KR100489760B1 - Heat generating Device using Rotatory force - Google Patents

Abstract

The present invention relates to a heat generating apparatus using a rotational force, comprising a body (11) and a cover (12), the fluid tank 10 for storing a fluid, attached to the cover 12 of the fluid tank 10 is the fluid The cylinder 20 mounted inside the body 11 of the tank 10, the fixed plate 30 mounted inside the cylinder 20, and the inside of the cylinder 20 are located on the same axis as the fixed plate 30. It is a heat generating device using a rotating force including a rotary plate 40 and a rotating shaft 50 which is integrally coupled with the rotating plate 40 and the rotating plate 40 is connected to the external power transmission device. The fixed plate 30 mounted on the inner surface of the cylinder 20 and the rotating plate 40 integrally behaving together with the rotating shaft 50 are arranged to face each other side by side on the same axis so as to face the rotating plate 40 when the rotating plate 40 rotates. Heat is generated by the compression and friction of the fluid between the bottom of the fixing plate 30. The fluid inside the cylinder 20 containing heat generated by compression and friction passes through a plurality of holes 31 penetrating from the inner circumferential surface of the fixing plate 30 to the outer circumferential surface of the cylinder 20 in the direction of the outer circumferential surface. 20) discharged to the outside, the fluid outside the cylinder 20 flows into the hollow 51 formed on the rotating shaft 50 as the rotating shaft 50 rotates, and then the rotating plate 40 on the inner circumferential surface in which the hollow is formed It is introduced into the cylinder 20 by centrifugal force by the rotation of the rotating plate 40 through a plurality of holes 41 penetrating to the outer peripheral surface of the. As the rotation of the rotating plate 40 and the discharge and inflow of the fluid are repeated, the temperature of the fluid stored in the fluid tank is increased.

Description

Heat generating device using Rotatory force

The present invention relates to a heating and steam supply system as a heat generating device using a rotating force. In the existing heating and steam supply system, combustion heat generated by burning various oils, coal, or wood is used. Therefore, since a combustion chamber and an exhaust system are required, it is difficult to apply a heating and steam supply system in a place where the combustion chamber and the exhaust system cannot be provided, and environmental pollution by exhaust gas, a combustion product, has been a problem.

It is an object of the present invention to provide heating and steam in a place where a combustion chamber and an exhaust device, which are essentially required in a conventional heating and steam supply system using combustion heat, cannot be provided. Still another object of the present invention is to prevent environmental pollution caused by exhaust gas, which is essential for the existing heating and steam supply system.

The present invention is composed of a body 11 and the cover 12, as shown in Figure 1 is a fluid tank 10 for storing a fluid, attached to the cover 12 of the fluid tank 10, the fluid tank 10 Cylinder 20 to be mounted inside the body 11, the fixed plate 30 to be mounted inside the cylinder 20, located inside the cylinder 20 and mounted to face on the same axis as the fixed plate 30 It is a heat generating device using a rotating force including a rotating shaft 50 which is integrally coupled with the rotating plate 40 and the rotating plate 40 and connected to an external power transmission device.

The fluid tank 10 is composed of a body 11 and the cover 12 can store various fluids such as water or oil therein. A coupling part of the body 11 and the cover 12 uses a sealant to prevent leakage or leakage and is integrally assembled using a fastener such as a bolt. The cover 12 is formed with a hollow for supporting one end of the rotating shaft, and the hollow can be equipped with a bearing 60 to reduce the friction force when the rotating shaft is rotated, and the hollow to prevent leakage or leakage of fluid stored in the fluid tank The oil seal 70 may be mounted between the rotary shaft and the rotary shaft. When the temperature control sensor 14 is attached to the body 11 or the cover 12 to control the temperature of the fluid, the temperature control sensor 14 detects the temperature of the fluid and transmits the temperature to the external controller. In addition, in order to prevent the risk of instantaneous bursting of the fluid tank 10, when the pressure of the fluid rises above a certain value, a safety valve 13 for discharging the fluid inside is added to the body 11 or the cover 12. In addition, safety accidents can be prevented in advance.

The cylinder 20 is attached to the cover 12 of the fluid tank 10 and mounted inside the body 11. The cylinder 20 has a hollow formed at the bottom of one side of the cylinder to support the other end of the rotating shaft 50, and the expansion hole capable of accommodating the fixed plate 30 and the rotating plate 40 inside the cylinder 20 has a fluid tank. It extends to the other bottom surface to which the cover 12 of 10 is attached. The hollow supporting the other end of the rotating shaft may be equipped with a bearing 60 in order to reduce the frictional force during the rotation of the rotating shaft. The side surface of the cylinder 20 is formed with a plurality of holes 31 penetrating to the inner peripheral surface where the hollow of the fixing plate 30 is formed.

The fixing plate 30 has a cylindrical shape in which a hollow through which the rotating shaft 50 passes is formed, and its outer circumferential surface is integrally coupled with the inner surface of the cylinder 20 and penetrates from the inner circumferential surface having the hollow to the outer circumferential surface of the cylinder 20 in the direction of the outer circumferential surface. A plurality of holes 31 are formed. In addition, as shown in Figure 2 on the bottom of both sides of the fixed plate 30 to form a plurality of projections at regular intervals, or a plurality of grooves at regular intervals in order to increase the compression efficiency during rotation of the rotating plate to generate more frictional heat ( groove) to obtain the same effect as that of forming the projection.

The rotating plate 40 is a cylindrical shape is made integrally with the rotating shaft 50 or comprises a hollow for coupling with the rotating shaft after the separate production is combined integrally with the rotating shaft 50 and the central axis on the outer peripheral surface of the rotating plate 40 A plurality of holes 41 penetrate to the hollow 51 formed in the rotation shaft 50 in the direction. In addition, the bottom surface of both sides of the rotating plate 40 or one side of the rotating plate 40 opposite to the bottom of the fixed plate 30 as shown in Figure 3 radially constant to increase the compression efficiency during rotation to generate more frictional heat By forming a plurality of protrusions, or by processing the groove at a predetermined interval can be obtained the same effect as forming the protrusions.

The rotating shaft 50 moves integrally with the rotating plate 40 and is connected to an external power transmission device to transmit the rotating force to the rotating plate 40. The rotating shaft 50 has a cylindrical shape with a hollow 51 formed therein, and a plurality of holes 41 penetrate from the inner circumferential surface on which the hollow 51 is formed to the outer circumferential surface of the rotating plate 40 in the direction of the outer circumferential surface. The external power transmission method can be selected by using the belt and the pulley and the gear engagement method.

The fixed plate 30 mounted on the inner surface of the cylinder 20 and the rotating plate 40 integrally behaving together with the rotating shaft 50 are arranged so as to face each other side by side on the same axis as shown in FIGS. 1 and 4. Heat is generated by the compression and friction of the fluid between the bottom of the rotating plate 40 and the fixed plate 30 facing the rotation of the. The fluid inside the cylinder 20 containing heat generated by compression and friction passes through a plurality of holes 31 penetrating from the inner circumferential surface of the fixing plate 30 to the outer circumferential surface of the cylinder 20 in the direction of the outer circumferential surface. 20) discharged to the outside, the fluid outside the cylinder 20 flows into the hollow 51 formed on the rotating shaft 50 as the rotating shaft 50 rotates, and then the rotating plate 40 on the inner circumferential surface in which the hollow is formed It is introduced into the cylinder 20 by centrifugal force by the rotation of the rotating plate 40 through a plurality of holes 41 penetrating to the outer peripheral surface of the. As the rotation of the rotating plate 40 and the discharge and inflow of the fluid are repeated, the temperature of the fluid stored in the fluid tank is increased.

Since the present invention is a heat generating device using a rotational force, it can supply heating and steam without having a combustion chamber and an exhaust device, which is essentially required in the existing heating and steam supply system, so that it can be safely performed without being limited by the installation place. . In addition, since there is no combustion process, the exhaust gas is not generated by combustion, thereby preventing environmental pollution.

1 is a schematic cross-sectional view of a specific embodiment of the present invention.

Figure 2 is a schematic perspective view of a fixing plate protrusion that is a component of a specific embodiment of the present invention.

3 is a schematic perspective view of a rotating plate protrusion which is a component of a specific embodiment of the present invention.

Figure 4 is a schematic coupling state diagram of the stationary plate and the rotating plate as a component of a specific embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10 fluid tank 11 body

12: cover 13: safety valve

14: temperature control sensor 20: cylinder

30: fixed plate 40: rotating plate

50: rotation axis 60: bearing

70: Oil Seal

Claims (6)

A fluid tank composed of a body and a cover and storing fluid; A cylinder attached to a cover of the fluid tank and mounted inside the body of the fluid tank; A fixed plate mounted inside the cylinder; A rotating plate positioned inside the cylinder and mounted to face the same axis as the fixed plate; In the heat generating apparatus using a rotational force comprising a rotary shaft coupled to the rotating plate and connected to an external power transmission device, a hollow through which the rotating shaft passes is formed in the center of the cover of the fluid tank to support one end of the rotating shaft A hollow for supporting the other end of the rotating shaft is formed at one end of the cylinder, and an inside of the cylinder is formed with an expansion hole for accommodating the fixed plate and the rotating plate, and the fixed plate has a hollow through which the rotating shaft passes. As the cylindrical shape, the outer circumferential surface thereof is coupled to the cylinder inner surface, and a plurality of holes are formed to penetrate from the inner circumferential surface of which the hollow is formed to the outer circumferential surface of the cylinder in the direction of the outer circumferential surface. After being combined integrally, the rotating shaft Among them, a hollow cylindrical shape is formed, a plurality of holes penetrating from the inner circumferential surface in which the hollow is formed to the outer circumferential surface of the rotating plate, and a plurality of projections are formed radially on both bottom surfaces of the fixed plate, both bottom surfaces of the rotating plate Or a heat generating device using a rotational force, characterized in that a plurality of projections are formed radially on one side of the bottom facing the bottom of the fixing plate. The heat generating device using a rotational force of claim 1, further comprising a safety valve in the fluid tank. The heat generating device using a rotational force of claim 2, further comprising a temperature control sensor in the fluid tank. According to claim 2 or 3, wherein the heat generating apparatus using a rotational force further comprises a bearing in each of the hollow formed in the cover of the cylinder and the fluid tank for supporting the rotating shaft. [5] The heat generating apparatus using rotational force of claim 4, further comprising an oil seal in the hollow formed in the cover of the fluid tank. delete