller than the diameter (b) of the second flow tube (120), and particularly preferably the ratio of the diameter of the first flow tube and the second flow tube ( 0.1 to 1): 2 is preferably implemented. In order to realize the most efficient heat transfer structure, as shown in FIG. 3, the diameter of the first flow tube 110 may be formed to be equal to or smaller than the radius b1 of the second flow tube 120. The efficiency can be increased in consideration of the cost and the enhancement of the thermal efficiency according to the filling rate of the material.

In addition, as shown in (b) of Figure 2, the temperature control tube according to the present invention is further formed with a sealing portion 150 for sealing the sock end of the second flow tube 120, the sealing portion ( 150 is preferably implemented by unitizing the first flow pipe 110 to be implemented in a structure in which a through hole through which the first flow pipe 110 passes. This unit unit structure can be implemented by the temperature control pipe of the present invention, the circulation pipe structure of the entire heating system, as well as a structure that is installed a plurality of specific standards in a specific area (building, soil, barn, greenhouse, etc.) that requires heating. It can also be implemented to increase installation efficiency.

Figure 4 shows the basic principle of the temperature control tube according to the present invention.

Referring to FIG. 4, in the temperature control tube according to the present invention, a first flow tube 110 into which hot water is introduced and a second flow tube 120 are formed outside thereof, and the heat medium is formed in the vacuum state space 140. The material 130 is filled.

Particularly, as described above with reference to FIG. 2 (b), a sealing part having a structure for sealing both ends of the second flow pipe 120 is realized. In this case, when hot water is supplied to the first flow tube 110, the heat medium material 130 absorbs heat around the first flow tube 110 to evaporate (Y1), and the vaporized vapor stream is a relatively low temperature portion. The high speed moves to the inner wall of the second flow tube 120, the steam is cooled in the second flow tube 120 to condense to transfer heat. The condensed heat medium material circulates back to the periphery of the first flow tube 110 by gravity and returns. Through the circulation process of evaporation, movement, and condensation of the heat medium material, heat is continuously transferred from the first flow tube, which is a high temperature part, to the second flow tube, which is a low temperature part.

The temperature control tube according to the present invention of such a structure is free from the limitation that the conventional heat pipe for installation to maintain a bent structure or a constant bent angle to implement heat circulation by convection, horizontal direction It is possible to connect to this, and through this it is possible to connect and connect a long distance male.

In particular, since the thermal conductivity is very high and the temperature of the second flow tube 120 is maintained substantially constant due to the action of the heat medium material, there is almost no temperature difference between the inlet and outlet at which the hot water flows into the temperature control tube. The advantage of obtaining the heat dissipation is realized. Furthermore, not only the heating but also cooling is possible, so that when the low temperature water is introduced, the temperature of the cold water hardly rises to the outlet due to the uniformity maintaining ability. For example, if the temperature is set to 15 ° C, it is also possible to circulate as set temperature to implement a relative cooling function to use as cooling.

The heat medium material 130 filled in the temperature control tube according to the present invention includes 55 to 65% by weight of the main raw material material containing alcohol components and 35 to 45% by weight of water in the total weight of the heat medium material. It can be formed into a mixture, the mixture preferably has a hydrogen ion concentration (pH) of 6.5 ~ 6.9 range. In addition, the above-described heat medium material may have a specific gravity of 0.8 to 0.9 and a break point at 80 ° C to 81 ° C.

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Figure 5 shows a schematic configuration of a temperature control system according to the present invention.

As shown, the boiler 200 for warming the temperature of the water is not only a function of warming the water for heating, but also to lower the set temperature according to the external temperature to warm the water, it is possible to implement the cooling efficiency as described above.

In addition, the temperature control pipe 100 according to the present invention can be utilized as a whole pipe, of course, it is also possible to implement the structure as shown in Figure 5 by forming a temperature control pipe only in a certain heating zone.

In the temperature control system according to the present invention, since the amount of hot water is reduced by 1/5 compared with the structure of the conventional heat pipe, energy for heating can be significantly reduced. That is, since it is possible to continuously maintain the excellent heat transfer rate and the uniform hot water temperature according to the structure of the temperature control tube and the action of the heat medium according to the present invention, it is remarkably compared to the boiler system using a normal pipe structure. By implementing only a small amount of water to compensate for the slightly lost temperature, the amount of water used is also reduced, thereby minimizing the size of the boiler.

In addition, due to the excellent heat conduction effect is realized that the temperature does not drop rapidly during operation, and thus, when setting the hot water temperature of the heat source to low temperature, it is also possible to use the temperature control for cooling in the summer.

In addition, the radiant heat and conduction heat emitted from the temperature control tube according to the present invention can warm the air like the normal air heat exchange type heating, and at the same time the radiant heat can uniformize the temperature distribution in the facility, and generate a wave accompanied by minute ultrasonic waves and far infrared rays. When activated and used for livestock such as pig cages, it not only activates the cells in the body of the livestock, but also does not generate carbon monoxide and carbon dioxide, so ventilation is unnecessary and has a low noise effect to realize a pleasant breeding environment. Furthermore, it does not cause convection in the room, thereby reducing the occurrence of disease caused by air infection.

Furthermore, in addition to using for heating and cooling, when the hot water is implemented by horizontally embedding the temperature control tube according to the present invention in the soil, it is not affected by temperature and humidity, and kills pathogens, pests, weeds and at the same time surrounding crops. As there is no adverse effect on the furnace and no residual toxicity to crops, there is an environmentally friendly effect as well as the use of toxic substances such as methyl embrittlement used for soil disinfection.

In the foregoing detailed description of the present invention, specific examples have been described. However, various modifications are possible within the scope of the present invention. The technical idea of the present invention should not be limited to the embodiments of the present invention but should be determined by the equivalents of the claims and the claims.

100: temperature control tube
110: first flow tube
120: second flow tube
130: heat medium
140: vacuum space

Claims (8)

A boiler for heating the water flowing therein to heat the water;
A first flow pipe 110 which receives the warm water and circulates therein; A second flow tube 120 disposed in a structure in which the first flow tube 110 is inserted and dissipating heat of the first flow tube 110 to the outside; And a vacuum state space 140 between the first flow tube 110 and the second flow tube 120, absorbs heat around the first flow tube 110, and evaporates the second flow tube 120. It includes a temperature control tube 100 including the heat medium material 130 to be delivered to the inner wall of the,
The first flow pipe 110 is disposed below the central axis of the second flow pipe 120, the entire outer surface of the first flow pipe 110 accommodated in the second flow pipe 120 is the heat medium. In direct contact with material 130,
The heat medium material 130 has a weight of 55-65% of the main raw material material containing an alcohol component in the weight% of the total heat medium material, the water contains a weight of 35-45%, hydrogen ion concentration (pH) Is within the range of 6.5 ~ 6.9, the specific gravity is 0.8 ~ 0.9, the break point is formed at 80 ℃ ~ 81 ℃, the inside of the second flow tube 120 is filled in more than the height of the first flow tube 110,
The temperature control tube 100 is further formed with a sealing portion 150 for sealing the sock end of the second flow tube 120, the sealing portion 150 is a through hole through which the first flow tube 110 passes. The temperature control system of the structure which is formed. delete delete delete delete delete delete delete

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