JPH0223789B2 - - Google Patents

Description

[Detailed description of the invention] (a) Industrial application field This invention relates to an improvement of the technology introduced as a reduced pressure equilibrium heat generation mechanism or a constant pressure equilibrium heat generation mechanism. The present invention relates to a storage having a heat generating device with a driven rotating body that utilizes a heat generating device that can also reduce power consumption.

(B) Prior Art The present inventor has developed a method for generating heat generation due to friction with gas in a hollow chamber in which a rotating body is disposed in a constant pressure equilibrium state of depressurization or pressurization based on the rotational action of a rotary body. By heating the inside of the hollow chamber, discharging heated gas outside the hollow chamber, or heating the hollow chamber itself as a heat source, it is possible to obtain an effective and clean heat source inside and outside the hollow chamber. completed a series of inventions. In other words, to exemplify some of them, Japanese Patent Application Laid-open No. 57-19582,
Japanese Patent Publication No. 57-19583, Special Publication No. 59-52342, Special Publication No.
No. 59-52753, Special Publication No. 59-47821, Special Publication No. 59-
The first invention of No. 9822, the first invention of Japanese Patent Publication No. 59-4625, the first invention of Japanese Patent Publication No. 172492-1987, and the first invention of Japanese Patent Publication No. 172492-1989,
No. 224270, JP-A-59-191882 and JP-A-59-
No. 53947, Special Publication No. 16904, Special Publication No. 61-16905
No., JP 61-16906, JP 61-16479, JP 61-86532, JP 61-86533, JP 61
―No. 86534, JP-A-61-86535, JP-A-61-
No. 87502, JP-A-61-107053, JP-A-61-
No. 107054, Patent Application No. 139757 (Japanese Unexamined Patent Publication No. 1983-1983)
5080), EPC publication EP O 176 930 A2, etc.

In connection with the above-mentioned series of inventions, the present inventor provided a driven rotation mechanism that works by the viscous effect of fluid or fluid energy based on the rotational action of a rotating body in a hollow chamber, and by this driven rotation mechanism, the rotation inside the hollow chamber is He has completed a related invention that enables the generation of a gas flow by forcing gas to flow and backing up the thermogenic effect. Examples include the second invention of Tokoku Kokoku No. 58-47621, Tokoku No. 58-47622, the second invention of Tokoku No. 59-9822 mentioned above, and the second invention of Tokoku Kokoku No. 4625 of Tokoku Sho 59-4 mentioned above.

Among the many inventions of the present inventors mentioned above, the driven rotation mechanism in particular is provided exclusively on the intake port side of the rotating body provided in the hollow body, and this mechanism mainly handles the heat generation backup inside the hollow chamber. It is used for a purpose.

However, driving the driven rotation mechanism provided on the intake port side consumes more power than a case without the same mechanism.

By the way, in the reduced pressure equilibrium heating mechanism or the constant pressure equilibrium heating mechanism, the temperature rises rapidly, so in order to cool the electric motor that drives the rotating body, cooling has been carried out by specifically introducing outside air.

Places that provide warm air in the temperature range that animals and plants normally live in, for example, 10°C to 30°C, supply the heat generated by the same mechanism by cooling it with introduced outside air. However, if cooling is performed separately, the energy such as electric power used to rotate the mechanism is rather wasted.

Therefore, we tried a constant pressure equilibrium rotary heating device whose basic principle is illustrated in FIG. 10. That is, a rotating body 104 having an intake and exhaust function driven by an electric motor 105 is disposed in a cylindrical casing 101 having an intake port 102 and an exhaust port 103 opened, respectively.
Annular weir plates 107 and 108 are arranged inside the cylindrical casing 101 along the front and rear of the pressure regulating chamber 1.
09, and as a result, the electrical energy consumed by the electric motor 105 is significantly reduced. In this rotary constant-pressure equilibrium heating device, as described in the inventions of the publications listed above, the rotating body is placed inside a cylindrical casing, and the inside of the cylindrical casing is depressurized or pressurized in a constant-pressure equilibrium state. Since it is rotated so that the state can be maintained, it is assumed that it exhibits a heat-generating effect due to effective friction with the gas.
The inside of the cylindrical casing can be heated to the required temperature, and the heated gas is exhausted to the outside through the exhaust port.

By the way, the rotating body is separated by cylindrical weir plates installed at the front and rear inside the cylindrical casing, and because it faces the pressure regulating chamber, the pressure reduction effect increases, the gas density decreases, and the gas resistance decreases. The energy consumption of the electric motor that drives the rotating body, that is, the power consumption, can be significantly reduced.

That is, the reduced pressure state of the pressure regulating chamber can reduce the rotational torque of the rotating body, and as a result, the electrical energy acting on the electric motor can be reduced.

Similarly, a rotary body 201 having an intake and exhaust function whose basic principle is illustrated in FIG.
03 and a gas exhaust port 204, and a driven rotary body 205 is disposed opposite to the exhaust side of this rotary body, and furthermore, a driven rotary body 205 and a gas discharge port 204 are disposed in front and behind the driven rotary body 205 and the rotary body. Along the cylindrical casing 202, an annular weir plate 206, 2 is provided.
07, the rotational force is not limited to constant pressure equilibrium heat generation, but a constant pressure equilibrium equipped with a driven rotation mechanism that includes a driven rotation body to obtain the necessary output. A rotating heating device was tried.

The rotating body can be driven not only by the electric motor 208 but also by other driving means such as a gasoline engine.

As described in the inventions of the above-mentioned publications, this constant-pressure equilibrium rotary heat generating device reduces or increases the pressure inside the cylindrical casing by suction and exhaust action when the rotating body 201 rotates within the cylindrical casing 202. In addition to being able to maintain a constant pressure equilibrium state, the cylindrical casing 2
The inside of 02 can be heated to the required temperature, and if the hollow chamber is connected to the intake side, the heated gas will be guided into the hollow chamber, but if there is no hollow chamber and it is just a ventilation state, the heated gas will be guided to the outside from the exhaust port. is exhausted.

Since the rotating body 201 has a driven rotating body disposed opposite to it on its exhaust side, it rotates in the same direction as the rotating body due to the action of gas flow energy accompanying the rotational action of the rotating body, and the driven rotating body 201 rotates in the same direction as the rotating body. Desired rotational force can be extracted from the mechanism.

Furthermore, since the rotating body and the driven rotating body face the pressure regulating chamber 109 based on the annular weir plate 206 provided in both of the cylindrical casing, the rotating body 201 itself is not affected by the pressure reduction effect. In addition to improving the rotational efficiency, the driven rotor 205 has gas that is prevented from flowing out by the annular weir plate 207 and turns into a swirling flow, increasing the force acting on the driven rotor and energizing the rotational action of the driven rotor. Since the amount of follow-on operation to the rotating mechanism can be increased, high output can be obtained from the mechanism.

(c) Problems to be solved by the invention The rotating body 10 as shown in FIGS. 9 and 10
The rotary constant-pressure equilibrium heating device having weir plates (diameter adjusting plates) 107, 207 on the side of the gas discharge ports 103, 204 of 4,201 has the excellent advantage of reducing power consumption. It was also found that the amount of gas exhausted from the mouth was reduced.
Therefore, it is not very suitable for applications that use a large amount of exhausted hot air.

Therefore, a casing having a gas inlet and a gas outlet, a rotating body that rotates within the casing so that gas can be moved from the gas inlet to the gas outlet, and a gas inflow restriction installed on the side of the gas inlet from the rotating body. When we tried a heat generating device characterized by a driven rotating body installed on the exhaust side of the rotating body and facing the rotating body, the power consumption was reduced and the amount of air discharged from the gas exhaust port was reduced. We also found that the results also improved. The temperature of the exhausted gas can also be changed by appropriately selecting the fin shape of the driven rotor, and it is possible to change the temperature of the exhausted gas by appropriately selecting the fin shape of the driven rotor. It has been found that it is possible to continuously supply a large amount over a long period of time.

It is presumed that this effect is due to the fact that the driven rotor has a rotation function and promotes exhaust gas, and also has a function as a diameter adjustment plate (weir plate).

Furthermore, the inventor has a heat generation chamber, a storage, and a ventilation passage that communicates the heat generation chamber and the storage chamber, and the heat generation chamber includes a casing having a gas inlet and a gas discharge port, and a gas inlet. A rotating body that rotates within the casing so that it can move from the gas inlet to the gas outlet, a gas inflow restriction means (weir plate) installed on the gas inlet side of the rotating body, and facing the rotating body on the exhaust side of the rotating body. We attempted a storage facility in which a heat generating device consisting of a driven rotary body and a driven rotary body were installed, and the hot air generated in the heat generating chamber was circulated within the heat generating chamber and the storage chamber by the exhaust force of the rotary body. At the same time, the inventor has provided a heating chamber, a storage, and a ventilation passage communicating the heating chamber and the storage chamber, and the heating chamber includes a casing having a gas inlet and a gas outlet, and a gas A rotating body that rotates within the casing so as to be movable from the inlet to the gas outlet; a gas inflow restriction means installed on the gas inlet side of the rotating body; and a gas inflow restricting means installed opposite the rotating body on the exhaust side of the rotating body. A heat generating device consisting of a driven rotary body is installed, and a casing having a gas inlet and a gas discharge port, and a casing that is connected to the rotating shaft of the previous rotary body within the casing so that gas can be moved from the gas inlet to the gas discharge port. Driven rotation as an air clutch installed in the gas outlet of a circulation heat generating device consisting of a circulating rotating body rotated by a drive and a gas inflow restricting means installed on the gas inlet side of the circulating rotating body. A storage unit with an attached heating device was tried.

When both storage chambers were driven by electric motors with the same output, a heating device for circulation or a rotating body was installed separately, and the rotating force of the rotating shaft of the driven rotating body serving as an air clutch was used to drive the device or rotating body to circulate the gas. It was found that the air blowing efficiency is about 1.5 times or more better than when the heat generating device also serves as the gas circulation.

(d) Means for solving the problems This invention is based on these findings, and includes a heating chamber, a storage chamber, and a ventilation passage communicating the heating chamber and the storage chamber, and the heating chamber includes: A casing having a gas inlet and a gas outlet, a rotating body that rotates within the casing so that gas can be moved from the gas inlet toward the gas outlet, and a rotating body that rotates within the casing to move gas from the gas inlet to the gas inlet. A heat generating device is installed, which consists of a gas inflow restricting means for restricting the inflow of gas, and a driven rotary body, which is installed on the exhaust side of the rotary body facing the rotary body and rotates by the flow of gas generated by the rotation of the rotary body. A storage warehouse having a heat generating device with a driven rotary body, characterized in that a circulating rotary body is installed in the passageway, and is driven by a rotating shaft of the driven rotary body and rotates so as to move gas from the heating chamber toward the storage chamber; and a casing having a heat generation chamber, a storage chamber, and a ventilation passage communicating the heat generation chamber and the storage chamber, and a casing having a gas inlet and a gas discharge port, and a gas inlet and a gas inlet. a rotating body that rotates within the casing so as to be movable from the rotating body toward the gas exhaust port; a gas inflow restricting means that restricts the inflow of gas into the casing that is installed on the gas inlet side of the rotating body; and a rotating body that rotates on the exhaust side of the rotating body. A heat generating device consisting of a driven rotary body that is installed facing the body and rotates with the flow of gas generated by the rotation of the rotary body is installed, and a gas inlet for a heat generating device for circulation and a heat generating device for circulation are installed in the ventilation passage. A casing for a circulating heat generating device having a gas outlet for the circulating heat generating device, and a circulating heat generating device within the casing for the circulating heat generating device such that gas can be moved from the gas inlet for the circulating heat generating device toward the gas outlet for the circulating heat generating device. A circulating rotating body that is driven and rotated by the rotation shaft of a driven rotating body, and a circulating heating device that restricts the inflow of gas into the casing installed on the gas inlet side of the circulating heating device from the circulating rotating body. By providing a storage having a heat generating device with a driven rotating body, the circulating heat generating device comprising a gas inflow restricting means is installed with the gas outlet for the circulating heat generating device facing toward the storage. To provide a storage warehouse having a heat generating device with a driven rotary body suitable for preserving stored items by always supplying hot air within the range in which animals and plants normally survive inside the warehouse by using a heat generating device that improves the air volume while reducing the amount of air.

(E) Effect When the rotating body rotates within the casing, gas moves from the gas inlet to the gas outlet. Then, the pressure between the gas inflow restricting means in the casing and the rotating body is reduced, and as the rotation continues, heat is generated.

Since the driven rotary body is installed on the exhaust side of the rotary body, it is assumed that the driven rotary body is affected by the flow energy of the gas accompanying the rotational action of the rotary body, and therefore rotates in the same direction as the rotary body.

The action of the driven rotor promotes hot air discharge from the gas outlet, and the driven rotor itself replaces a fixed weir plate, forming a kind of pressure regulating chamber with the casing and gas inflow means. However, since the rotating body rotates under a reduced pressure state, gas resistance is reduced, and therefore it is presumed that the energy consumption for energizing the motor is reduced.

Further, by increasing the distance between the rotating body and the driven rotating body, the drive of the driven rotating body is weakened, and by decreasing it, it is strengthened.

The warm air generated in the heat generating chamber is sent into the storage chamber by a circulating rotary body or a circulating heat generating device driven by a rotating shaft of a driven rotary body, thereby providing hot air inside the storage chamber. When the rotating body is used as a heating device for circulation, it generates even more heat.

(F) Example Figure 1 shows a central cross section of a heat generating device used in an example of this invention, and Figures 2 and 3 show parts diagrams.
The first embodiment will be described with reference to FIGS. 4 and 5.

1 is a cylindrical casing with a gas inlet 2 and a gas outlet 3 opened; 4 is a rotating body rotatably disposed within the cylindrical casing 1 and has an intake and exhaust function; 5 is the rotating body 4; The driving source is an electric motor in the illustration, but any type of engine may be used.
It is arranged outside the opening surface of the gas inlet 2. Therefore, it is possible to heat the inside of the casing 1.

By the way, the rotating body 4 includes a rotating blade 4a such as a propeller fan or a shirotsukofan, which has a desired inclination angle and has a suction/exhaust function.

Reference numeral 6 denotes a driven rotary body (air clutch) which is rotatably supported on the exhaust side opposite to the rotary body 4, and is fixed to a rotary shaft 7 disposed along the axial center of the cylindrical casing 1. There is.

The driven rotating body 6 is formed by providing a large number of fins 10 around a disc-shaped plate-like body 9, as shown in the front view in FIG. 2 and the side view in FIG. The fin 10 is a plate-like body 9
It is sufficient to provide the fins around the periphery of the plate-shaped body 9, and there is no need to provide the fins up to the center of the plate-like body 9. There is no difference in driven rotation, and the shape of the fins can be arbitrarily selected.

Reference numeral 11 denotes a gas inflow restricting means, which in this embodiment is an annular diameter adjustment plate disposed on the intake side of the rotating body 4. The diameter adjustment plate 11 shown in FIG. 4 has a constant inner diameter, but the diameter adjustment plate 12 shown in FIG.
has a variable diameter aperture 13 on the inside, and the diameter length of the inner diameter can be adjusted.

Casing 1, diameter adjustment plate 11, and driven rotor 6
A kind of pressure regulating chamber 14 is formed. The rotating body 4 facing into the pressure regulating chamber 14 has a suction and exhaust function, and forms a small gap g between it and the cylindrical casing 1 to form a reduced pressure equilibrium heating mechanism A.

Therefore, the operation of the heat generating device will be explained.

When the rotating body 4 is rotated by the action of the drive source 5, gas is sucked through the gas suction port 2, and in the reduced pressure balanced heating mechanism A of the pressure adjustment chamber 14, reduced pressure balanced heating action is performed, and the gas temperature is adjusted to a desired temperature. At the same time, the driven rotary body 6 disposed opposite to the rotary body 4 is also rotated in the same direction as the rotary body 4 due to the action of the gas flow energy. Rotating body 4
Since the rotational action of is performed within the pressure regulating chamber 14 formed by the diameter adjustment plate 11 and the driven rotor 6, the pressure reduction effect is enhanced in front of the rotor 4 (on the intake side), but the rotational action of the rotor 4 is A kind of pressurizing effect works at the rear (exhaust side), and the swirling laminar flow, which is partially blocked by the driven rotor 6 and urges the driven rotor 6 to rotate, exhibits a backlash effect and pushes the rotor 4. Rotation is encouraged from the rear, and gas resistance acting on the rotating body 4 is significantly reduced due to the gas environment in front of the rotating body 4, which is under reduced pressure and has a low gas density, which ultimately makes the rotating body 4 economical. It is presumed that it works efficiently under the high energy.

By the way, the driven rotating body 6 has a large number of fins 10 facing the area formed by the gas inflow restricting means 11 consisting of an annular diameter adjustment plate and the cylindrical casing 1. It rotates as a result of effectively receiving the swirling flow of gas obtained by the rotational action of step 4, and exhausts heated hot air from the gas outlet 3 while maintaining balance with the reduced pressure.

Next, another heat generating device that can be used in the embodiment will be described with reference to FIG. 6, which is a cross-sectional view. In this embodiment, a sealed hollow chamber is used as the gas inflow restricting means 11 and is attached to the gas inlet 2. Therefore, a pressure regulating chamber 14 is formed between the casing 1, the driven rotating body 6, and the hollow chamber 11. In this case, although there is a limit to the amount of new gas flowing into the heating chamber 31, the heat generation device 41 continues to generate heat, so the heat is propagated to the heating chamber 31 via the casing 1. .

FIG. 7 is a central sectional view of yet another heat generating device that can be used in the embodiment. In this embodiment, by making the diameter of the gas inlet 2 of the casing 1 small,
This is referred to as gas inflow restricting means 11.

FIG. 9 shows a heat generating device that has a rotating shaft moving mechanism 15 and that can be used in this embodiment. In this heat generating device, a gear 16 fixed to the rotating shaft 7 and a gear 17 on the electric motor 20 side mesh with each other, and as the gear 17 rotates, the gear 16 moves in the axial direction. 17 is a mechanism that does not rotate. Then, the rotation of the electric motor 20 is controlled by the pulley 1.
8 and 19, the driven rotating body 6
It is possible to select the proximity and separation of the rotating bodies in four directions, and the mutual clearance can be selected. By making the clearance small, the drive of the driven rotating body 6 can be strengthened, and by making it large, it can be weakened.

FIG. 8 is a central sectional view of an embodiment of the invention.

Reference numeral 31 is a heating room, and 32 is a storage room, in which metals, calligraphy and painting bones, furniture, etc. 61 are stored. The heating chamber 31 and the storage chamber 32 are connected through ventilation passages 33 and 34.

A heat generating device 41 is installed between the heat generating chamber 31 and the outside air with the gas inlet 2 facing the outside air side. Ventilation path 3
3 includes a circulating heat generating device casing 51, a circulating heat generating device gas inlet 52, a circulating heat generating device gas outlet 53, a circulating heat generating device gas inflow restriction means 54 consisting of a diameter adjustment plate, and a circulating heat generating device gas inflow restricting means 54 consisting of a diameter adjusting plate. Rotating body 55
The circulating heat generating device 56 is fixed with the circulating heat generating device gas outlet 53 facing the storage chamber 32. Although only a rotating body may be provided instead of the circulating heat generating device 56 and the circulating rotating body 55 may be used, even more heat can be expected when the circulating heat generating device 56 is used. The circulating rotating body 55 rotates in conjunction with the rotating shaft 7 of the heat generating device 44 .

Therefore, the hot air supplied into the heat generating chamber 31 by the heat generating device 41 is supplied into the storage chamber 32 via the reduced pressure equilibrium heat generating device 56. The storage room 32 is continuously supplied with warm air at a constant temperature, so it can be used as a storage room with no environmental changes.

(G) Effects of the Invention Therefore, the present invention provides a system with a driven rotating body that can reduce power consumption and, in particular, efficiently and continuously supply a large amount of warm air within the range in which animals and plants normally survive into the storage room. A storage with a heat generating device is provided.

Furthermore, the present invention provides a storage having a heat generating device with a driven rotating body that can further heat by using a heat generating device for circulation.

[Brief explanation of drawings]

Fig. 1 is a central sectional view of the parts diagram of the embodiment, Fig. 2 is a front view of the driven rotating body, Fig. 3 is a side view of the same, and Fig. 4
The figure is a front view of the diameter adjustment plate, Figure 5 is a front view of another diameter adjustment plate, Figures 6, 7, and 9 are center sectional views of other parts diagrams, and Figure 8 is a diagram of the embodiment. central sectional view,
10 and 11 are central sectional views of the related invention. 1... Casing, 2... Gas inlet, 3...
Gas outlet, 4... Rotating body, 5... Drive source, 6...
...Followed rotating body, 7...Rotating shaft, 11, 12...Gas inflow restricting means, 31...Heating chamber, 32...Storage chamber, 33, 34...Ventilation passage, 51...For heating device for circulation Casing, 52... Gas inlet for circulating heat generating device, 53... Gas outlet for circulating heat generating device, 54... Gas inflow restricting means for circulating heat generating device, 55... Circulating rotating body, 56... Circulating heating device.

Claims (1)

[Scope of Claims] 1. A casing having a heating chamber, a storage chamber, and a ventilation passage communicating the heating chamber and the storage chamber, and having a gas inlet and a gas outlet in the heating chamber; a rotating body that rotates within the casing so as to be able to move gas from the gas inlet to the gas outlet; a gas inflow restricting means that restricts the inflow of gas into the casing, which is installed closer to the gas inlet than the rotating body; A heat generating device is installed on the exhaust side of the body, which consists of a driven rotating body that is installed opposite to the rotating body and rotates due to the gas flow generated by the rotation of the rotating body, and in the ventilation path, the heating device is driven by the rotating shaft of the driven rotating body. 1. A storage having a heat generating device with a driven rotary body, characterized in that a circulating rotary body that rotates so as to move gas from the heat generating chamber toward the storage chamber is installed. 2. A storage having a heat generating device with a driven rotating body according to claim 1, wherein the gas inflow restricting means is a sealed hollow chamber installed on the gas inlet side. 3. A storage having a heat generating device with a driven rotating body according to claim 1, wherein the gas inflow restricting means is a diameter adjusting plate installed on the gas inlet side. 4. A storage having a heat generating device with a driven rotating body according to claim 3, wherein the diameter adjustment plate is an adjustment plate capable of freely adjusting the diameter. 5. A storage having a heat generating device with a driven rotating body according to claim 1, wherein the gas inflow restricting means is a casing having a small diameter opening on the gas inlet side. 6. A heat generating device with a driven rotating body according to claim 1 or 2 or 3 or 4 or 5, wherein the rotating body is rotated by the drive of an electric motor installed outside the casing intake port side. storage with. 7. A heating device with a driven rotating body according to claim 1, 2, 3, 4, 5, or 6 in which the distance between the rotating body and the driven rotating body can be adjusted. storage with. 8 It has a heating chamber, a storage chamber, and a ventilation passage that communicates the heating chamber and the storage chamber, and the heating chamber includes a casing having a gas inlet and a gas outlet, and a casing for supplying gas from the gas inlet. A rotating body that rotates within the casing so as to be movable toward the gas exhaust port, a gas inflow restriction means that restricts the inflow of gas into the casing and installed on the gas inlet side of the rotating body, and a rotating body on the exhaust side of the rotating body. A heat generating device consisting of a driven rotating body which is installed opposite to the rotating body and rotates with the flow of gas generated by the rotation of the rotating body is installed, and the ventilation passage has a gas inlet for the circulating heat generating device and a gas inlet for the circulating heat generating device. A casing for a circulating heat generating device that has a gas outlet, and a casing for a circulating heat generating device that allows gas to be moved from the gas inlet for the circulating heat generating device toward the gas outlet for the circulating heat generating device. a circulating rotating body that is driven and rotated by the rotating shaft of the driven rotating body;
A circulating heat generating device consisting of a circulating heat generating device gas inflow restricting means for restricting the inflow of gas into the casing installed on the gas inlet side for the circulating heat generating device from the circulating rotating body. 1. A storage having a heat generating device with a driven rotating body, characterized in that the discharge port is installed facing the storage. 9. A storage having a heat generating device with a driven rotating body according to claim 8, wherein the gas inflow restricting means is a sealed hollow chamber installed on the gas inlet side. 10. A storage having a heat generating device with a driven rotating body according to claim 8, wherein the gas inflow restricting means is a diameter adjusting plate installed on the gas inlet side. 11. A storage having a heat generating device with a driven rotating body according to claim 10, wherein the diameter adjustment plate is an adjustment plate capable of freely adjusting the diameter. 12. A storage having a heat generating device with a driven rotating body according to claim 8, wherein the gas inflow restricting means is a casing having a small diameter opening on the gas inlet side. 13. The heat generating device with a driven rotating body according to claim 8, 9, 10, 11, or 12, wherein the rotating body is rotated by the drive of an electric motor installed outside the casing intake port side. storage with. 14. A heating device with a driven rotating body according to claim 8, 9, 10, 11, 12, or 13, in which the distance between the rotating body and the driven rotating body can be adjusted. storage with.