KR102065787B1 - air cleaning building - Google Patents

Abstract

The present invention relates to a new air purifying structure, which can improve a surrounding environment by effectively purifying fine dust and ultrafine dust in air. The air purifying structure according to the present invention comprises a plurality of air purifying means (B) installed on a circumferential part of a structure (A) having a high height such as an apartment or commercial building. The air purifying means (B) include: a purification tower (10) extending vertically and having an inlet (11) formed at a lower end thereof and an outlet (12) formed at an upper end thereof; an air circulation means (C) provided in the purification tower (10) to allow external air to be sucked into the inlet (11) of the purification tower (10) and then to be discharged to the outlet; and a filtering means (70) provided in the inlet (11) of the purification tower (10) to purify the air sucked into the inlet (11). Accordingly, fine dust and ultrafine dust included in air around the structure (A) are purified and discharged, thereby effectively removing various contaminants including the fine dust and ultrafine dust in air, and fundamentally solving a problem generated by the fine dust and ultrafine dust.

Description

Air cleaning building

The present invention relates to an air purification structure of a new structure that can effectively clean the fine dust and ultrafine dust in the atmosphere to improve the surrounding environment.

In general, the smoke emitted from a factory or the exhaust gas generated from a vehicle includes a large amount of fine dust and ultrafine dust, and inhaling such fine dust and ultrafine dust adversely affects the human body.

Therefore, recently, by providing a mask for fine dust or an air purifier, when the concentration of fine dust and ultrafine dust is increased, people who wear a mask or operate the air purifier to minimize the inhalation of fine dust and ultrafine dust This is increasing.

However, this method has a problem that it is difficult to solve the problem of fine dust and ultra-fine dust fundamentally.

Therefore, there is a need for a new method to solve this problem.

On the other hand, in recent years, many rectangular structures, such as apartments and commercial buildings, have been built.

Patent Publication No. 10-2007-0081791,

The present invention has been made to solve the above problems, and an object thereof is to provide an air purification structure of a new structure that can effectively clean the fine dust and ultrafine dust in the atmosphere to improve the surrounding environment.

The present invention for achieving the above object, in a high-height structure (A), including apartments, commercial buildings, etc., comprising a plurality of air purifying means (B) provided on the periphery of the structure (A) In addition, the air purifying means (B) extends in the vertical direction, the inlet 11 is formed at the bottom and the exhaust port 12 is formed in the upper end and the purification tower 10, the purification tower 10 is provided on the outside Air circulating means (C) which sucks air into the inlet 11 of the purification tower 10 and discharges it to the outlet, and the inlet 11 of the purification tower 10 to the inlet 11 It is provided with an air purification structure, characterized in that it comprises a filtering means for purifying the air sucked.

According to another feature of the invention, the filtering means 70 is provided in the suction passage 71 extending laterally from the suction port 11, the middle portion of the suction passage 71 and the suction passage 71 Provided is an air purification structure comprising a purifying filter (72) for filtering contaminants contained in air passing therethrough.

According to another feature of the invention, the structure (A) is composed of a square, the purification tower 10 is composed of four air is characterized in that it is provided to be embedded in each corner portion of the structure (A) Purification structures are provided.

According to another feature of the invention, the structure (A) is composed of a square, the purification tower 10 is composed of four is provided to be close to each corner portion of the structure (A) support member 80 Air purification structure is provided, characterized in that connected to be supported by the structure (A) by.

According to another feature of the invention, the air circulation means (C) is provided on the upper side of the purification tower 10 is heated by sunlight and the heating cylinder 21 is stored inside the heating medium, and the purification tower ( 10, a heat supply cylinder 22 provided on the inner bottom surface of the inner surface, a supply pipe 23 and a return pipe 24 for connecting the heating cylinder 21 and the heat generating cylinder 22, and the supply pipe 23 or return. The air purifying structure is provided, which includes a circulation pump 25 provided in the tube 24 so that the heat medium stored in the heating cylinder 21 is circulated to the heat generating cylinder 22.

According to another feature of the invention, the inner circumferential surface of the purification tower 10 is configured to reflect light, the air circulation means (C) is provided on the upper end of the purification tower 10 and to the control unit 40 Tilt and direction are adjusted by the light condensing unit 30 for condensing the sunlight into the purification tower 10 and the inner bottom surface of the purification tower 10 is purified by the light collecting unit 30 It includes a heating member 50 is heated by the light condensed into the inside of the tower 10, the light collecting unit 30 is provided on the upper side of the purification tower 10 and extends downward on both sides of the lower side A plurality of reflecting plates 32 are coupled to the support ring 31 having a pair of extension portions 31a formed thereon, and the upper and lower surfaces of the support ring 31 to adjust the angle in the vertical direction. And an angle adjusting means 33 connected to the reflecting plate 32 to adjust an angle of the reflecting plate 32. The control unit 40 has a ring-shaped support 41 provided on the outside of the upper end of the purification tower 10, and is rotatably coupled to the support 41 in a lateral direction to rotate the driving means 42b. Is rotated by the upper surface on both sides of the rotary table 42 is provided with a support portion (42a) is extended to the upper side and hinged to the extension portion (31a) of the support ring body 31, the support ring body 31 is connected to the support There is provided an air purification structure comprising an inclined drive means 43 for adjusting the angle of the ring body 31.

According to another feature of the invention, the inner peripheral surface of the purification tower 10 is provided inside the purification tower 10 is provided on one side of the cleaning means 90, and the light condensing unit 30 to the brightness of sunlight A light sensor 61 to measure, a temperature sensor 62 provided on the heating member 50 to measure the temperature of the heating member 50, and one side of the purification tower 10 is provided with a purification tower ( 10) wind speed sensor 63 for measuring the speed of the wind blowing around the periphery, and receives the signals of the light sensor 61, the temperature sensor 62 and the wind speed sensor 63 and the condensing unit 30 And control means 64 for controlling the operation of the control unit 40 and the washing means 90, wherein the control means 64 has a predetermined brightness of the light measured by the light sensor 61. When the temperature of the heating member 50 is lower than the reference level in a state of being raised above the reference, the cleaning unit 90 is operated to operate the inner circumference of the purification tower 10. When the speed of the wind measured by the wind speed sensor 63 rises above a predetermined speed, the angle adjusting means 33 is controlled to rotate the reflecting plate 32 downward. An air purification structure is provided.

Air purifying structure according to the present invention is configured by installing a plurality of air purifying means (B) on the periphery of the high structure (A), such as apartments or commercial buildings, the air purifying means (B) in the vertical direction An inlet 11 is formed at the lower end and an exhaust port 12 is formed at the upper end, and the purification tower 10 is provided in the purification tower 10 so that outside air flows into the inlet 11 of the purification tower 10. Air suction means (C) to be discharged to the outlet after the suction, and filtering means 70 provided in the inlet 11 of the purification tower 10 to purify the air sucked into the inlet 11 By purifying and discharging fine dust and ultrafine dust contained in the air around the structure (A), it is possible to effectively remove various contaminants including fine dust and ultrafine dust in the atmosphere, and fine dust and ultrafine Door caused by fine dust There are advantages to address a fundamental point.

1 is a side cross-sectional view showing an air purification structure according to the present invention;
2 is a plan view showing an air purification structure according to the present invention;
3 is a reference diagram showing a modification of the air purification structure according to the present invention,
Figure 4 is a side cross-sectional view showing a second embodiment of the air purification structure according to the present invention,
5 is a side cross-sectional view showing a third embodiment of an air purification structure according to the present invention;
Figure 6 is an enlarged side cross-sectional view showing the main part of a third embodiment of an air purification structure according to the present invention;
7 is a front view of a third embodiment of an air purifying structure according to the present invention;
8 and 9 are reference views showing the operation of the third embodiment of the air purification structure according to the present invention.

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

1 and 2 show the air purification structure according to the present invention, a plurality of air purification means (B) in the periphery of the structure (A) of high height (preferably 20m or more), such as apartments or commercial buildings It is configured with.

At this time, the structure (A) is configured to form a square when viewed from above.

The air purifying means (B), the air purifying means (B) extends in the vertical direction, the inlet 11 is formed at the lower end and the exhaust tower 12 is formed with an exhaust port 12 at the upper end, and the purification tower 10 Is provided in the air circulation means (C) and the outside air is sucked into the inlet 11 of the purification tower 10 and discharged to the discharge port, and provided in the inlet 11 of the purification tower 10 It consists of a filtering means 70 for purifying the air sucked into the suction port (11).

The purification tower 10 is configured in a rectangular tubular shape extending in the vertical direction, composed of a high-strength concrete structure (A), is composed of four is provided to be embedded in each corner portion of the structure (A).

At this time, the upper end of the purification tower 10 is configured to extend upward compared to the upper end of the structure (A).

The air circulation means (C) is provided in the middle portion of the purification tower 10 uses a fan to supply the outside air to the inlet 11 during operation to be discharged to the outlet.

The filtering means 70 is provided in the suction passage 71 extending laterally from the suction port 11, and is provided in the middle portion of the suction passage 71 and contained in the air passing through the suction passage 71. And a purifying filter 72 for filtering the substance.

The purifying filter 72 is configured to filter out the fine dust and the ultrafine dust contained in the air when the air containing the fine dust and the ultrafine dust passes.

Therefore, when the air circulation means (C) is driven, as shown by the arrow in Figure 1, the air around the structure (A) passes through the filtering means 70, contaminants such as fine dust or ultra-fine dust After removing the contaminants, only the air from which the contaminants have been removed is lifted through the purification tower 10 and then discharged to the outside through the outlet of the top of the purification tower 10.

The air purifying structure configured as described above is configured by installing a plurality of air purifying means B around the periphery of the high structure A, such as an apartment or a commercial building, and the air purifying means B extends in the vertical direction. And a suction inlet 11 formed at the lower end and an exhaust port 12 formed at the upper end thereof, and the external air is provided to the inlet 11 of the purification tower 10. After the air circulation means (C) to be discharged to the outlet and the suction means of the purification tower 10 is provided with a filtering means 70 for purifying the air sucked into the inlet (11) By purifying and discharging fine dust and ultrafine dust contained in the air around the structure (A), it is possible to effectively remove various pollutants including fine dust and ultrafine dust in the air, and fine dust and ultrafine Caused by dust There is an advantage that can solve the problem fundamentally.

In particular, since the purification tower 10 extends in the vertical direction and the inlet 11 is formed at the lower end and the exhaust port 12 is formed at the upper end, a difference in the air pressure generated at the inlet 11 and the exhaust port 12 is used. Air is sucked into the inlet 11 and discharged to the outlet 12.

Therefore, there is an advantage that can minimize the consumption of electricity required to operate the fan that is the air circulation means (C).

In addition, the structure (A) is composed of a square, the purification tower 10 is composed of four is provided to be embedded in each corner of the structure (A), the space required for installation of the air purification means (B) It is easy to ensure that, since the air purification means (B) is supported by the structure (A), there is an advantage that the structural strength of the air purification means (B) is improved.

In the present embodiment, the purification tower 10 is illustrated to be embedded in each corner portion of the structure (A), but the purification tower 10 is composed of four, as shown in FIG. It may be provided to be close to each corner portion of the structure (A).

At this time, the purification tower 10 is connected to the structure (A) by the support member 80.

As such, when the purification tower 10 is installed to be close to the structure A, there is an advantage in that the purification tower 10 may be additionally installed in the existing structure A.

That is, in the case of the first embodiment described above, the purification tower 10 is installed so as to be buried in the corner portion of the structure (A), when constructing the structure (A), the purification tower 10 should be installed, but purification When the tower 10 is installed separately, it is possible to install the purification tower 10 in addition to the existing structure (A).

Figure 4 shows another embodiment according to the present invention, the air circulation means (C) is provided on the upper side of the purification tower 10 is heated by sunlight and the heating cylinder 21 is stored in the heat medium therein And a heating tube 22 provided on the inner bottom surface of the purification tower 10, a supply pipe 23 and a return tube 24 connecting the heating cylinder 21 and the heating cylinder 22. It is composed of a circulation pump 25 provided in the supply pipe 23 or the return pipe 24 to circulate the heat medium stored in the heating cylinder 21 to the heat generating cylinder 22.

The heating cylinder 21 is composed of a metal material having a high thermal conductivity, a spherical shape, the outer peripheral surface is painted in black with high endothermic performance, the support frame 21a to be located above the purification tower 10 by the It is provided on the upper surface of the structure (A).

The heating medium uses various kinds of oils or gases, and after heating in the heating cylinder 21, moves to the heating cylinder 22 to heat the heating cylinder 22.

The heat generating cylinder 22 is made of a metal material having high thermal conductivity, and after the heat medium supplied through the supply pipe 23 passes through the inside, is circulated to the heating cylinder 21 through the return pipe 24. do.

Therefore, when the heating cylinder 21 is heated by sunlight being irradiated to the heat generating cylinder 22, the heat medium inside the heating cylinder 21 is heated.

Then, when the circulation pump 25 is driven, the heating medium heated inside the heating cylinder 21 is supplied to the heating cylinder 22 through the supply pipe 23 to raise the temperature of the heating cylinder 22. Thereafter, it is heated to the heating cylinder 21 through the return pipe 24.

Therefore, repeating this process, the temperature of the heat generating cylinder 22 is raised, thereby improving the temperature of the lower side inside the purification tower (10).

When the temperature inside the purification tower 10 is lowered in this manner, the air inside the purification tower 10 is raised to be discharged to the exhaust port 12 of the purification tower 10, whereby the purification tower 10 ) The internal air pressure is lowered, the outside air is inserted into the purification tower 10 through the inlet 11, the contaminant contained in the air is removed through the filtering means 70, As a process is repeated, it is possible to purify large quantities of air naturally.

The air purification structure configured as described above allows the outside air to be sucked into the inside of the purification tower 10 by using sunlight, thereby reducing electric consumption compared to the first embodiment in which air is forcedly circulated using the fan. There is an advantage.

In the present embodiment, the air circulation means (C) is provided on the upper side of the purification tower (10) is heated by sunlight and the heating cylinder 21, the heat medium is stored therein, and the inside of the purification tower (10) The heating tube 22 provided on the bottom surface, the supply pipe 23 and the return pipe 24 connecting the heating cylinder 21 and the heating cylinder 22, and the supply pipe 23 or return tube 24 Although it is illustrated that the heat medium is stored in the heating cylinder 21 is configured in the circulation pump 25 to be circulated to the heat generating cylinder 22, the first embodiment described above in the middle of the purification tower (10) It is also possible to further include a fan as shown in the above, and to force the air to circulate by using the fan at night when the sun does not rise to perform the purifying action.

5 to 9 show another embodiment according to the present invention, wherein the inner circumferential surface of the purification tower 10 is configured to reflect light.

To this end, a metal plate 13 having a reflective coating is fixed to the inner circumferential surface of the purification tower 10.

In addition, the upper end of the purification tower 10 is formed with an extension pipe portion 14 that extends more than the upper end of the structure (A).

The extension pipe portion 14 is configured in a circular ring shape.

In addition, the air circulation means (C) is provided at the upper end of the purification tower 10, the inclination and direction is adjusted by the control unit 40 to condense the sunlight into the interior of the purification tower 10 30, a heating member 50 provided on the inner bottom surface of the purification tower 10 and heated by light collected by the light converging unit 30 into the purification tower 10, and the purification The inner peripheral surface of the purification tower (10) provided inside the tower (10) and the cleaning means (90), the light sensor (61) for measuring the intensity of sunlight provided on one side of the light collecting unit 30, and the heating The temperature sensor 62 which is provided in the member 50 and measures the temperature of the heating member 50, and the speed of the wind blowing on the circumference of the purification tower 10 provided on one side of the purification tower 10 Wind speed sensor 63 for measuring the signal, the light sensor 61 and the temperature sensor 62 and the signal of the wind speed sensor 63 and the condensing unit 30 and the control unit 40 and control means 64 for controlling the operation of the washing means 90.

As shown in FIG. 6, the light converging unit 30 is coupled to the support ring body 31 provided above the purification tower 10 and the circumferential surface of the support ring body 31 in the vertical direction. The upper surface includes a plurality of reflecting plates 32 formed of reflecting surfaces reflecting light and angle adjusting means 33 connected to the reflecting plates 32 to adjust the angle of the reflecting plates 32.

The support ring 31 has an inner diameter that is wider than the outer diameter of the extension pipe portion 14 and has a rectangular frame shape, and a pair of extension portions 31a extending downward on both sides of the lower side are formed.

The reflecting plate 32 is formed in a plate shape of a metal material of high strength, and is composed of four pieces, and one side of the circumferential surface is hinged to the outer surface of the support ring 31 in a rotatable manner up and down.

The angle adjusting means 33 uses four driving motors coupled to the hinge shafts so that the reflecting plate 32 rotates in an up and down direction according to an operation. Each of the driving motors drives the reflecting plate 32. Each of them is rotated in the vertical direction separately, so that the sunlight is reflected by the reflector 32 to condense the inside of the purification tower 10.

6 to 9, the ring-shaped support 41 provided on the outer side of the upper end of the purification tower 10 and the support 41 is rotatable in the lateral direction. Rotating table 42 is rotatably coupled to the rotary drive means 42b is provided with a support portion 42a which is hinged to the extension portion 31a of the support ring body 31 is extended to the upper side on both sides, and the It is connected to the support ring body 31 is composed of inclined drive means 43 for adjusting the angle of the support ring body 31.

The support 41 has a gear train 41a formed on a circumferential surface thereof.

The rotary drive means 42b is provided on the swivel table 42 and a drive motor having a drive gear 42c meshed with the gear train 41a is used for the drive shaft.

The swivel 42 is rotatably coupled to the outside of the support 41 through a bearing.

The inclined drive means 43 is provided in the support part 42a and is connected to the extension part 31a of the support ring body 31 to use a driving motor to rotate the support ring body 31 up and down in accordance with the operation.

Therefore, as shown in FIGS. 8 and 9, the control means 64 controls the rotation driving means 42b and the inclined driving means 43 so that the rotating table 42 is rotated laterally. At the same time, by allowing the support ring 31 to rotate in the vertical direction, the light converging unit 30 can be adjusted to face the sun.

When the light collecting unit 30 is adjusted to face the sun, the light reflected by the reflecting plate 32 of the light collecting unit 30 passes through the exhaust port 12 of the purification tower 10. Reflected from the inner circumferential surface of the heating) is irradiated to the heating member 50 provided on the lower side to heat the heating member (50).

The heating member 50 is formed in a block shape of a metal material whose upper surface is painted in black, and is heated by light reflected into the purification tower 10 by the light collecting means to lower the inside of the purification tower 10. By heating the air of the air, the air inside the purification tower 10 is discharged to the upper exhaust port 12, the outside air is sucked into the suction port (11).

The cleaning means 90 is configured in a ring shape corresponding to the internal shape of the purification tower 10 is provided in the purification tower 10 and a plurality of injections toward the inner peripheral surface of the purification tower 10 on the outer surface An injection tube 92 provided with a nozzle 92a, a pair of winches 94 provided at an upper end of the purification tower 10 and connected to the injection tube 92 to elevate the injection tube 92; The water supply means 93 is connected to the injection pipe 92 and supplies water to the injection pipe 92.

Therefore, when water is supplied to the injection pipe 92 by using the water supply means 93 while raising and lowering the injection pipe 92 by using the winch 94, the water is purified through the injection nozzle 92a. It is sprayed on the inner circumferential surface of the tower 10 to remove foreign substances attached to the inner circumferential surface of the purification tower 10.

The light sensor 61 is provided on one side of the upper surface of the reflecting plate 32.

The temperature sensor 62 is provided on the upper surface of the heating member 50.

The wind speed sensor 63 is provided at an upper end of the purification tower 10.

The control means 64 is a reference to the temperature of the heating member 50 measured by the temperature sensor 62 in a state in which the brightness of the light measured by the light sensor 61 is raised above a predetermined reference In the following case, it is determined that contaminants are attached to the inner circumferential surface of the purification tower 10 so that the light collected by the light collecting unit 30 into the purification tower 10 may not be reflected by the heating member 50. To operate the washing means 90 to clean the inner circumferential surface of the purification tower 10.

In addition, the control means 64 controls the angle adjusting means 33 when the wind speed measured by the wind speed sensor 63 rises above a predetermined speed, as shown by a dotted line in FIG. 6. In the same manner, the reflecting plate 32 is rotated downward, thereby preventing the reflecting plate 32 from being damaged by wind.

The air purification structure configured as described above is configured such that the inner circumferential surface of the purification tower 10 reflects light, and the air circulation means C is provided at the top of the purification tower 10 and is inclined by the adjustment unit 40. And condensation direction is provided on the inner bottom surface of the condensing unit 30 and the light collecting unit 30 for condensing sunlight into the interior of the purification tower 10, the purification tower (30) 10 is composed of a heating member 50 heated by the light condensed into the interior, by heating the heating member 50 by using the light collected by the condensing means, the suction port of the purification tower 10 naturally External air is sucked into 11 and purified, and then discharged to the exhaust port 12, thereby minimizing electric consumption and further improving the efficiency of purifying air.

A. Structure B. Air Purification Means
10 Purification tower C. Air circulation means
70. Filtering means

Claims (7)

In tall structures (A), such as apartments or commercial buildings,
It includes a plurality of air purifying means (B) provided on the periphery of the structure (A),
The air purifying means (B) is
Purging tower 10 extending in the vertical direction and the inlet 11 is formed at the lower end and the exhaust port 12 is formed at the upper end,
An air circulation means (C) provided in the purification tower 10 to allow the outside air to be sucked into the inlet 11 of the purification tower 10 and then discharged to the exhaust port 12;
It is provided in the inlet 11 of the purification tower 10 includes a filtering means 70 for purifying the air sucked into the inlet 11,
The inner circumferential surface of the purification tower 10 is configured to reflect light,
The air circulation means (C) is provided on the upper end of the purification tower 10, the inclination and direction is adjusted by the control unit 40 to condense the solar light into the interior of the purification tower 10 (30) )and,
It is provided on the inner bottom surface of the purification tower 10 includes a heating member 50 is heated by the light collected by the light collecting unit 30 into the interior of the purification tower 10,
The condensing unit 30 is provided on the upper side of the purification tower 10, and a support ring body 31 having a pair of extension portions 31a extending downward on both sides of the lower side, and the support ring body 31. It is coupled to adjust the angle in the vertical direction to the circumferential surface and the upper surface is a plurality of reflecting plate 32 consisting of a reflecting surface for reflecting light, and the angle adjusting means connected to the reflecting plate 32 to adjust the angle of the reflecting plate 32 ( 33),
The control unit 40 is rotatably coupled to the support of the ring-shaped support 41 provided on the outside of the upper end of the purification tower 10, the support 41 by the rotary drive means 42b Rotating table 42 having a support portion 42a which is rotated and extends upward on both sides of the upper surface and is hinged to the extension portion 31a of the support ring body 31, and is connected to the support ring body 31 to support ring body ( 31, the inclination driving means 43 for adjusting the angle,
It is provided inside the purification tower 10, the inner peripheral surface of the purification tower 10, the cleaning means 90, and provided on one side of the condensing unit 30, a light sensor 61 for measuring the brightness of sunlight; The temperature sensor 62 is provided in the heating member 50 to measure the temperature of the heating member 50, and the wind blowing on the circumference of the purification tower 10 provided on one side of the purification tower 10 Wind speed sensor 63 for measuring the speed of the light, the light sensor 61 and the temperature sensor 62 and the signal of the wind speed sensor 63 receives the condensing unit 30 and the control unit 40 and washing means Further comprising control means 64 for controlling the operation of the 90,
The control means 64, when the temperature of the heating member 50 is below the reference value in the state in which the brightness of the light measured by the light sensor 61 is raised above a predetermined reference, the cleaning means 90 Operate to clean the inner circumferential surface of the purification tower 10, and if the wind speed measured by the wind speed sensor 63 rises above a predetermined speed, by controlling the angle adjusting means 33, the reflection plate ( 32) is air cleaning structure, characterized in that to rotate downward.
The method of claim 1,
The filtering means 70
A suction passage 71 extending laterally from the suction port 11,
And a purification filter (72) provided at an intermediate portion of the suction passage (71) to filter contaminants contained in the air passing through the suction passage (71).
The method of claim 1,
The structure A is composed of a square,
The purification tower (10) is composed of four air purification structure, characterized in that it is provided to be embedded in each corner portion of the structure (A).
The method of claim 1,
The structure A is composed of a square,
The purification tower (10) is composed of four air cleaning structure, characterized in that provided to be close to each corner portion of the structure (A) is connected to support the structure (A) by a support member (80).
The method of claim 1,
The air circulation means (C)
It is provided on the upper side of the purification tower 10 is heated by sunlight and the heating cylinder 21 is stored inside the heat medium,
A heat generating cylinder 22 provided on the inner bottom surface of the purification tower 10;
A supply pipe 23 and a return pipe 24 connecting the heating cylinder 21 and the heating cylinder 22;
And a circulation pump (25) provided in the supply pipe (23) or the return pipe (24) to circulate the heat medium stored in the heating cylinder (21) to the heat generating cylinder (22). delete delete

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