KR20070113753A - Vinegar power saving triple structure heat-pipe heating system - Google Patents

Abstract

A energy-saving heat-pipe heating system with a triple structure is provided to facilitate circulation of heat medium with a blade communicating end portions of fins, and to prevent crack of pipe due to high water pressure or high temperature by inserting a copper pipe on the outside of a heater. A energy-saving heat-pipe heating system with a triple structure comprises a heater(110), an auxiliary pipe(120), a vacuum filling pipe(130), a plurality of heat dissipating fins(140), and a blade(150). The heater comprises one of a heater tube using electricity as heat source or a hot water pipe using hot water as heat source. The auxiliary pipe is made of copper pipe for the insertion of the heater. The vacuum filling pipe is made of copper pipe for the insertion of the auxiliary pipe and filling of a heat medium(131) therein. The heat dissipating fins extends to the outside on an outer peripheral side of the vacuum filling pipe, in communication with the vacuum filling pipe. The blade is coupled to end portions of the heat dissipating fins, in communication with the heat dissipating fins.

Description

Vinegar power saving triple structure heat-pipe heating system

1 is a cross-sectional view schematically showing a heating system using a heat pipe according to the prior art,

2 is a view showing an example in which the heating system of Figure 1 is applied to the floor,

3 is a view showing an example in which the heating system of Figure 1 is applied to a self-supporting radiator,

4 is a front side cross-sectional view schematically showing an ultra-low power triple structure heat pipe heating system for floor heating according to the present invention;

Figure 5 is a side cross-sectional view schematically showing a self-supporting radiator type ultra-low power triple structure heat pipe heating system according to the present invention,

6 is a cross-sectional view showing a connection portion for continuously connecting the ultra-low power triple structure heat pipe heating system using electricity as a heat source according to the present invention; and

7 is a view showing an example in which the ultra-low power triple structure heat pipe heating system for a floor ondol according to the present invention is applied to a floor ondol.

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

100: Ultra low power triple structure heat pipe heating system for floor ondol

200: Freestanding radiator type ultra low power triple structure heat pipe heating system

110: heater 120: auxiliary pipe

130: filling tube 131: heat medium

140: heat radiation fins 141: induction furnace

150: wing 151: circuit

160: connector 170: connection cap for power discharge

170 ': power supply connection cap 171: terminal

171 ': terminal

The present invention relates to a heating system, and more particularly, to an ultra-low power triple structure heat pipe heating system with excellent heating effect while saving energy.

In general, a heating system may be representative of an ondol or a radiator.

Ondol heating method is Korea's own floor radiant heating method that has been introduced for a long time, and its origin is about 2000 years. It is efficient to reduce the perfusion heat loss due to the temperature difference between and, and the heat storage effect is very scientific heating method. In the past, domestic research on heating has been extremely insignificant compared to the long period of use. Bonfire and Ondol Guilde Field has been continued since prehistoric times It is only recently developed into hot water pipes (Excel pipe, copper pipe), hot air fan, and radiator heating method.

On the other hand, in the case of foreign countries, various methods have been sought for the efficient use of energy as well as the efficient transfer of thermal energy, and one of them is the heat pipe, which is becoming more versatile due to its advantages.

When heat pipe was used for heating in Korea about 10 years ago, when heat pipe heating is installed, energy (fuel, electricity) can be reduced by about 50% compared to the existing heating method. Although it is attempting, due to technical problems (head leakage, slope, deformation due to welding stress, cracks, etc.), high production cost (about 200% compared to the existing method) and construction cost (about 150% compared to the existing method), it is a competitive product. In addition, the supply is very low compared to copper pipes, and the market share is less than 1% in this field. Some companies are still developing products and pioneering the market.

As shown in FIG. 1, the heat pipe includes a heater 2 heated by electricity or water, and a filling tube 3 in which the heat medium 4 is filled in the outside of the heater 2 while the heater 2 is embedded therein. ) And a heat dissipation fin 5 that is integrally attached to one side of the filling tube 3 and communicates with the filling tube 3 to circulate the heat medium 4.

That is, the heater 2 heats the heat medium 4, and the heated heat medium 4 is convex in the filling tube 3 and the heat dissipation fin 5 to dissipate heat from the heat dissipation fin 5.

This type of heat pipe 1 is used for floor ondol and for radiators.

FIG. 2 is a view schematically showing a heating system using a heat pipe manufactured for ondol, and as shown in FIG. 2, the heating system 10 supplies a filling pipe 3 to a center of a floor 11 for heating. And a collecting tube 3 for recovery, and each filling tube 3 is returned. And the heat radiation fins 5 to be formed in each of the filling tubes 3 extend to the edge side of the bottom. The heating system 10 can reduce the fuel cost because a lot of water is not needed when using water, and even if electricity is used, the heating element is not spread over the entire bulb of the floor, and thus, a lot of power can be reduced. .

3 is a view schematically showing a heating system using a heat pipe manufactured for a radiator. As shown in FIG. 3, the heating system 20 arranges the filling tube 3 toward a wall of a living room or an office, and the like. The heat radiation fins 5 are formed above the filling tube 3. And it is installed by connecting the filling tube (3) and the filling tube (3) continuously.

The heating system 10, 20 using the heat pipe as described above has an advantage of excellent energy saving effect, but some inadequate parts have been found continuously, there was a problem that often breaks due to defects between the heater and the filling tube.

The present invention has been made to reinforce the prior art as described above, an object of the present invention can be used semi-permanently by further inserting a new copper pipe to the outside of the heater to prevent damage caused by high temperature or water pressure, It is to provide an ultra-low power triple structure heat pipe heating system capable of releasing higher temperature with rapid heating by further providing a wing that connects the end and communicates with the heat medium more quickly and smoothly.

The present invention to achieve the above object,

A heater composed of any one of a heater rod using electricity as a heat source or a hot water pipe using hot water as a heat source;

An auxiliary pipe made of copper pipe into which a heater is inserted;

A vacuum filling tube made of a copper pipe in which an auxiliary tube is inserted and a heating medium is filled therein;

A plurality of heat dissipation fins communicating with the filling tube while extending to one side on an outer circumferential surface of the filling tube; And

It provides an ultra-low power triple structure heat pipe heating system comprising a wing connected to the ends of the heat radiation fins and in communication with the heat radiation fins.

Or, the present invention,

In a self-supporting radiator type heating system consisting of a filling tube zigzag-extended in one or several rows and a heat radiation fin integrally formed on the upper side of the filling tube,

The structure of the filling tube is a heater composed of any one of a heater rod using electricity as a heat source or a hot water pipe using hot water as a heat source, an auxiliary pipe made of a copper pipe into which the heater is inserted, and an auxiliary pipe is inserted therein. It consists of a vacuum filling tube made of copper pipe filled with a heat medium, the ends of the heat dissipation fins are formed with wings communicating with each other, ultra-low power triple structure heat, characterized in that it further comprises a connecting tube connecting the wings to each other Provide a pipe heating system.

Hereinafter, an ultra-low power triple structure heat pipe heating system according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

The heating system according to the present invention can be largely classified into a heating system for floor heating and a self-supporting radiator type heating system. Each heating system may be further classified into a heating system using electricity or a heating system using hot water.

First, the heating system for floor ondol will be described.

Figure 4 is a front side cross-sectional view schematically showing an ultra-low power triple structure heat pipe heating system for floor ondol according to the present invention.

As shown in FIG. 4, the heating system for the floor ondol according to the present invention includes a heater 110, an auxiliary pipe 120, a filling tube 130, a heat dissipation fin 140, and a wing 150.

The heater 110 is a heater rod having a structure in which electricity is supplied to one side of the heat generating unit heated by electricity to radiate heat from the whole. These heater rods have been developed in recent years and used those that can be easily obtained on the market. At this time, one side of the heater 110 is connected to the plug 111 is connected to the outlet.

Alternatively, the heater 110 is supplied with hot water to one side of the hot water pipe heated by the hot water and the hot water is recovered to the other side.

The auxiliary pipe 120 has a structure wrapped around the outside of the heater 110. The auxiliary pipe 120 is made of copper pipe, and is wrapped in close proximity to the heater 110. At this time, the reason for placing the auxiliary pipe 120 is to extend the life.

That is, in order to solve the problem that the heater 110 itself is damaged early due to the high temperature of the heater 110, the heating system using hot water is more effective than the heating system using electricity.

Herein, the role of the auxiliary pipe 120 will be described in detail. The heater 110 may be cracked due to high temperature and high pressure, and may be corroded when aged. In view of these problems, the auxiliary pipe 120 is further placed outside the heater 110.

Of course, the thicker the thickness of the heater 110 can be used longer, but the life is shorter than that formed in two layers.

In other words, assuming that the thickness of one heater is 3 mm and that the thickness of the two heaters is 1.5 mm, the time at which the first crack occurs in both heaters is almost the same, with only a slight difference. The time difference that progresses from breakage does not have much difference. For example, if both types of cracks occur, and the time required for breakage takes about 100 days for a 3mm tube, it is considered to be about 70 days for a 1.5mm tube. Therefore, in case of 1.5mm pipe, the point of breakage may be a little faster than 3mm pipe, but since it is doubled, if you calculate the time from crack to break again, you will be able to boast a considerable life.

Filling pipe 130 is made of a copper pipe similar to the auxiliary pipe 120 and the auxiliary pipe 120 is inserted into the auxiliary pipe 120 to be separated at a predetermined interval, the auxiliary pipe 120 and the filling pipe 130 The heat medium 131 is filled between the gaps, and the space therebetween is formed in a vacuum. There are several reasons for this, such as vacuum. For example, water evaporates at 100 ° C but evaporates at 30 ° C in vacuum. That is, the energy sensible heat of water is 100 kcal (1 cal is required to increase 1 g of water by 1 ° C.), but the sensible heat of 100 ° C. of gas (vapor) is 539 kcal.

The heat dissipation fin 140 is integrated with the filling tube 130 and extends to the outside on one side on the outer circumferential surface of the filling tube 130. The induction path 141 is formed in the heat dissipation fin 130 to communicate with the filling tube 130 while the heat medium 131 flows. Therefore, the heat medium 131 heated by the heater 110 is convex to the filling tube 130 and the heat dissipation fin 140.

The wing 150 connects the ends of the extended heat dissipation fins 140, and a circulation path 151 communicating with the induction path 141 inside the heat dissipation fins 140 is formed in the wing 150 to form respective heat dissipation fins. The heat medium 131 of 140 is quickly circulated.

The following describes a self-contained radiator type heating system.

Figure 5 is a side cross-sectional view schematically showing a self-supporting radiator type ultra-low power triple structure heat pipe heating system according to the present invention.

The radiator type heating system has a structure similar to that of the floor heating system 100, as shown in FIG. 5, but aims for another heat dissipation in the return line to recover the waste heat.

That is, the filling tube 130 extends in a single row or a plurality of rows in a zigzag form, and the heat dissipation fins 140 extending upward on the upper surfaces of the filling tubes 130 are formed to communicate with the filling tube 130. Here, the structure of each filling tube 130 is similar to the heating system for the floor ondol heater 110, which is generated by electricity or hot water, the auxiliary pipe 120 surrounding the outside of the heater 110, and the auxiliary pipe ( 120 is made of a filling tube 130 is built.

And at the ends of the heat dissipation fins 140, the wing 150 has a configuration formed to communicate the heat dissipation fins 140 with each other.

Here, in order to promote a more active circulation of the heating medium, the supply line side wing and the recovery line side wing may further form the connection tube 160 integrally.

Although described above as a set of heating system, it is possible to install a wide range by connecting several using the above-described set of heating system.

6 is a cross-sectional view illustrating a connection structure of an ultra low power triple structure heat pipe heating system using electricity.

That is, in the case of a heating system using electricity, as shown in FIG. 6, a discharge line for discharging power supplied to one side may be further formed on the other side of the heater 110 to be connected to another heating system 100. Therefore, one side of another heating system 100 'is provided with a power supply connection socket 170'. And the other side of the heating system (100, 100 ') is connected to the power socket for power supply 170 is formed. These connection sockets 170, 170 'will be preferably extended to the filling tube 130 to be male and female to each other. In addition, a pair of terminals 171 for discharging power are formed in the power dissipation connecting socket 170, and a terminal 171 'into which the terminal 171 is inserted is formed in the power supply connecting socket 170'. It would be desirable to.

Meanwhile, in the case of a heating system using hot water, a connection socket for hot water discharge (not shown) to extend from the filling tube 130 to the other side and one side of the heater 110 similarly to the male and female, similarly to the heating system using electric power. Connection sockets (not shown) for hot water supply may be formed. In addition, the connection socket for hot water supply, which is not shown, is connected using a one-touch pipe connector (not shown) that is commonly used in the connection between the pipe and the pipe.

Preferably, for floor ondol, both a heating system using electricity and a heating system using hot water can be used very effectively. However, when used as a self-supporting radiator type, hot water type heating system can be used more effectively than electric since many heat radiation fins must be provided in double layers.

Figure 7 is a view showing an example applied to the ondol using the ultra-low power triple structure heat pipe heating system for floor ondol according to the present invention.

Referring to FIG. 7, the ultra-low power triple heat pipe floor heating system according to the present invention includes a supply pipe and a supply pipe 130 for supplying and recovering disposed side by side in a central portion of the bottom 11, and inside the filling pipe 130. Auxiliary tube and the heater 110 is built-in, each of the filling tube 130, a plurality of heat dissipation fins 140 are extended to the edge side of the floor 11, each of the heat dissipation fins 140 at the end of the heat dissipation fins 140 The wings 150 are formed in communication with the fields.

Examples of the application of the heating system (100, 200) according to the present invention, such as room, living room, bathroom, mall, dormitory, motel, pension, villa, apartment, house, power house, bungalow, ship, agricultural plastic house, etc. It can be applied wherever it is needed.

As described above, the ultra-low power triple heat pipe heating system according to the present invention is not only prevents heat loss due to preheating with fast heat transfer at high speed, and is advantageous for mobile heating. In addition, there is an advantage of excellent thermal efficiency with ease of construction, durability, long life.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art can be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims You will understand.

Claims (3)

A heater composed of any one of a heater rod using electricity as a heat source or a hot water pipe using hot water as a heat source; An auxiliary pipe made of copper pipe into which the heater is inserted; A vacuum filling tube made of copper pipe in which the auxiliary tube is inserted and a heating medium is filled therein; A plurality of heat dissipation fins extending outwardly on one side on the outer circumferential surface of the filling tube and communicating with the filling tube; Ultra-low power triple structure heat pipe heating system comprising a wing connected to the heat dissipation fins and connected to the ends of the heat dissipation fins. In the radiator type heating system consisting of a filling tube zigzag extending in one row or several rows, a heat dissipation fin integrally formed on the upper side of the filling tube, and a wing connecting the ends of the heat dissipation fins in communication with each other, The structure of the filling tube is a heater consisting of any one of the heater rod using electricity as a heat source, or a hot water pipe using hot water as the heat source, an auxiliary pipe made of a copper pipe to which the heater is inserted, and the auxiliary pipe An ultra-low power triple structure heat pipe heating system comprising a vacuum pipe formed of a copper pipe inserted and filled with a heat medium, and connecting the wings to each other. According to claim 2, The ultra-low power triple structure heat pipe heating system is connected to a plurality of uses for a wide range of use in the other side of the heater is formed integrally with the discharge cap is further extended discharge cap is discharged therein The terminal is formed, and the one side of the heater is formed integrally with the supply connection cap for extending the filling tube is integrally formed, the supply terminal is characterized in that the ultra-low power triple structure heat pipe heating system.

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