KR20140048758A - Heat generating device - Google Patents

Abstract

The present invention relates to a heat generation device and, more specifically, to a heat generation device comprising: a housing having a rotational space part arranged therein, a supply part for introducing fluid into the rotational space part, and a discharge part for discharging the fluid from the rotational space part; a first rotary unit arranged in one side of the housing and making a first drum having a surface rotate in the rotational space part; and a second rotary unit arranged in the other side of the housing and making a second drum having a surface rotate in the rotational space part; wherein the second drum is separated from the first drum at a regular interval to rotate in the opposite direction of the first drum. The first and second rotary units are rotated oppositely to make the friction of the fluid supplied to the rotary space part of the housing; thereby generating heat. The present invention can rotate the introduced fluid at high speed using the first and second rotary units rotating oppositely, can increase friction hours by partially generating vortex, and can generate the high-temperature heat with less power by increasing the frictional area.

Description

Heat generating device

The present invention relates to a generator, and more particularly, it is possible to move the fluid at high speed by rotating the introduced fluid in opposite directions on both sides, and increase frictional force with the fluid to generate high heat with less power. It relates to a heat generating device that can be.

In general, an apparatus for generating heat or thermal energy is used for an engine, a boiler, a turbine, and the like. In the case of a boiler, water is heated and supplied through a supply pipe, and heated by radiant heat of a supply pipe through which the heated water passes. The structure is returned to the pump.

In this case, high heat is generated by using fuel (oil, electricity, or gas) to heat water, and these fuels use fossil fuels in most cases, thus increasing the burden on the consumer in maintenance.

In addition, although recently used solar heat or geothermal heat in place of a portion of the depleted fossil fuel, there is a problem that the heat maintenance is difficult, conditional use is low.

Therefore, in consideration of cost and environment, it is urgently needed to develop a heating device that generates high heat using fossil fuel or minimal use.

Accordingly, the present invention has been made to solve the above problems, the first rotation means and the second rotation means are rotated in opposite directions spaced apart from each other at regular intervals inside the housing and the housing in which fluid is introduced and discharged The purpose of the present invention is to provide a heat generator capable of moving the fluid at high speed, generating partial vortex to increase friction time, and increasing friction area to generate high heat with low power.

The present invention for achieving the above object, has a rotating space therein, a housing having a supply for introducing the fluid to the rotating space portion and the discharge portion for discharging the fluid of the rotating space portion, provided on one side of the housing, the surface The first drum having a first rotating means is rotated in the rotating space portion, and the second drum having a surface is provided to the other side of the housing is rotated in the rotating space portion, spaced apart from the first drum at a predetermined interval And a second rotating means rotated in the opposite direction, wherein the first rotating means and the second rotating means rotate in opposite directions to heat the fluid supplied to the rotating space of the housing by friction. Generates.

Preferably, the housing opens and closes the rotating space portion open to one side and a body having a discharge portion for communicating with the rotating space portion to discharge the fluid, and the open rotating space portion of the body, the rotating space portion It is composed of a cover formed with a supply portion for communicating with the fluid flow in, and is closed between the body and the cover.

The first rotating means may include a first drum installed to be rotatable in a rotating space of the housing, a first motor for rotating the first drum, and a first bearing provided between the rotating shaft of the first drum and the housing. And a first sealing part which prevents the fluid of the rotating space part from flowing out through the first bearing.

The second rotating means may include a second drum installed to be rotatable in the rotating space of the housing, a second motor for rotating the second drum, and a second provided between the rotating shaft of the second drum and the housing. It comprises a bearing, and a second sealing portion for preventing the fluid from flowing out of the rotating space portion through the second bearing.

The second drum is provided to surround the first drum, a second lower drum having a mounting space portion open to one side so that the first drum is positioned, and an open mounting space of the second lower drum. The second upper drum and the second lower drum are fixed and rotated in the same manner.

The second drum may include a second lower drum having a lower space portion open to one side so that the first drum is positioned, and an intermediate space portion therein so that the first drum is positioned, And a second intermediate drum provided at an upper side to open and close the lower support space, an installation hole formed at the center, and a second upper drum to open and close the intermediate space of the second intermediate drum, wherein the second intermediate drum is at least At least one is provided and rotated in the same manner as the second lower drum and the second upper drum, and the first drum is positioned in the lower space and the intermediate space, respectively, and rotates in the opposite direction to the second drum.

And a lower bearing is further provided between the first drum and the second lower drum positioned in the lower space part, and an upper bearing is further provided between the second upper drum and the housing. Maintain the axis of rotation.

In addition, the first drum and the second drum, a plurality of flow paths are formed based on the axis of rotation so that the fluid can be moved through the inside.

In addition, the first drum and the second drum, a plurality of vortex grooves are formed along the outer surface to vortex the fluid during rotation.

In addition, the first drum and the second drum, a plurality of heat generating jaw protrudes along the outer surface to increase the friction area with the fluid.

The supply unit supplies the fluid to the central portion of the first rotating means, and the discharge portion is formed at the side of the housing so that the hot fluid is discharged by the centrifugal force caused by the rotation of the first rotating means and the second rotating means.

In addition, a supply passage is further formed inside the first rotating means and the second rotating means so that the fluid supplied through the supply portion moves, wherein the supply passage is formed to be orthogonal to the rotation axis of the first rotating means. A first supply flow passage having a first horizontal flow passage communicating with the first horizontal flow passage and passing through the first horizontal flow passage through the first horizontal flow passage, and a second horizontal flow passage which is orthogonal to the rotation shaft of the second rotation means; And a second supply passage communicating with the second horizontal passage, the second supply passage having a second vertical passage passing through the second drum along the axis of rotation, wherein a portion of the fluid supplied from the supply portion is connected to the first horizontal passage. A portion of the fluid moved through the first vertical flow path, the portion of the fluid moved through the first vertical flow path is moved to the space between the first drum and the second drum and the second vertical flow path, the fluid moved through the second vertical flow path Through 2 euros Is moved.

In addition, the first drum and the second drum may have a supply groove formed along the outer periphery of the first vertical flow path and the second vertical flow path, thereby temporarily reducing the moving speed of the fluid moved along the first vertical flow path. Increase the amount of fluid supplied at the interval between the second and second drums.

In addition, the fluid is at least one selected from a heat storage liquid and water.

As described above, according to the heat generating apparatus according to the present invention, the first fluid and the second rotating means rotated in the opposite direction to the incoming fluid, as well as to rotate at high speed, to generate a partial vortex It is a very useful and effective invention to increase the friction time and increase the friction area to generate high heat with little power.

1 is a view showing a heat generating apparatus according to the present invention,
2 is an exploded view of a heat generating apparatus according to the present invention,
3 is a view showing a first drum and a second drum of the heat generating apparatus according to the present invention,
4 is a view showing another embodiment of a heat generating apparatus according to the present invention,
FIG. 5 is an exploded view of the heat generator of FIG. 4;
6 is a view showing another embodiment of a heat generating apparatus according to the present invention,
FIG. 7 is an exploded view of the heat generator of FIG. 6.
8 is a view showing an installation state of the heat generating apparatus according to the present invention,
9 is a view showing a state in which a supply passage is further formed in the heat generating apparatus according to the present invention.

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

It should be noted that the present invention is not limited to the scope of the present invention but is only illustrative and various modifications are possible within the scope of the present invention.

1 is a view showing a heat generating apparatus according to the present invention, Figure 2 is a view showing an exploded view of the heat generating apparatus according to the present invention, Figure 3 is a first drum and the first 2 is a view showing a drum, Figure 4 is a view showing another embodiment of the heat generating apparatus according to the present invention, Figure 5 is a view showing an exploded view of the heat generating device of Figure 4, Figure 6 is a present invention FIG. 7 is a view illustrating an exploded view of the heat generator of FIG. 6, and FIG. 8 is a view illustrating an installation state of the heat generator according to the present invention. 9 is a view showing a state in which a supply passage is further formed in the heat generating apparatus according to the present invention.

As shown in the figure, the heat generating device 10 is composed of a housing 100, the first rotating means 200 and the second rotating means 300, the first rotating means 200 and the second rotating means ( As the 300 is rotated in opposite directions, the fluid may move at a high speed to generate heat due to friction.

To this end, the housing 100 has a rotating space portion 112 therein, the supply portion 130 for introducing the fluid into the rotating space portion 112 and the discharge portion 140 for discharging the fluid of the rotating space portion is Is formed.

And the first rotating means 200 is provided to one side of the housing 100, the first drum 210 having a surface is provided so as to rotate in the rotating space 112.

The second rotating means 300 is provided on the other side of the housing 100, the second drum 310 having a surface is rotated in the rotating space 112, spaced apart from the first drum 210 at a predetermined interval to the opposite Rotate in the direction.

In other words, the first rotating means 200 and the second rotating means 300 are rotated in opposite directions so that the fluid supplied to the rotating space portion 112 of the housing 100 flows at high speed and is rubbed with heat. To generate.

As such, the fluid having heat is converted into air conditioning and energy as it moves through the discharge unit 140 and is heat-exchanged.

At this time, the supply unit 130 supplies the fluid to the central portion of the first rotating means 200, the discharge portion 140 is formed on the side of the housing 100 is the first rotating means 200 and the second rotating means ( The hot fluid is automatically discharged by the centrifugal force by the rotation of 300).

Here, the housing 100 is composed of a body 110 and a cover 120, as shown in Figs.

The body 110 has a rotating space 112 open to one side therein and a discharge portion 140 for communicating with the rotating space 112 to discharge the fluid is formed.

The cover 120 opens and closes the open rotary space 112 of the body 110, and communicates with the rotary space 112 to form a supply 130 for introducing fluid.

Between the body 110 and the cover 120 is to be sealed, the sealing member (not shown) is provided on the portion to be coupled to each other, it is natural that the coupling member is firmly coupled.

In addition, the first rotating means 200 is composed of a first drum 210, a first motor 220, a first bearing 230 and the first sealing portion 240.

The first drum 210 is installed to be rotatable in the rotating space portion 112 of the housing 100, and the first motor 220 is provided on the outer surface of the cover 120 of the housing 100 to allow the first drum 210 to be rotated. Rotate).

In addition, the first bearing 230 is provided between the rotation shaft 250 of the first drum 210 and the cover 120 of the housing 100 to install the first drum 210 so as to be rotatable, and the first sealing part. The 240 may prevent the fluid of the rotating space 112 from flowing out through the first bearing 230.

Here, the first sealing unit 240 is preferably provided on both sides of the first bearing 230.

The second rotating means 300 includes a second drum 310, a second motor 320, a second bearing 330, and a second sealing part 340.

The second drum 310 is installed to be rotatable in the rotating space portion 112 of the housing 100, the second motor 320 is provided on the outer surface of the body 110 of the housing 100, the second drum 310 Rotate).

In addition, the second bearing 330 is provided between the rotation shaft 350 of the second drum 310 and the body 110 of the housing 100 to install the second drum 310 so as to be rotatable, and the second sealing part. 340 prevents the fluid of the rotating space 112 from flowing out through the second bearing 330.

Here, the second sealing portion 340 is preferably provided on both sides of the second bearing 330.

The first drum 210 of the first rotating means 200 and the second drum 310 of the second rotating means 300 are provided so as to be rotated in opposite directions spaced apart from each other at predetermined intervals in the rotating space 112. As the fluid moves at high speed and generates high heat as it is rubbed, the fluid can be rotated at a higher speed than when only one of the first drum 210 and the second drum 310 is rotated. .

At this time, as shown in Figure 3, the first drum 210 and the second drum 310 has a flow path (212, 312) relative to the axis of rotation (250, 350) so that fluid can be moved through the interior As a plurality is formed, the fluid introduced through the inlet 130 may be moved to the entire rotary space (112).

In addition, the first drum 210 and the second drum 310 are formed with a plurality of vortex grooves 214 and 314 along the outer surface to vortex fluid when rotated, and thus, the first drum 210 and the second drum ( By partially vortexing the fluid moving at high speed by the rotation of 310, the friction time may be increased to generate more heat.

The vortex grooves 214 and 314 may be formed on the inner surface of the rotating space 112 and the cover 120 of the body 110.

In addition, as the first drum 210 and the second drum 310 are formed with a plurality of heat generating projections 216 and 316 protruding along the outer surface, heat can be more easily generated as the friction area with the fluid increases. have.

On the other hand, as another embodiment of the second drum 310 ', as shown in Figures 4 to 5, it is composed of a second lower drum (310a') and the second upper drum (310b ').

The second lower drum 310a 'is provided to surround the first drum 210, and a mounting space portion 312a' opened to one side is formed therein so that the first drum 210 is positioned.

The second upper drum 310b 'is provided to open and close the open mounting space 312a' of the second lower drum 310a ', and the second lower drum 310a' and the second upper drum 310 310b ') are fixed to each other and rotated equally.

At this time, the installation hole 312b 'is formed in the center of the second upper drum 310b' so that the rotating shaft 250 of the first drum 210 is penetrated and rotatable.

Looking at the coupling sequence of the heat generating device 10 provided with the second drum 310 ′ of another embodiment, first, the first motor (1) of the first rotating means 200 in the cover 120 of the housing 100; 220 is installed, the second motor 320 of the second rotating means 300 is installed on the body (110).

The second upper drum 310b ′ of the second drum 310 ′, the first drum 210, and the second lower drum 310 a ′ of the second drum 310 ′ are sequentially connected to the rotation shaft 250 connected to the first motor 220. After mounting, the second lower drum 310a 'and the second upper drum 310b' are fixed.

Next, after connecting the rotating shaft 350 connected to the second motor 320 with the second lower drum 310a ', assembling is completed by sealing the body 110 and the cover 120 to each other, and the supply unit The fluid is supplied through the 130 to discharge the heat generated fluid through the discharge unit 140.

At this time, when the rotary shaft 250 of the first rotating means 200 and the rotary shaft 350 of the second rotating means 300 are respectively installed on the cover 120 and the body 110, the first bearing 230 and the first Of course, the sealing unit 240 is installed on the cover 120, and the second bearing 330 and the second sealing unit 340 are installed on the body 110.

In addition, the first drum 210 and the second drum 310 ′ are introduced as a plurality of flow paths 212 and 312 ′ are formed based on the rotation shafts 250 and 350 so that the fluid can move through the interior. Fluid introduced through the unit 130 may be moved to the entire rotary space 112.

At this time, the second lower drum 310a 'of the second drum 310' is formed with a flow path 312 'on the side part, and when the first drum 210 and the second drum 310' are rotated by centrifugal force. It is preferable to move the fluid moved to the side portion to the rotating space portion 112 of the housing 100.

In addition, the first drum 210 and the second drum 310 'are formed with a plurality of vortex grooves 214 and 314' along the outer surface to vortex fluid when rotated, and thus, the first drum 210 and the second drum 310 '. By partially vortexing a fluid moving at high speed by the rotation of the drum 310 ′, the friction time may be increased to generate heat.

In addition, as the first drum 210 and the second drum 310 'are formed with a plurality of heat generating projections 216 and 316' protruding along the outer surface, heat is more easily generated as the friction area with the fluid increases. You can.

6 to 7, as another embodiment of the second drum 310 ″, the second lower drum 310a ″, the second intermediate drum 310b ″ and the second upper drum 310c ″ may be used. It consists of.

First, the second lower drum 310a ″ is provided with a lower space portion 312a ″ that is open to one side so that the first drum 210 is positioned.

In addition, the second intermediate drum 310b ″ has an intermediate space 312b ″ therein so that the first drum 210 is positioned, and is provided above the second lower drum 310a ″ to provide a lower space 312a ″. ) And the installation hole 314b "is formed in the center part.

The second upper drum 310c ″ is provided to open and close the intermediate space portion 312b ″ of the second intermediate drum 310b ″, and a central portion of the second upper drum 310c ″ of the first drum 210. An installation hole 312c ″ is formed to rotatably install the rotating shaft 250.

Here, at least one second intermediate drum 310b ″ is provided, and rotates in the same manner as the second lower drum 310a ″ and the second upper drum 310c ″.

The first drum 210 is positioned in the lower space portion 312a ″ and the intermediate space portion 312b ″, and each of the first drums 210 is rotated in the same manner by the first motor 220. It is rotated in the direction opposite to the second drum 310 ".

In addition, a lower bearing 310d ″ is further provided between the first drum 210 and the second lower drum 310a ″ positioned in the lower space portion 312a ″, and the second upper drum 310c ″ and the housing ( An upper bearing 310e ″ may be further provided between the covers 120 of the 100 to maintain the rotation shaft 350 of the first rotation means 200 and the second rotation means 300 in a constant manner.

Looking at the coupling sequence of the heat generating device 10 equipped with the second drum 310 "of this embodiment, first, the first motor of the first rotating means 200 in the cover 120 of the housing 100 220 is installed, the second motor 320 of the second rotating means 300 is installed in the body (110).

The second upper drum 310c ″, the second intermediate drum 310b ″, and the second lower drum 310a ″ of the second drum 310 ′ are sequentially connected to the rotation shaft 250 connected to the first motor 220. The first drum 210 is mounted on the intermediate space 312b ″ of the second intermediate drum 310b ″ and the lower space 312a ″ of the second lower drum 310a ″.

Thereafter, the second upper drum 310c ″, the second intermediate drum 310b ″ and the second lower drum 310a ″ are fixed, and then the rotation shaft 350 connected to the second motor 320 is lowered to the second lower drum 310. After connecting to the drum (310a "), the assembly is completed by sealing the body 110 and the cover 120 to each other, supply the fluid through the supply unit 130 to discharge the high-temperature fluid outlet 140 Through the exhaust.

At this time, when the rotary shaft 250 of the first rotating means 200 and the rotary shaft 350 of the second rotating means 300 are respectively installed on the cover 120 and the body 110, the first bearing 230 and the first Of course, the sealing unit 240 is installed on the cover 120, and the second bearing 330 and the second sealing unit 340 are installed on the body 110.

As the first drum 210 and the second drum 310 ″ are formed with a plurality of flow paths 212 and 312 ″ based on the rotation shafts 250 and 350 so that the fluid can be moved through the inside, the inflow is performed. Fluid introduced through the unit 130 may be moved to the entire rotary space 112.

In this case, a flow path 312 ″ is also formed at the side surface of the second intermediate drum 310b ″ and the second lower drum 310a ″ of the second drum 310 ″ to form the first drum 210 and the second drum 310. "), It is preferable to move the fluid moved to the side part by centrifugal force to the rotating space part 112 of the housing 100.

In addition, the first drum 210 and the second drum 310 ″ form a plurality of vortex grooves 214 and 314 ″ along the outer surface to vortex fluid when rotated, and thus, the first drum 210 and the second drum 310 ″. By partially vortexing the fluid moving at high speed by the rotation of the drum 310 ″, the friction time can be increased to generate more heat.

In addition, the first drum 210 and the second drum 310 "are formed with a plurality of heat generating projections 216 and 316" protrudingly formed along the outer surface of the first drum 210 and the second drum 310 "to further generate heat more easily as the friction area with the fluid increases. You can.

The fluid used herein may be used as a heat medium oil, a fluid for heating water, water, and the like, and it is preferable to use at least one selected from a heat storage liquid or water, and similar heat medium oil or a fluid for heating water may be used.

In addition, as shown in Figure 8, the heat generating device 10 is preferably provided with a buffer means 400 in the lower end.

The shock absorbing means 400 is provided with a rubber or a spring having a shock-absorbing effect, when the heat generating device 10 is operated, it can reduce the noise by buffering the vibration.

And, as shown in Figure 9, the supply passage 500 is further formed inside the first rotating means 200 and the second rotating means 300 so that the fluid supplied through the supply unit 130 is moved.

The supply passage 500 includes a first supply passage 510 and a second supply passage 520, the first supply passage 510 is formed in the first rotating means 200, and the second supply passage ( 520 is formed on the second rotating means (300).

Here, the first supply passage 510 communicates with the first horizontal passage 512 and the first horizontal passage 512 through which the first supply passage 510 is orthogonal to the rotation shaft 250 of the first rotating means 200. The first vertical flow path 514 is formed through the first drum 210 along.

The second supply passage 520 communicates with the second horizontal passage 522 through which the second supply passage 520 is orthogonal to the rotation shaft 350 of the second rotating means 300 and the second horizontal passage 522 to rotate the rotation shaft 350. Accordingly, the second vertical flow path 524 is formed through the second drum 310.

Looking at the movement path of the fluid moving along the supply passage 500, a portion of the fluid supplied from the supply unit 130 is moved through the first horizontal passage 512 and the first vertical passage 514, the first A portion of the fluid moved through the vertical flow path 514 is moved to the space between the first drum 210 and the second drum 310 and the second vertical flow path 524, and moves through the second vertical flow path 524. The fluid is moved through the second horizontal passage 522.

Accordingly, the supplied fluid may be moved between the first drum 210 and the second drum 310 as well as the entire rotary space 112.

At this time, the first drum 210 and the second drum 310 is provided with a supply groove 530 along the outer periphery of the first vertical flow path 514 and the second vertical flow path 524, the supply groove 530 is As the moving speed of the fluid moved along the first vertical flow path 514 is instantaneously reduced, the amount of fluid supplied at the interval between the first drum 210 and the second drum 310 may be increased.

10: heat generator 100: housing
110: body 120: cover
130: supply part 140: discharge part
200: first rotating means 210: first drum
220: first motor 230: first bearing
240: first sealing portion 300: second rotation means
310: second drum 320: second motor
330: second bearing 340: second sealing part
400: buffer means

Claims (14)

A housing having a rotation space portion therein and a supply portion for introducing fluid into the rotation space portion and a discharge portion for discharging the fluid of the rotation space portion;
A first rotating means provided on one side of the housing, the first drum having a surface rotating in the rotating space; And
The second drum having a surface provided on the other side of the housing is rotated in the rotation space portion, and comprises a second rotating means spaced apart from the first drum at a predetermined interval and rotated in the opposite direction,
And the first and second rotating means rotate in opposite directions to generate heat as the fluid supplied to the rotating space of the housing flows and rubs.
The connector according to claim 1,
A body having a discharge space for discharging fluid by being in communication with the rotary space and the rotary space opened to one side therein; And
Opening and closing the open rotating space of the body, and is in communication with the rotating space is composed of a cover formed with a supply for introducing the fluid,
Heat generating device, characterized in that the sealing between the body and the cover.
The method of claim 1, wherein the first rotating means,
A first drum installed to be rotatable in the rotating space of the housing;
A first motor for rotating the first drum;
A first bearing provided between the rotating shaft of the first drum and the housing; And
And a first sealing part which prevents the fluid from flowing in the rotating space part through the first bearing.
The method of claim 1, wherein the second rotating means,
A second drum installed to be rotatable in the rotating space of the housing;
A second motor for rotating the second drum;
A second bearing provided between the rotating shaft of the second drum and the housing; And
And a second sealing part for preventing the fluid from flowing out of the rotating space part through the second bearing.
The method of claim 1, wherein the second drum,
It is provided to surround the first drum,
A second lower drum having a mounting space portion open to one side so that the first drum is positioned; And
It is composed of a second upper drum for opening and closing the open mounting space portion of the second lower drum,
And the second upper drum and the second lower drum are fixed and rotated in the same manner.
The method of claim 1, wherein the second drum,
A second lower drum having a lower space portion open to one side so that the first drum is positioned;
A second intermediate drum having an intermediate space therein so that the first drum is positioned, provided on an upper side of the second lower drum to open and close a lower support space, and an installation hole formed at a central portion thereof; And
It comprises a second upper drum for opening and closing the intermediate space portion of the second intermediate drum,
The second intermediate drum is provided with at least one is rotated in the same manner as the second lower drum, the second upper drum,
And the first drum is positioned in the lower space and the intermediate space, respectively, and rotates in a direction opposite to the second drum.
The method according to claim 6,
A lower bearing is further provided between the first drum and the second lower drum positioned in the lower space part, and an upper bearing is further provided between the second upper drum and the housing to rotate the shaft of the first rotation means and the second rotation means. Heat generating device characterized in that to maintain.
The method of claim 1, wherein the first drum and the second drum,
A heat generating apparatus characterized in that a plurality of flow paths are formed based on the rotation axis so that the fluid can move through the interior.
The method of claim 1, wherein the first drum and the second drum,
A plurality of vortex grooves are formed along the outer surface to vortex the fluid during rotation.
The method of claim 1, wherein the first drum and the second drum,
A plurality of heat generating jaw protrudes along the outer surface to increase the friction area with the fluid.
The method of claim 1,
The supply unit supplies the fluid to the central portion of the first rotating means, the discharge portion is formed on the side of the housing characterized in that the high-temperature fluid is discharged by the centrifugal force by the rotation of the first rotating means and the second rotating means Heat generator.
The method of claim 1,
A supply passage is further formed inside the first rotating means and the second rotating means so that the fluid supplied through the supply part moves.
The supply passage,
A first supply flow passage having a first horizontal flow passage through which the first rotation flow passage is orthogonal to the rotation axis of the first rotation means, and a first vertical flow passage communicating with the first horizontal flow passage and passing through the first drum along the rotation shaft; And
And a second supply passage having a second horizontal flow passage that is orthogonal to the rotation axis of the second rotation means and a second vertical flow passage which is in communication with the second horizontal flow passage and is passed through the rotation axis to the second drum. ,
A portion of the fluid supplied from the supply is moved through the first horizontal flow path and the first vertical flow path, and a portion of the fluid moved through the first vertical flow path is the space between the first drum and the second drum and the second vertical flow path. And the fluid moved through the second vertical flow path is moved through the second horizontal flow path.
The method of claim 12, wherein the first drum and the second drum,
Supply grooves are formed along the outer periphery of the first vertical flow path and the second vertical flow path to instantaneously decrease the moving speed of the fluid moved along the first vertical flow path. Heat generating apparatus characterized by increasing the amount.
The method of claim 1, wherein the fluid,
Heat generating device, characterized in that any one or more selected from the heat storage liquid and water.

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