KR20100098913A - Boiler apparatus using friction heat - Google Patents

Abstract

PURPOSE: A boiler apparatus using friction heat is provided to rapidly heat a heat medium between friction plates by reducing the interval between the friction plates in proportion to the rpm of an electric motor. CONSTITUTION: A boiler apparatus using friction heat comprises a box-type heating chamber(1), first and second friction plates(5,7), an electric motor(9), a heat medium supply unit, and a heat medium discharge unit. The first and second friction plates are installed at an interval within the heating chamber. The electric motor rotates one or both of the first and second friction plates. The heat medium supply unit provides heat medium(H) to between the first and second friction plates. The heat medium discharge unit discharges the heat medium heated by the relative motion of the first and second friction plates to the outside of the heating chamber.

Description

Boiler apparatus using friction heat}

The present invention relates to a boiler, and more particularly to a friction type boiler device using kinetic energy.

Boilers, which are widely used for heating in various industrial fields such as general households, vinyl houses, public baths, generate heat by igniting liquid or gaseous fossil fuels, and using the generated heat. Alternatively, there is a method of using a heating wire, and a boiler using solar energy is also provided.

Conventional boilers have an indirect heating system that heats circulating water and circulates it in a heating zone. However, the energy consumption to heat the circulating water is high, and heating costs are burdened in the winter for consumers.

For this problem, a friction type boiler for generating heat by increasing the kinetic energy of water molecules by rotation of the motor has been proposed, but has not been practically used at present. This is the biggest reason that it is difficult to perform the function as a boiler due to the poor heat generation effect.

An object of the present invention for the above problems, to provide a friction type boiler to obtain heat by applying kinetic energy to water, more specifically, it can be applied realistically by maximizing the friction heat, the energy consumption is low and the configuration It is to provide a boiler using this simple and durable frictional heat.

The above object is to rotate any one or more of the first and second friction plates installed in the heating chamber in a state in which the liquid heat medium is introduced into and out of the box-type heating chamber spaced apart from each other. Electric motor for heat medium supply means for introducing the heat medium between the first, second friction plate characterized in that it comprises a heat medium discharge unit for discharging the heat medium heated by the relative movement of the first, second friction plate to the outside of the heating chamber It is achieved by a friction type boiler device.

According to a feature of the present invention, the thrust generating means for generating the thrust in the direction in which the first and second friction plates stick to each other by the relative rotation of the first and second friction plates.

According to a feature of the present invention, the thrust generating means is a gear which is inscribed in the cylindrical hub member and the hub member coupled to the center of the first, second friction plate and fixed to the rotor shaft of the electric motor by a key (key) Including a member, but the hub member and the gear member can be engaged in the form of a helical gear.

According to another feature of the invention, the heat medium supply means is a tubular rotor shaft of the electric motor for rotating the first friction plate so that the tip of the rotor shaft is communicated to the inlet hole perforated in the center of the first friction plate Connect one end of the supply pipe to the rear end of the rotor shaft, connect the circulation pump to the other end of the supply pipe, and provide a plurality of induction grooves extending radially from the inlet hole in the friction surface of the first friction plate. Can be configured.

According to the configuration as described above, the friction plate of the electric motor gradually heats up the heat medium flowing between the first and second friction plates by decreasing the interval between the first and second friction plates in proportion to the rotational speed of the electric motor. This provides a friction type boiler which can be used for heating by heating the heating medium only by the rotation of the electric motor.

Hereinafter, with reference to the accompanying drawings in the detailed description of the present invention will be described in more detail. 1 is a schematic perspective view of a friction type boiler apparatus according to an embodiment of the present invention. 2 is an exploded perspective view of the friction plate of the friction type boiler apparatus according to the embodiment of the present invention.

3 is a partial cross-sectional view taken along the line A-A of FIG. 4 is an exploded perspective view of the rotating shaft of the friction plate and the electric motor for explaining an example of the thrust generating means.

The box-shaped heating chamber 1 has an inlet and an outlet for circulation or flow of the liquid heat medium. The outer wall of the heating chamber 1 is provided with a heat insulating member 3 to prevent heat loss to the outside. The heating chamber 1 is shown as a cube but may be cylindrical or polygonal.

The first and second friction plates 5 and 7 (hereinafter referred to simply as “friction plates”) are installed inside the heating chamber 1 to be rotatable about the central axis X while being separated from each other. The spacing before operation between the friction plates 5 and 7 may be 0.1 to 5.0 mm. This interval is only an example. The friction plates 5 and 7 are in the form of disks, and may have a large moment of inertia such as a flywheel, and it is preferable to select a metal material having a high heat transfer rate.

An electric motor 9 for rotating at least one of the friction plates 5, 7 is provided coaxially with the central axis X of the friction plates 5, 7. More preferably, as shown, the electric motors 9 driving independently of the friction plates 5 and 7 are installed. The electric motor 9 is set to rotate the friction plates 5, 7 in opposite directions. A control unit for controlling the rotation speed of the electric motor 9 and the like will be provided.

A heat medium supply means for introducing a heat medium between the friction plates 5 and 7 is provided. The heat medium supply means has a rotor shaft 11 'of the electric motor 9' for rotating the first friction plate 5 in the form of a pipe, and the front end of the rotor shaft 11 'has a first friction plate ( 5) is connected to the inlet hole 13 in the center of the communication and connected to one end of the supply pipe 15 to the rear end of the rotor shaft (11 '), the circulation pump 17 is the other end of the supply pipe 15 It may be configured by providing a plurality of induction grooves 19 extending in the radial direction from the inlet hole 13 in the friction surface (5a) of the first friction plate (5).

A coupling 21 is connected between the supply pipe 15 and the rotor shaft 11 'to prevent leakage and at the same time serve as a bearing. The heat medium (H) is a friction surface of the first and second friction plates (5, 7) through the supply pipe (15), the coupling (21), the rotor shaft (11 ') and the inlet hole (13) by the circulation pump (17). It is supplied along the flow path extending to the guide groove 19 is provided in.

Each of the friction surfaces 5a and 7a of the first and second friction plates 5 and 7 is provided with a plurality of guide grooves 19 in the radial direction from the center of rotation in the same shape, but in the opposite direction. Each friction plate (5,7) may be approximately four to twelve guide grooves 19, the guide groove 19 may be formed in a spiral. This is to protect the friction plates 5 and 7 by reducing the fluid resistance and to reduce noise.

In addition, the guide groove 19 may be gradually narrowed and lowered toward the outer side of the friction plates 5 and 7. The average depth of the guide groove 19 may be 1 ~ 5mm, the average width may be about 3 ~ 10mm. The high speed rotation of the friction plates 5 and 7 causes the heating medium to move along the guide grooves 19 to form an oil film. In the end, the heating medium is distributed in the radial direction of the friction plates 5 and 7 by centrifugal force. In this process, the heat medium receives negative pressure by the capillary phenomenon and is continuously sucked into the inlet hole 13 of the first friction plate 5.

A heat medium discharge part for discharging the heat medium heated by the relative motion of the friction plates 5 and 7 to the outside of the heating chamber 1 is provided. The heat medium discharge part includes an outlet pipe 23 and a circulation pump 17 connected to the heating chamber 1.

According to a feature of the invention, thrust generating means for causing the friction plates 5, 7 to thrust in the direction in which the friction plates 5, 7 stick together by the relative rotation of the friction plates 5, 7 is further included. Thrust generating means may be a combination of several forms or only one form may be used. EMBODIMENT OF THE INVENTION Hereinafter, the form considered most preferable by this inventor is demonstrated.

The friction plates 5 and 7 are installed to receive a force in a direction approaching each other by the rotation of the electric motor 9. To this end, the friction plates 5 and 7 and the rotor shaft 11 of the electric motor are connected in a similar manner to the helical gear. It is inscribed in the cylindrical hub member 25 and the hub member 25 coupled to the center of the friction plate (5,7) and the gear fixed to the rotor shaft 11 of the electric motor by a key (26, key) Including the member 27, the hub member 25 and the gear member 27 is made possible by engaging in the form of a helical gear. Of course, the hub member 25 and the gear member 27 should be formed in the opposite direction so that the thrust acts in the direction in which the friction plates (5, 7) are stuck to each other by the rotation of the rotor shaft (11).

The friction plates 5 and 7 generate heat at a high temperature by frictional heat, but are not physically damaged because an oil film having a thickness of 0.5 mm or less is formed by the heat medium flowing between the contact surfaces.

In addition, as a thrust generating means, an electromagnet, a permanent magnet or a coil spring may be additionally or alternatively used to perform the same or similar action.

The heat medium described above can be a working oil that continually circulates in a closed loop (indirect heating), or sometimes can be water used directly as heating water (direct heating). What is shown in Figure 1 corresponds to an indirect heating formula. In the case of the indirect heating type, the heat dissipation pipe 29 in which the heat medium flows is connected to the heat exchange tank 31 and has a structure for supplying heating water into the heat exchange tank 31. The heating water is introduced into the heat exchange tank 31 through the heat dissipation pipe 29. The heat dissipation pipe 29 may be configured to be thin and long to widen the heat exchange area. Furthermore, it may be provided with a known heat dissipation means such as heat dissipation fins. The low temperature water flowing into the heat exchange tank 31 through the heat dissipation pipe 29 passes through the heat exchange tank 31 in the elevated temperature after undergoing heat exchange with the heat medium, and is supplied to the point of use. The operating oil is stored as a heat medium in the heat exchange tank 31.

A boiler according to another embodiment of the invention is shown through the perspective view of FIG. 5.

According to the present embodiment, the electric motor 9 is spaced apart from the heating chamber, and the electric motor 9 and the rotating shaft 33 are connected by the belt 35 and the pulley 37 to thereby form the electric motor 9. The rotational force is transmitted to the first and second friction plates 5 and 7 through the belt 35, respectively. This configuration is for preventing the high heat of the friction plates 5 and 7 from being transmitted directly to the electric motor and to protect the electric motor 9 against sudden large loads. In connection with this embodiment, a transmission means such as a gear or a chain belt other than the flat belt may alternatively be used.

According to another embodiment of the present invention, a manner in which any one of the friction plates 5 and 7 is fixed to the inner wall of the heating chamber 1 and using only one electric motor 9 may be considered. And the heat medium can be supplied through the center of the fixed friction plate (5,7). This has the advantage that the configuration of the device can be simplified. However, the calorific value will be lower than the previous embodiment.

6 is a perspective view of a heating chamber according to another embodiment of the present invention, Figure 7 is a schematic cross-sectional configuration thereof.

As shown, the friction plates 5, 7 have the form of a conical barrel. This is to maximize the heating effect by widening the contact surface between the friction plates (5,7). The present embodiment differs only in the shape of the friction plates 5 and 7, and the rest are the same as in the previous embodiment. The guide groove 19 is provided to extend over the entire section of the friction plate.

According to another embodiment of the present invention, the heat medium (H) may be introduced at the same time through the central portion of the first, second friction plates (5, 7).

1 is a schematic perspective view of a friction type boiler apparatus according to an embodiment of the present invention. 2 is an exploded perspective view of the friction plate of the friction type boiler apparatus according to the embodiment of the present invention.

3 is a partial cross-sectional view taken along the line A-A of FIG. 4 is an exploded perspective view of the rotating shaft of the friction plate and the electric motor for explaining an example of the thrust generating means.

5 is a partial perspective view of a boiler apparatus according to another embodiment of the present invention.

6 is a perspective view of a heating chamber according to another embodiment of the present invention, Figure 7 is a schematic cross-sectional configuration thereof.

Explanation of symbols on the main parts of the drawings

One ; Heating chambers 5, 7; First and second friction plate

9 (9 '); Electric motor 11 (11 '); Rotor shaft

13; Inlet hole 15; Supply pipe

17; Circulating pump 19; Induction groove

21; Coupling 23; Outflow pipe

25; Hub member 27; Gear member

29; Heat dissipation pipe 31; Heat exchange tank

35; Belt H; Heating medium

Claims (5)

First and second friction plates 5 and 7 installed inside the heating chamber 1 while being spaced apart from each other in a box-shaped heating chamber 1 through which the liquid heat medium H may flow in and out. 2 Electric motor 9 for rotating at least one of the friction plates 5 and 7, Heating medium supply means for introducing the heat medium H between the first and second friction plates 5 and 7 The first and second And a heat medium discharge part for discharging the heat medium heated by the relative movement of the friction plates 5 and 7 to the outside of the heating chamber 1. The heating medium supply means has a rotor shaft 11 'of the electric motor 9' for rotating the first friction plate 5 in the form of a pipe, and a tip of the rotor shaft 11 'is formed in the first shape. It is connected to the inlet hole 13 perforated in the center of the friction plate (5) and connects one end of the supply pipe (15) to the rear end of the rotor shaft (11 '), the circulation pump 17 to the supply pipe (15) Friction boiler device, characterized in that configured by connecting to the other end of the. The friction type boiler apparatus according to claim 1, wherein the friction surface (5a) of the first friction plate (5) is provided with a plurality of guide grooves (19) extending radially from the inlet hole (13). . 2. The thrust generating means of claim 1, wherein the thrust is generated so that the first and second friction plates 5, 7 cause thrust in the direction in which the first and second friction plates 5, 7 stick together. Friction boiler device further comprising. The thrust generating means is inscribed in a cylindrical hub member 25 and the hub member 25 coupled to a center of the first and second friction plates 5 and 7, and the key 26. Friction, characterized in that it comprises a gear member 27 fixedly coupled to the rotor shaft 11 of the electric motor by the hub member 25 and the gear member 27 to be engaged in the form of a helical gear Type boiler device. 2. Friction boiler device according to claim 1, characterized in that the friction plates (5, 7) are in the form of conical barrels.

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