WO2020045999A1 - Heat-accumulating radiator heating device also configured to generate warm wind - Google Patents

Abstract

The present invention relates to a heat-accumulating radiator heating device also configured to generate a warm wind, which employs a heat pipe. More specifically, a heating case is formed inside and at a distance from an outer case in a double structure. A heat-accumulating discharge tube is vertically installed inside the heating case so as to quickly move air inside the outer case in the upward direction. A heat pipe is vertically installed outside the heat-accumulating discharge tube so as to be heated by an underlying heater heating portion. A warm-wind discharge port and an air inflow port are formed in the front and rear sides of the upper portion of the outer case, respectively. Openings are formed in the front and rear sides of the upper portion of the heating case so as to be connected to the warm-wind discharge port and the air inflow port of the outer case, respectively. Accordingly, a warm wind is formed by heat from the heat pipe and is discharged forwards through the warm-wind discharge port, or heat is radiated from the radiator, thereby conducting double-type heating. Particularly, the heating case has a heat-accumulating member inserted outside the heat pipe and heat-radiating members inserted into the upper portion of the heat-accumulating member and into the heat-accumulating discharge tube, respectively, such that heat is radiated while storing the heat source of the heat pipe. Accordingly, not only can the heating efficiency be substantially improved compared with the prior art, but the heat pipe can be formed to have a larger length than the prior art, thereby providing a characteristic feature in that the heating device can be manufactured to have a large-capacity size.

Description

Regenerative Hot Air Radiator Heating

The present invention relates to a heating apparatus for a heating device for combined use of hot air using a heat pipe, and more specifically, the outer case and the heat generating case are formed in an inner and outer double structure, and generate warm air as a heat source by the heat pipe installed in the heat generating case. Heats the heat pipe of the heat pipe by heat storage member and heat dissipation member, and heats and heats the heat source of heat pipe. The present invention relates to a regenerative hot air combined radiator heating device that can be formed longer and can be manufactured in a large size.

In general, the radiator heating device dissipates heat to the outside while moving steam generated by the boiler operation through the heat exchange tube or heats the medium inside the heat exchange tube by an electric heater to convert it to steam, thereby dissipating heat to the outside. Was done.

In the former case, since the steam is generated by the operation of the boiler, the fuel cost is excessive, the pollution of the air environment or the risk of fire is high, and in the latter case, the consumption of power is consumed instead of the occurrence of less pollution.

In this regard, the present applicant has previously applied for a radiator heating device that uses a vacuum spiral heat pipe to increase the heating efficiency while reducing pollution source and power consumption, which is the first and second spirals as in Patent No. 10-1290833. Heat is dissipated through the first and second heat dissipation pipes connected to the joint pipes while passing through the spiral inside of the heat pipes and the first and second heat pipes, thereby heating the heaters. It can be applied to indoor and outdoor heating as well as seat heating under the chair.

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

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

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

Second, since the heating device does not have a separate heat storage means capable of accumulating heat generated by the heat pipe, the heating efficiency is reduced, and thus the length of the heat pipe may be formed to a short length of 2.5 m or less. It has a disadvantage that can not manufacture a large amount of heating device had a limitation.

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

The present invention has been invented to solve the above-mentioned problems of the prior art, the outer case and the heat generating case is formed in the inner and outer double structure, by generating a warm air to the heat source by the heat pipe installed in the heat generating case or discharged The heating is carried out in a dual manner by the heat radiation of the radiator, the heat storage member and the heat dissipation member is built in the heat generating case to accumulate and heat the heat source of the heat pipe to improve the heating efficiency.

The present invention is to heat storage and heat dissipation by the heat storage member and the heat dissipation member of the heat pipe, so that the length of the heat pipe can be formed longer than before, the purpose is to be able to manufacture a large capacity size.

The present invention and the outer case to form a hot air outlet, air inlet in the front, rear; Spaced apart from each other inside the outer case is installed to form a space space and the upper and rear air outlets, forming an opening communicating with the air inlet of the outer case, at least one heat storage discharge pipe vertically from the bottom to the top inside A heating case installed to rapidly move the air of the spaced apart portion; A heat pipe installed vertically outside the heat storage discharge pipe inside the heat generating case, forming a hollow pipe in the form of a coil spring, embedding the heat medium in a vacuum state therein, and installing and installing a heater heating unit at a lower portion thereof; A heat storage member configured to accumulate a heat source discharged from the heat pipe by filling the outside of the heat pipe in an inner lower portion of the heat generating case; The heat storage member is inserted into the heat storage member upper part and the heat storage discharge pipe inside the heat generating case, and the heat dissipation member is configured as a heat dissipation member for discharging the air passing through the opening-heating air outlet of the heat storage case and the heat storage discharge pipe to discharge the warm air. .

According to the present invention, a lower portion of the heat storage discharge pipe is characterized in that the blower fan is installed to generate a greater intensity of the warm air while sucking the air warmed from the spaced apart space portion and pumped to the upper portion.

According to the present invention, the heat storage member has a heat storage function, and the heat dissipation member is formed of a material having a heat storage and heat dissipation function, and is characterized in that it is formed so that the ventilation of the heat dissipation member is made better than the heat storage member.

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

The present invention forms a heat generating case spaced apart in a double structure inside the outer case, vertically installed a heat storage discharge pipe for rapidly moving the air inside the outer case inside the heat generating case, the heater heating unit of the lower portion outside the heat storage discharge pipe The heat pipe heated by the vertical installation, but the hot air discharge port and the air inlet in the front and rear of the outer case, the hot air outlet and the opening to the air inlet of the outer case before and after the upper portion of the heat generating case The hot air formed by heating by the pipe is discharged forward through the hot air discharge port or is heated in a dual manner by radiating heat from the radiator. In particular, the heat generating case is inserted into a heat storage member, a heat storage member on the outside of the heat pipe and the heat storage member inside the heat storage discharge pipe to store the heat source of the heat pipe to radiate heat, thereby having an effect of greatly improving heating efficiency.

In addition, the surface temperature of the outer case is lowered by the double structure than the conventional has the effect of minimizing the risk of burns and the like.

In addition, since the heat source of the heat pipe is thermally accumulated and radiated by the heat storage member and the heat radiation member, the length of the heat pipe can be formed longer than before, so that the heat pipe can be manufactured in a large size, thereby 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 front sectional view of the apparatus of the present invention.

3 is a side cross-sectional view of the device of the present invention.

4 is an enlarged view of a portion “A” of FIG. 3.

5 is a front view showing a heat pipe of the apparatus of the present invention.

Figure 6 is an excerpt of the main portion showing another embodiment of the device heat storage discharge pipe of the present invention.

Figure 7 is a photograph showing an example of the heat storage member of the present invention.

Figure 8 is a photograph showing an example of the heat dissipation member of the present invention

9 is a side cross-sectional view showing an operating state of the device of the present invention.

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

The regenerative hot air combined radiator heating device of the present invention has an outer case 10, a heat generating case 20, a heat pipe 30, and heat storage as shown in FIGS. 1 to 5 for heating by a warm air and a radiator method. It consists of the member 40 and the heat dissipation member 50.

The outer case 10 may be formed of a metal material having excellent thermal conductivity, but may form a plurality of convex-convex air contact protrusions to widen the heat dissipation area in order to improve the heat dissipation function of the radiator, and may be moved below. It is configured by installing a moving wheel (13).

And the outer case 10 is configured by forming a hot air discharge port 11 for discharging the warm air in the upper front, an air inlet 12 for introducing external air in the rear.

The heat generating case 20 is installed in a double structure so as to be spaced apart inside the outer case 10 to form a spaced space portion 15, and the lower case 18 is installed to support the lower pedestal 18.

In addition, before and after the upper portion of the heat generating case 20, a hot air outlet 21, an opening 22 communicating with the air inlet 11 of the outer case is formed, the hot air outlet 21 and the Between the air inlet 11 of the outer case is configured to be hermetically connected to the insulation packing 17 is inserted into the outer circumference.

In addition, at least one vertically installed heat storage discharge pipe 25 having a 2/3 height position from the bottom to the inside of the heat generating case 20 is heated in the spaced space 15 through the heat storage discharge pipe. It is comprised so that a rapid upward movement to an inner upper part may be carried out.

At this time, the blower fan 26 may be installed in the lower portion of the heat storage discharge pipe 25 to suck the air warmed from the spaced space portion 15 and pump it to the upper portion while generating the warm air intensity. Of course.

The heat pipe 30 is installed vertically out of the heat storage discharge pipe 25 inside the heat generating case 20, and forms a hollow pipe in the form of a coil spring to embed the heat medium in a vacuum state therein and to generate a heater heating part at the bottom. Combining and installing the 31 is configured by combining 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, the vacuum pressure regulating valve 32 is inside the heat pipe as set forth in the applicant's prior application Of course, it can be applied to various structures that can control the vacuum state of the.

The heat storage member 40 is a heat storage function, the heat dissipation member 50 is formed of a variety of materials having a heat storage and heat dissipation function, it is formed so that the ventilation of the heat dissipation member 50 is better than the heat storage member 40 Configure.

That is, the heat storage member 40 and the heat dissipation member 50 are formed of a cutting tip generated when cutting a metal or non-ferrous metal, for example, 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) material, the heat storage member is 1.5 to 2 mm thick, the heat dissipation member is formed to be 3 to 4 mm thick for the difference in breathability 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. It is possible to manufacture a large-sized device for large capacity heating.

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

Next will be described the operation and action of the present invention configured as described above.

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

As such, the heat in the heat dissipation operation of the heat pipe 30 and the outer case 10 is heated by the heat dissipation operation of the heat pipe 30, whereby the outer case 10 is heated to radiators. The heat dissipation operation of the outside space is to operate the heating.

On the other hand, the air warmed in the spaced space portion 15 inside the outer case 10 is rapidly rising to the inner upper portion of the heat generating case through the heat storage discharge pipe 25 is installed vertically in the heat generating case 15, The heat pipe is heated by the heat pipe outside the heat storage discharge pipe to move up rapidly.

At this time, the blower fan 26 is installed at the lower portion of the heat storage discharge pipe 25 to suck the air warmed up in the spaced space portion 15 inside the outer case to smoothly transport the upper portion to move upward.

Thus, the warm air moved to the inner upper portion of the heat generating case 20 through the heat storage discharge pipe 25 is heated together with the external air introduced through the external air inlet 11 of the outer case 11-the opening 22 of the heat generating case. Then, it is discharged to the front through the hot air discharge port 21 in front of the heat generating case and the hot air discharge port 11 in front of the outer case to be heated by the warm air.

That is, the present invention is excellent in heating efficiency because the heat generated by the heat source by the heat pipe inside the heat generating case is discharged or heated in a dual manner by radiator heat dissipation.

In addition, the present invention is to heat the heat source of the heat pipe by inserting the heat storage member 40, the heat storage member 40 and the heat storage member upper portion and the heat storage discharge pipe 25 inside the heat pipe inside the heat generating case 10 and By making the heat dissipation will increase the heating efficiency.

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

In this way, the heat source of the heat pipe 30 is regenerated by the heat storage member 40 to more effectively heat the air in the space of the space inside the outer case, or the heat radiation member 50 inside the heat storage member and the heat storage discharge pipe 25. By heating the heat storage discharge pipe 25 and the warm air (air) passing through the heat generating case to be smoothly moved by the heat dissipation member while moving smoothly to increase the heating effect.

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 longer than that of the prior art to about 3.5 m. The device can be manufactured in a large size.

Claims (4)

1. An outer case 10 forming a hot air outlet 11 and an air inlet 12 before and after the upper part,

   It is installed to form a spaced space 15 spaced apart from each other inside the outer case and forms an opening 22 to communicate with the hot air outlet 21, the air inlet 11 of the outer case before and after the upper, A heat generating case 20 for vertically installing at least one heat storage discharge pipe 25 from the bottom to the inside to rapidly move the air of the space 15 apart from each other;

   Vertically installed outside the heat storage discharge pipe 25 in the heat generating case 20, the hollow pipe is formed in the form of a coil spring to embed the heat medium in a vacuum state therein and install the heater heating unit 31 in the lower portion With heat pipe 30 to say,

   A heat storage member 40 filling the inner bottom of the heat generating case 20 to the outside of the heat pipe and accumulating the heat source discharged from the heat pipe; and an upper heat storage member and the heat storage discharge pipe 25 on the inner upper portion of the heat generating case 20. Regenerative hot air, which is inserted into the opening 22 of the heat storage and heat generating case-a hot air discharge port 21, heat dissipation member 50 to heat the air passing through the heat storage discharge pipe 25 to discharge the hot air. Combined radiator heating.
2. The method of claim 1,

   The heat storage type radiator heating unit is characterized in that the blower fan 26 is installed in the lower portion of the heat storage discharge pipe 25 so as to suck the air warmed from the spaced space portion 15 and pump it to the upper portion to generate a higher intensity of warm air. Device.
3. The method of claim 1,

   The heat storage member 40 is formed of a heat storage function, the heat dissipation member 50 is formed of a material having a heat storage and heat dissipation function, it is configured to be formed to better ventilate the heat dissipation member 50 than the heat storage member 40 Radiator-type hot air combined radiator heating device.
4. The method of claim 3,

   The heat storage member 40 and the heat dissipation member 50 are formed of a cutting tip generated when cutting a metal or non-ferrous metal material, the heat storage member 40 is an aluminum (AL) material, the heat dissipation member 50 ) Is an aluminum (AL) and stainless steel (SUS) material, the heat storage member is a heat storage type radiator heating device characterized in that the heat radiation member is formed by forming a thickness of 1.5 ~ 2 mm, 3 ~ 4 mm.

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