KR20150129346A - Hot water generating boiler using centrifugal force - Google Patents

Abstract

The present invention relates to a hot water generating boiler to heat water by rotating a disk and generating hot water by friction with the water and, more specifically, relates to a hot water generating boiler capable of preventing the heated hot water and steam from being inserted into a bearing. According to the present invention, the hot water generating boiler comprises: a housing, a rotary shaft, a bearing, a heating disk, and a motor. The housing includes a sealing stand wherein a penetration hole is formed, forming an inlet wherein water is inserted and an outlet wherein the heated water is discharged. The rotary shaft is inserted into the housing; one end of the rotary shaft is exposed outside the housing through the penetration hole; and a water current groove is formed on an outer circumference surface inserted into the sealing stand to prevent water accommodated in the housing from being leaked. The bearing supports on one end of the rotary shaft is exposed to the outside. The heating disk is accommodated in the housing and is arranged along the rotary shaft to integrally be rotated with the rotary shaft at regular intervals. The motor is combined with one end of the rotary shaft and rotates the rotary shaft to heat the water accommodated inside the housing by rotating the heating disk. According to the present invention, the hot water inserted through a driving shaft is induced into a water current guide groove from the water current groove with a centrifugal force as the water current groove is formed on the driving shaft. As such, hot water inside the housing is prevented from inducing into the bearing.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a boiler for generating hot water using centrifugal force,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a boiler for generating hot water using centrifugal force that generates hot water by friction with water while rotating a disk to decompose water, and more particularly, to a boiler for generating hot water, And for boilers for generating hot water.

Generally, boilers are widely used as heating or hot water supply devices. These boilers heat the water for a certain period of time and supply it to the water supply or heating system through the piping.

These boilers heat the water for a period of time and then supply it to the water supply or heating system through the piping. Here, as a means for heating water, a separate combustion chamber is generally used to heat the water.

Recently, the boiler has been improved in performance due to the improvement of the technology, which makes it easier to handle, but the structure becomes complicated, requiring a high skill in construction maintenance and repair. In addition, the burden of fuel supply and demand due to the cost of facilities and high oil prices accompanying boiler handling is increasing.

In particular, recently, electric boilers have been developed so that low-priced electric fuels can save fuel for high oil prices through midnight electricity. However, even with the increase in electric power consumption due to the strong winds, .

In order to solve these problems, various types of energy saving boilers are proposed for reducing fuel loss.

An example of an energy saving boiler is a centrifugal heat pump capable of making a low temperature fluid high temperature by using kinetic energy of a disk rotating without generating heat by combustion (fossil fuel or electricity).

Japanese Patent Application Laid-Open No. 10-2013-0051746 discloses a centrifugal centrifugal heat pump in which hot water is generated by frictional heat of a disk and water molecules that are formed by a plurality of disks for generating frictional heat with water on a driving shaft .

However, the conventional centrifugal heat pump described above has a problem in that corrosion of the bearing occurs due to the flow of hot water or steam into the bearing installed to support the rotation of the upper and lower parts of the driving center shaft in the operation process.

In addition, the conventional centrifugal heat pump has a problem that the driving shaft rotates to rotate the disk at a high speed, but there is a limit in stably maintaining the rotational force of the disk.

The present invention is intended to solve the above problems. An object of the present invention is to provide a hot water generating boiler for preventing hot water heated inside, vapor, steam, or the like from flowing backward to the bearing side.

It is another object of the present invention to provide a boiler for generating hot water capable of stably maintaining the rotational force on the drive shaft and improving the rotational efficiency of the disk.

A hot water generating boiler according to the present invention includes a housing, a rotary shaft, a bearing, a heat generating disk, and a motor. The housing has an airtight base on which a through hole is formed, and an inlet for introducing water and an outlet for discharging the heated water are formed. The rotation shaft is inserted into the housing, one end of the rotation shaft is exposed to the outside of the housing through the through hole, and the water flow groove is formed on the outer circumferential surface inserted into the sealing bar to prevent the water contained in the housing from flowing out. The bearing supports one end of the rotation shaft exposed to the outside. The heat-generating disk is accommodated in the housing and is disposed at a predetermined interval along the rotation axis so as to rotate integrally with the rotation shaft. The motor rotates the rotary shaft by engaging one end of the rotary shaft to rotate the heating disk to heat the water contained in the housing.

In the boiler for generating hot water, it is preferable that the closed block has a water flow guide groove formed on the inner circumferential surface so as to face the water flow groove.

The boiler for generating hot water may further include a shut-off blade coupled to one end of the rotary shaft at an upper portion of the closed block so as to block the steam flowing into the gap between the closed block and the rotary shaft from entering the bearing desirable.

Preferably, the boiler for generating hot water further includes an inertia disk and an inertia block. The inertial disk is coupled to the rotating shaft within the housing to increase the inertial force of the rotating shaft. The inertia block is coupled to an outer circumferential surface of the inertial disk.

The hot water generating boiler may further include a gap disc disposed between the heating discs to maintain a constant gap between the heating discs.

In addition, in the boiler for generating hot water, it is preferable that the heating disk has a friction groove along an outer circumferential surface and a friction hole along a circumferential direction at an edge thereof in order to dissolve and heat water by friction during rotation.

According to the present invention, the water flow groove is formed in the drive shaft, and the hot water flowing through the drive shaft is guided to the water flow guide groove by the centrifugal force in the water flow groove. This prevents the hot water in the housing from flowing into the bearing.

In addition, according to the present invention, since the blocking blade is provided on the upper part of the sealing block, the steam or steam inside the housing is blocked from the blocking blades, thereby preventing the flow of the steam or steam into the bearing.

Further, according to the present invention, the inertial disk and the inertia block are coupled to the rotary shaft, thereby increasing the moment of inertia of the rotary shaft. Therefore, the rotation efficiency of the heat generating disk can be improved.

1 is a conceptual diagram of an embodiment of a hot water generating boiler according to the present invention;
Fig. 2 is an enlarged view of a portion A shown in Fig. 1,
Fig. 3 is a part view of the heat-generating disk of the embodiment shown in Fig.
FIG. 4 is a part of the gap disk of the embodiment shown in FIG. 1,
5 is a part view of the rotating shaft shown in Fig.

1 to 5, an embodiment of a hot water generating boiler according to the present invention will be described.

The hot water generating boiler according to the present invention comprises a housing 10, a rotary shaft 20, a bearing 25, a heat generating disk 30, a shutoff vane 35, a gap disk 37, An inertia block 41, a motor 50, and a frame 55. The inertial block 41 includes a frame member 39, an inertia block 41, a motor 50,

The housing 10 includes an airtight base 11 on which a through hole 12 is formed and includes an inlet 15 through which water flows and an outlet 17 through which water heated by rotation of the heating disk 30 flows, Respectively. A water guide groove (13) is formed in an inner peripheral surface of the sealing bar (11) where a through hole (12) is formed. The water flow guiding groove 13 serves to prevent the water contained in the housing 10 from penetrating into the bearing 25 by utilizing the centrifugal force.

The rotary shaft 20 is inserted into the housing 10 and the one end 20a is exposed to the outside of the housing 10 through the through hole 12 of the sealing ring 11. At this time, a water flow groove 21 is formed in the rotary shaft 20 on a surface facing the water flow guide groove 13 of the sealing bar 11. Since there is a clearance between the rotary shaft 20 and the sealing ring 11, the water contained in the housing 10 flows out through the gap and can penetrate into the bearing 25. At this time, a centrifugal force is generated when the rotary shaft 20 rotates. Then, the water flowing out between the gaps is guided to the water flow guide groove 13 by the centrifugal force in the water flow groove 21 and the water flow guide groove 13. So that water is primarily prevented from being separated from the housing 10 and penetrating into the bearing 25.

The bearing 25 supports one end 20a of the rotating shaft 20 exposed to the outside of the housing 10.

The heat generating disc 30 is accommodated in the housing 10 and is disposed at a predetermined interval along the rotary shaft 20 so as to rotate integrally with the rotary shaft 20. [ At this time, a friction groove (31) and a friction hole (33) are formed in the heat generating disk (30) to dissolve water by friction during rotation and to heat it. The friction grooves 31 are formed along the outer circumferential surface of the heat generating disk 30 and the friction holes 33 are formed along the circumferential direction at the edges of the heat generating disk 30. When the heat generating disc 30 rotates, water is decomposed in the friction grooves 31 and the friction holes 33 and heated by friction.

The interval discs 37 are disposed between the heating discs 30 to keep the intervals of the heat generating discs 30 constant.

The inertial disc 39 and the inertia block 41 serve to increase the inertial force of the rotary shaft 20. [ The inertial disk 39 is coupled to the rotating shaft 20 within the housing 10 and the inertial block 41 is coupled to the outer circumferential surface of the inertial disk 39. [

In the present embodiment, the heat generating disk 30 and the interval disk 37 are alternately arranged between the inertia disks 39 and fastened with the fastening bolts 43 to fix them to the rotary shaft 20. [

The shutoff vane 35 is coupled to one end of the rotary shaft 20 at the upper portion of the sealing pedestal 11 so as to prevent the steam flowing out from the gap between the sealing pedestal 11 and the rotary shaft 20 from flowing into the bearing 25. [ do. The blocking blade 35 may be screwed to the inside of the blocking blade 35 and fixed to the rotating shaft 20 by screwing. The steam flowing out through the gap between the sealing ring 11 and the rotary shaft 20 is blocked by the blocking blade 35 and can not penetrate into the bearing 25.

The motor 50 serves to rotate the rotary shaft 20. A coupling 60 is mounted on one end of the motor shaft 51 and the rotary shaft 20 of the motor 50 to couple the coupling 60 and drive the motor 50 so that the rotary shaft 20 rotates.

The frame 55 serves to fix the hot water generating boiler of the present embodiment.

In this embodiment, when the motor 50 is driven, the rotary shaft 20 rotates. Then, the heat generating disk 30 provided inside the housing rotates. Water is introduced into the housing (10) through the inlet (15) and water is discharged through the outlet (17).

When the heat generating disk 30 rotates, the water inside the housing 10 is decomposed by the friction grooves 31 and the friction holes 33, and is heated by friction. The heated water is discharged through the outlet (17). At this time, since the inertial disk 39 and the inertia block 41 are coupled to the rotary shaft 20, the rotational force of the rotary shaft 20 can be stably maintained. Also, even if hot water or steam flows out from the gap between the sealing ring 11 and the rotary shaft 20 of the rotary shaft 20, the hot water is prevented from being primarily discharged from the water flow groove 21 due to the centrifugal force, 35 prevent steam from penetrating into the bearing 25 directly.

10: housing 11:
12: Through hole 13: Water flow guide groove
15: inlet 17: outlet
20: rotation shaft 21: water flow groove
25: bearing 30: heating disc
31: Friction groove 33: Friction ball
35: blocking blade 37: interval disc
39: inertia disk 41: inertia block
43: fastening bolt 50: motor
51: motor shaft 55: frame
60: Coupling

Claims (6)

A housing having an inlet for introducing water and an outlet for discharging heated water,
A rotary shaft having a water flow groove formed therein to prevent water contained in the housing from flowing out to an outer circumferential surface of the housing, the one end of which is exposed to the outside of the housing through the through hole,
A bearing for supporting one end of the rotation shaft exposed to the outside,
A heating disk accommodated in the housing and spaced apart at regular intervals along the rotation axis so as to rotate integrally with the rotation shaft;
And a motor coupled to one end of the rotating shaft to rotate the rotating shaft to rotate the heating disk to heat the water contained in the housing. The method according to claim 1,
Wherein the hermetically sealed vessel has a water flow guide groove formed on an inner circumferential surface to face the water flow groove. 3. The method of claim 2,
Further comprising a shut-off blade coupled to one end of the rotary shaft at an upper portion of the closed block so as to block steam flowing into the gap between the closed block and the rotary shaft into the bearing. The method of claim 3,
An inertial disc coupled to the rotating shaft within the housing to increase the inertial force of the rotating shaft,
Further comprising an inertia block coupled to an outer circumferential surface of the inertial disk. 5. The method of claim 4,
Further comprising a gap disc disposed between the heating discs to maintain a constant gap between the heating discs. 6. The method according to any one of claims 1 to 5,
Wherein the heat generating disk has a friction groove along an outer circumferential surface thereof and a friction hole along a circumferential direction at an edge thereof in order to dissolve and heat water by friction during rotation.

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