KR102125699B1 - Heating radiator combined with warm air of heat storage type - Google Patents

Abstract

The present invention relates to a heating device for a heat storage type combined use of a heat pipe using a heat pipe, and more specifically, a heating case is formed in a double structure spaced apart inside the outer case, and the air inside the outer case is rapidly elevated inside the heating case. The heat storage discharge pipe is vertically installed, and a heat pipe heated by the heater heating part at the bottom is installed on the outside of the heat storage discharge pipe vertically, but before and after the upper portion of the outer case, the hot air outlet and the air inlet, and before and after the upper portion of the heating case To form a hot air outlet and an opening that is connected to the air inlet of the outer case, the hot air formed by the heat pipe is discharged to the front through the hot air outlet or heated in a dual manner by heat dissipation of the radiator. In particular, the heat-generating case inserts a heat storage member on the outside of the heat pipe, an upper heat storage member and a heat radiation member inside the heat storage discharge pipe to store and radiate heat while storing the heat source of the heat pipe, thereby greatly improving heating efficiency as well as improving the length of the heat pipe. Since it can be formed longer, it is possible to manufacture a heating device in a large size.

Description

Heating radiator combined with warm air of heat storage type

The present invention relates to a radiator heating device for a combined use of warm air using a heat pipe, and more specifically, to form an outer case and a heating case in a double structure inside and outside, and generates warm air as a heat source by a heat pipe installed in the heating case. To heat or radiate heat from the radiator, but heat storage and heat dissipation of heat pipes are built-in inside the heat-generating case to heat and heat, thereby improving heating efficiency and reducing the length of the heat pipe. The present invention relates to a heat-storage-type radiator heating device that can be formed longer and can be manufactured in a large size.

In general, the radiator heating device radiates heat to the outside by dissipating heat to the outside by dissipating heat while moving the steam generated by the boiler operation through the heat exchanger tube or by heating the heat medium inside the heat exchanger tube with an electric heater. To do.

In the former case, since steam is generated by the operation of the boiler, the fuel cost is excessive, and there is a disadvantage in that there is a high risk of pollution or fire in the atmospheric environment.

Accordingly, the present applicant has previously applied for a radiator heating device that increases heating efficiency while reducing pollution sources and power consumption by using a vacuum spiral heat pipe, which is the first and second spiral type as in Patent No. 10-1290833. As it passes through the inner side of the heat pipe and the first and second heat pipe spirals and heats through heat dissipation through the first and second heat dissipation pipes connected to the joint pipe, the energy consumption is significantly reduced within the case volume range of the heating device, while heating efficiency It was made to be applicable to seat heating under the chair as well as indoor and outdoor heating.

However, the applicant's prior application technology has the following problems.

First, the heating device is limited to a radiator method through heat dissipation by a heat pipe, so there is a limitation in that heating efficiency is limited.

In addition, since the heat is dissipated by the radiator method, there is a problem in that the temperature on the surface of the device is high and there is a risk of burns.

Second, the heating device does not have a separate heat storage means capable of accumulating heat generated by the heat pipe, and thus the heating efficiency is lowered, and thus, the length of the heat pipe is only shorter than 2.5 m. It has a limitation that cannot be manufactured in large quantities because it has a disadvantage that cannot be produced.

That is, there was a limit that cannot maximize the efficiency of use of the heating device.

Registered Patent No. 10-1290833 (July 23, 2013) Registered Patent No. 10-1125323 (March 02, 2012)

The present invention was invented to solve all the problems of the above-described prior art, the outer case and the heating case is formed of a double structure inside and outside, and generates and discharges warm air as a heat source by a heat pipe installed in the heating case or The heating is performed in a dual manner by radiating heat from the radiator, but the purpose is to improve the heating efficiency by storing and heating the heat source of the heat pipe by embedding a heat storage member and a heat radiation member inside the heat generating case.

The present invention aims to enable the heat source of the heat pipe to be heat-stored and dissipated by a heat storage member and a heat dissipation member, so that the length of the heat pipe can be formed longer than in the prior art and thus can be manufactured in a large size.

The present invention is an outer case forming a hot air outlet, air inlet in the front and rear of the upper portion; It is installed to be spaced apart from each other inside the outer case, and forms an opening for communicating with the air inlet of the outer case and a warm air outlet at the front and rear, and vertically at least one heat storage discharge pipe from the bottom to the top inside. A heating case installed to rapidly move the air in the spaced apart portion; A heat pipe installed vertically outside the heat storage discharge pipe inside the heat generating case, and forming a hollow pipe in the form of a coil spring to embed a heat medium in a vacuum state therein and to install a heater heating part coupled to the bottom; A heat storage member filled with the outside of the heat pipe on the inner bottom of the heating case to accumulate heat sources emitted from the heat pipe; It is characterized in that it consists of a heat storage member that is inserted into the heat storage member upper part and the heat storage discharge pipe inside the heat generating case to heat the air passing through the heat storage and heat generating case, and the air passing through the heat storage discharge pipe to discharge it with warm air. .

According to the present invention, there is a feature in that a fan installed in the lower portion of the heat storage discharge pipe is installed to suck the air warmed from the spaced portion and pressurize the air upward to generate a greater intensity of warm air.

According to the present invention, the heat storage member is formed of a material having a heat storage function and the heat dissipation member is a heat storage and heat dissipation function.

According to the present invention, the heat storage member and the heat radiation member are formed of a cutting tip generated when cutting a metal or non-ferrous metal material, wherein the heat storage member is aluminum (AL) material, and the heat radiation member is aluminum (AL). As a stainless steel (SUS) material, the heat storage member has a thickness of 1.5 to 2 mm, and the heat radiation member has a thickness of 3 to 4 mm.

In the present invention, the heat generating case is spaced apart in a double structure inside the outer case, and a heat storage discharge pipe for rapidly moving air inside the outside case is vertically installed inside the heat generating case, and a heater heating part at the bottom outside the heat storage discharge pipe. Heat pipes are heated vertically, but heat is formed by forming hot air outlets and air inlets at the front and rear of the outer case, and hot air outlets at the front and rear of the heating case and openings connected to the air inlets of the outer case. The hot air formed by the pipe is discharged to the front through the hot air discharge port or the heating is performed in a dual manner by radiating heat from the radiator. In particular, the heat-generating case has a heat-storing member outside the heat pipe, and a heat-radiating member is inserted inside the heat-storing member and inside the heat-storing discharge pipe to store and heat-dissipate while storing the heat source of the heat pipe, thereby significantly improving heating efficiency.

In addition, it has the effect of minimizing the risk of burns, etc. by lowering the surface temperature of the outer case than the conventional by the dual structure.

In addition, since the heat source of the heat pipe is heat-stored and dissipated by the heat-storage member and the heat-radiating member, the length of the heat pipe can be formed longer than before, so that it can be manufactured in a large-sized size, thereby greatly improving the efficiency of use. To have.

1 is a front view showing the appearance of the device of the present invention.
2 is a cross-sectional view of the device of the present invention.
3 is a side sectional view of the device of the present invention.
FIG. 4 is an enlarged view of part “A” of FIG. 3.
5 is a front view showing the heat pipe of the device of the present invention.
Figure 6 is a main part excerpt showing another embodiment of the device heat storage discharge pipe of the present invention.
7 is a photograph showing an example of the heat storage member of the present invention.
8 is a photograph showing an example of the heat dissipation member of the present invention
9 is a side sectional view showing the operating state of the device of the present invention.

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

The heat-storage type radiator heating device of the present invention combines the external case 10, the heating case 20, the heat pipe 30, and heat storage as shown in FIGS. 1 to 5 to perform heating by the warm air and the radiator method. It consists of a member 40 and a heat radiation member 50.

The outer case 10 is formed of a metal material having excellent thermal conductivity, but a plurality of uneven air contact protrusions can be formed to increase the heat dissipation area to improve the heat dissipation function of the radiator around the outside, and can be moved to the lower part. So as to install the moving wheel 13 is configured.

In addition, the outer case 10 is configured by forming a warm air outlet 11 for discharging warm air in the upper front and an air inlet 12 for introducing external air in the rear.

The heating case 20 is installed in a dual structure to be spaced apart from the inside of the outer case 10 to form a spaced portion 15, the lower portion of the heating case is installed to support the lower pedestal 18.

In addition, the front and rear of the upper heating case 20 forms a hot air outlet 21, an opening 22 communicating with the air inlet 11 of the outer case, and the hot air outlet 21 of the heating case Between the air inlet 11 of the outer case is configured to be tightly connected so that the insulation packing 17 is inserted around the outside.

And at the inside of the heating case 20, at least one of the heat storage discharge pipes 25 located at a height of 2/3 from the floor to the top is vertically installed to heat the air heated in the spaced portion 15 through the heat storage discharge pipes. It is configured to move upward rapidly to the inner upper part.

At this time, a blower fan 26 may be installed at the lower portion of the heat storage discharge pipe 25 to suck the air warmed from the spaced portion 15 and pressurize it to the upper portion to generate a greater intensity of warm air as shown in FIG. 6. Yes, of course.

The heat pipe 30 is vertically installed outside the heat storage discharge pipe 25 inside the heat generating case 20, but a hollow pipe is formed in the form of a coil spring to embed a heat medium in a vacuum state, and a heater heating part at the bottom. (31) is coupled to the installation and is configured by installing the vacuum pressure control valve (32) on the top.

Here, the heat pipe 30 may be configured by manufacturing the inside in a vacuum state without a vacuum pressure regulating valve on the top, and the vacuum pressure regulating valve 32 is inside the heat pipe as suggested in the pre-application invention of the applicant. Of course, it can be applied to a variety of structures that can control the vacuum state of the.

The heat storage member 40 is formed of a variety of materials having a heat storage function, and the heat dissipation member 50 has heat storage and heat dissipation functions, but is formed so as to achieve better ventilation of the heat dissipation member 50 than the heat storage member 40 Make up.

That is, the heat storage member 40 and the heat dissipation member 50 are formed of, for example, a cutting tip generated when cutting a metal or non-ferrous metal material, and the heat storage member 40 is made of aluminum (AL) material, The heat dissipation member 50 is formed of aluminum (AL) and stainless steel (SUS), and for heat-permeable difference, the heat storage member is 1.5 to 2 mm thick, and the heat dissipation member is 3 to 4 mm thick. desirable.

In addition, the present invention can increase the heating efficiency by the heat storage and heat dissipation function by the heat storage member 40 and the heat dissipation member 50, as well as to form the length of the heat pipe 30 to about 3.5m longer than before. Therefore, it is possible to manufacture a device of a large size for heating a large capacity.

As an unexplained reference numeral, 19 denotes an operation unit provided in front of the outer case to operate power on, off, and the like.

The following is a look at the operation and operation of the present invention configured as described above.

In the heating apparatus of the present invention, when the power is turned on, the heat pipe 30 vertically installed in the heating case 20 inside the outer case 10 is heated by the heater heating part 31 in the lower portion to the heat pipe. The built-in thermal medium converts to steam, and heat dissipates.

In this way, the air in the space 15 between the heating case 20 and the outer case 10 is heated by the heat dissipation operation of the heat pipe 30, whereby the radiator is heated while the outer case 10 is heated. The heat dissipation operation of will heat the external space.

On the other hand, the air heated in the spaced portion 15 inside the outer case 10 is rapidly moved upward to the inner upper portion of the heating case through the heat storage discharge pipe 25 vertically installed inside the heating case 15, the It is heated again by the heat pipe outside the heat storage discharge pipe and moves rapidly.

At this time, a blower fan 26 is installed at the lower portion of the heat storage discharge pipe 25 to suck the air warmed from the spaced portion 15 inside the outer case and more smoothly pressurize the air to move upward.

As described above, the warm air moved to the inner upper portion of the heating case 20 through the heat storage discharge pipe 25 is heated together with the external air flowing through the external air inlet 11 of the external case-the opening 22 of the heating case. It is discharged to the front through the warm air outlet 21 in front of the heating case and the warm air outlet 11 in front of the outer case to perform heating by the hot air.

That is, according to the present invention, the heating efficiency is excellent because the heat is generated by the heat pipe inside the heating case and discharged or the heating is performed in a dual manner by radiator heat radiation.

Furthermore, the present invention heats the heat source of the heat pipe by inserting a heat storage member (40) inside the heat pipe (10) inside the heat pipe and a heat dissipation member (50) inside the heat storage member and the heat storage discharge pipe (25). Since the heat dissipation works, the heating efficiency is further increased.

That is, the heat storage member 40 and the heat dissipation member 50 are formed of cutting tips generated when cutting a metal or non-ferrous metal material. The heat storage member 40 is made of aluminum (AL) material or the heat dissipation member. 50 is made of aluminum (AL) and stainless steel (SUS), and the heat storage member has a thickness of 1.5 to 2 mm, and the heat radiation member has a thickness of 3 to 4 mm, so that the heat radiation member 50 is more breathable than the heat storage member 40. This is to ensure better.

In this way, the heat source of the heat pipe 30 is stored in the heat storage member 40 to heat the air in the spaced space inside the outer case more effectively, or the heat dissipation member 50 inside the heat storage member upper and heat storage discharge pipe 25 By heating the heat storage discharge pipe 25 and the warm air (air) passing through the inside of the heat-generating case while being smoothly discharged by the heat dissipation member, the heating effect is further enhanced.

In addition, since the heat source of the heat pipe is stored and heated by the heat storage member 40 and the heat dissipation member 50, the length of the heat pipe 30 can be formed to a length of 3.5 m or more, which is longer than the conventional heating. The device can be manufactured in a large size.

10: outer case 11: hot air outlet
12: air inlet 15: spaced apart
20: heating case 21: hot air outlet
22: opening 25: heat storage discharge pipe
30: heat pipe 31: heater heating section
40: heat storage member 50: heat dissipation member

Claims (4)

An outer case 10 forming a hot air outlet 11 and an air inlet 12 at the front and rear of the upper part;
It is spaced apart from each other inside the outer case to form a spaced portion 15, and forms an opening 22 communicating with the hot air outlet 21 and the air inlet 11 of the outer case at the front and rear of the upper part, A heating case 20 for vertically installing at least one heat storage discharge pipe 25 from the bottom to the inside to rapidly move the air in the spaced portion 15;
Vertically installed outside the heat storage discharge pipe (25) inside the heating case (20), the hollow pipe is formed in the form of a coil spring to embed a heat medium in a vacuum state, and a heater heating part (31) is coupled to the bottom. And the heat pipe 30,
A heat storage member 40 that heats the heat source discharged from the heat pipe by being filled with the outside of the heat pipe at an inner lower portion of the heating case 20, and an upper heat storage member and a heat storage discharge pipe 25 at an inner upper portion of the heating case 20 It is composed of a heat dissipation member (50) that is inserted inside to heat the air passing through the heat storage and heating case (22), the hot air discharge port (21), and the heat storage discharge pipe (25) to discharge them with warm air.
The heat storage member 40 is formed of a material having a heat storage function and the heat dissipation member 50 is a heat storage and heat dissipation function, but is configured to be formed so that ventilation of the heat dissipation member 50 is better than that of the heat storage member 40 And
The heat storage member 40 and the heat dissipation member 50 are formed of cutting tips generated when cutting a metal or non-ferrous metal material, but the heat storage member 40 is made of aluminum (AL) material and the heat dissipation member 50 ) Is an aluminum (AL) and stainless steel (SUS) material. The heat storage member is 1.5 to 2 mm thick, and the heat radiation member is 3 to 4 mm thick.
According to claim 1,
In the lower part of the heat storage discharge pipe (25), the air heated in the separation space part (15) is sucked and compressed to the upper part, while the blowing fan (26) is installed so as to generate a greater intensity of warm air. Device.
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