KR101238544B1 - The centrifugal foot heats and the centrifugal generation of heat way that used a bidirectional revolution - Google Patents

Abstract

PURPOSE: A centrifugal heating apparatus using bidirectional rotation and a centrifugal heating method are provided to improve the thermal energy generation efficiency of water supplied to a housing by rotating cell discs in an opposite direction. CONSTITUTION: A centrifugal heating apparatus comprise a housing(200), first and second shafts(510,520), and first and second cell discs(610,620). Water is supplied to the housing through an inlet, and discharged through an outlet. The shafts penetrate the housing, and rotate by the operation of first and second driving units(310,320). The first cell disc is installed in a rotatable manner at one side around the housing, and connected to the first shaft. The first shaft rotates by the operation of the first driving unit. The second cell disc is installed on the other side, and connected to the second shaft. The second cell disc rotates in the opposite direction to the first cell disc. The second shaft rotates by the operation of the second driving unit.

Description

Centrifugal foot heats and the centrifugal generation of heat way that used a bidirectional revolution}

The present invention relates to a centrifugal heating device that heats a fluid by collision and friction of fluid molecules by centrifugal force by rotational driving of the cell disk without a heating element caused by a combustion product, and more particularly, to rotate the direction of the cell disk in opposite directions. Therefore, the present invention relates to a centrifugal heating device and a centrifugal heating method in which a collision and friction of fluid are increased even at a low speed rotation.

In general, a boiler is widely used as a heating or hot water supply device by heating a fluid (water). Such a boiler is provided with a heating means to heat a predetermined time, and supply to the water supply or heating facility through the pipe.

Here, it is common to provide a separate combustion chamber as a means for heating water to heat water.

The heating means is typically supplied with thermal energy by burning fossil fuels such as oil, gas and coal, or by a heater connected to electricity.

While the boiler is easy to handle as the performance improves due to the development of the technology, the structure is complicated, there is a problem that requires a high level of technology in the construction, maintenance, repair, and also a large amount of fuel used in the heater device As the fuel consumption is increased, fuel costs are increased according to high oil prices.

To solve these problems, various types of energy-saving boilers have been introduced to reduce fuel loss, but there are limits to energy savings by burning water by burning fuel such as oil, gas, and coal. There was no.

In addition, the boilers are a lot of fuel wasted due to the decrease in efficiency compared to the fuel, the harmful gas generated by the combustion of the fuel is a situation that is emerging as a social problem as the main cause of environmental pollution.

In particular, in recent years, energy-free resources are being depleted, and since high oil prices continue for a long time, the need for alternative energy means is increasing.

Looking at a product developed to use such alternative energy,

The invention relates to a "centrifugal heat pump" registered in Korean Patent No. 10-0934244, and is composed of a pump, a shaft shaft, a housing, and a perforated disk. An inlet through which fluid is introduced is formed on one side of the housing, and the other side is heated. The outlet port is formed to discharge the water, and the perforated disc is formed with a through hole drilled on the outer periphery and a side hole drilled perpendicularly to the through hole to generate heat energy by rotational force by centrifugal force.

However, the conventional centrifugal heat pump has a problem that the perforated disc is drilled only to the outside so that no thermal energy is generated inside, so that the thermal efficiency is lowered, and fluid cannot be discharged to the outlet due to the side hole drilled vertically with the through hole. There was also. In addition, the centrifugal heat pump has a troublesome problem that the perforated disc is fixed to the shaft shaft only with a key and the perforated disc is shaken when rotating at high speed, so that the centrifugal heat pump needs to be replaced or repaired for a long time.

Patent No. 10-1043184 relates to a "centrifugal heat generator in which high heat energy is generated." In the centrifugal heat generating device for generating heat energy by rotating the incoming fluid by rotating the fluid, the motor and the motor generating the rotation force It is connected to the housing and receives a rotating shaft for transmitting power and one side of the rotating shaft, the inlet for the fluid inlet on one side, the outlet having a discharge port for discharging the fluid on the other side and the heat energy is seated inside the housing It is formed in a plurality of disk shape to be generated, consisting of a heating disk arranged a plurality of rotating holes in the inner periphery so that the heat energy is generated by the rotational force in conjunction with the rotating shaft, the heating disk between the rotating holes of the heating disk A plurality of long hole-shaped fluid moving holes are arranged to move a large amount of fluid by the rotational force of the It indicates that.

The fluid type centrifugal heating device for generating high heat energy is a centrifugal heating device that generates heat energy by arranging rotating holes in a heating disk configured in a housing and forming a plurality of fluid moving holes to rotate fluids. The centrifugal heating device that generates heat energy by forming a rotating hole and a fluid moving hole in the heating disc has a limitation in generating heat energy, which is a bearing configured in the centrifugal heating device by rotating the cell disk at a high speed in order to increase the efficiency of heat energy generation. , Mechanical seals, etc. shorten the service life and cause a risk of failure.

The present invention has been made in order to solve the problems of the prior art as described above so that the rotation of the cell disk is configured in the housing so as to drive in the opposite direction to each other configured to face each other the cell disk is configured around the housing Due to the driving of the driving device which is responsible for the rotation of each of the opposing cell disks, the cell disks are rotated in opposite directions so that the rotation of the cell disks generates the same high thermal energy as the high speed rotations even at the low speed rotations. Due to the technical problem with the focus on providing a centrifugal heating device and a centrifugal heating method that can shorten the time in the generation of thermal energy, and increase the durability of the centrifugal heating device due to low speed rotation.

According to the present invention for achieving the above object is provided with an inlet for receiving the supply water from the outside and a discharge port for discharging the supply water to the outside and the housing through which the supply water is moved, connected through the housing of the drive device In the centrifugal heating device composed of a shaft shaft which rotates in operation and a cell disk configured to be connected to the shaft shaft inside the housing, the first driving device 310 is operated on one side of the housing 200. The shaft shaft 510 is rotated so that the first cell disk 610 connected to the rotating shaft is configured to rotate, and the second shaft shaft (2) is operated on the other side of the housing 200 by the operation of the second driving device 320. The second cell disk 620 is configured to be rotated so that the 520 is rotated so as to rotate in a direction opposite to the rotation direction of the first cell disk 610.

An inlet for receiving supply water from the outside and a discharge port for discharging the supply water to the outside, the housing to which the supply water moves, a shaft shaft connected through the housing and rotating by operation of a driving device, and the inside of the housing In the centrifugal heating method comprising a cell disk is configured to be connected to the shaft shaft of the, the cell disks (610, 620) connected to the shaft shafts (510, 520) connected to both sides of the housing 200 facing each other correspond to each other It is characterized in that to increase the coagulation effect by rotating the drive in the opposite direction to each other by using each of the drive device 300 by configuring each.

According to the centrifugal heating device and the centrifugal heating method using the bidirectional rotation according to the present invention, in order to increase the thermal energy of the centrifugal heating device, the inside of the housing is configured to face each other and rotated cell disks are rotated mutually It is possible to obtain heat energy easily by rotating in the opposite direction to increase the generation of heat energy for the feed water inside the housing, and the frictional force of the feed water is increased due to the rotation of the cell disks facing each other inside the housing, thereby providing high heat energy. It is possible to obtain, thereby reducing the time for generating thermal energy for the feed water, the effect of which is a great invention.

Figure 1 is a side cross-sectional view showing a preferred embodiment of the present invention
Figure 2 is a side cross-sectional view showing in detail the housing and the bearing portion of the present invention;
Figure 3 is a side cross-sectional view showing the flow of the feed water introduced into the housing of the present invention
Figure 4 is a side cross-sectional view showing a preferred embodiment inside the housing of the present invention
Figure 5 is a side cross-sectional view showing another embodiment of the cell disk in the configuration of the present invention
Figure 6 is a side cross-sectional view showing another embodiment of the cell disk in the configuration of the present invention;
Figure 7 is a side cross-sectional view showing another embodiment of the cell disk in the configuration of the present invention;
Figure 8 is a side cross-sectional view showing another embodiment of the drive device of the configuration of the present invention

Hereinafter, with reference to the accompanying drawings 1 to 8 will be described in more detail the configuration of the present invention.

Centrifugal heating apparatus 100 using bidirectional rotation according to an embodiment of the present invention is a centrifugal heating apparatus 100 for generating thermal energy by rotating the feed water introduced into the housing 200 to the cell disk to rotate the cell disk (100) In the following, the configuration of the present invention will be described in detail.

Referring to FIGS. 1 and 2, an inlet for receiving supply water from the outside and a discharge hole for discharging the supply water to the outside are provided and connected to the housing through which the supply water moves, through the housing, and the driving device and the bearing. In the centrifugal heating device composed of a shaft shaft which is rotated by the negative operation, and the cell disk is connected to the shaft shaft inside the housing, one side of the housing 200 by the operation of the first driving device 310 The first shaft disk 610 is rotated by the first shaft shaft 510, and the second shaft shaft is operated by the operation of the second driving device 320 on the other side of the housing 200. The second cell disk 620 connected to the 520 is rotated so as to rotate in a direction opposite to the rotation direction of the first cell disk 610.

In addition, referring to FIG. 8, an inlet for receiving the supply of water from the outside and a discharge port for discharging the supply of water to the outside are provided and connected to the housing through which the supply water moves, through the housing to operate the driving device. In the centrifugal heating device consisting of a shaft shaft which is rotated in the rotational direction, and a cell disk configured to be connected to the shaft shaft inside the housing, one side of the housing 200 by the operation of the drive device 300, the first shaft shaft ( 510 is rotated so that the first cell disk 610, which is connected, is configured to rotate, and the second shaft shaft 520 is rotated by the operation of the driving device 300 on the other side of the housing 200. The second cell disk 620 to be connected is configured to rotate in a direction opposite to the rotation direction of the first cell disk 610.

This is to rotate the shaft shafts (510, 520) of both sides with one drive device 300 to achieve the rotational speed of the cell disk (610, 620) in the same way to increase the effect of coping.

The cell disks 610 and 620 of the centrifugal heating device 100 having the above-described configuration may rotate in opposite directions so that the rotation of the cell disks 610 and 620 may generate heat energy at high speed even at low speed. So that the collision and friction of the fluid is increased.

Referring to FIG. 7, the first cell disk 610 and the second cell disk 620 configured to face each other inside the housing 200 may face each other to increase frictional force of the feed water. The cell disk 610 and the second cell disk 620 should be spaced apart from each other. This is configured to drive the heat energy generated by the change in the heat energy generated by the spaced apart interval of the first cell disk 610 and the second cell disk 620 rotating in opposite directions to be spaced at a predetermined interval according to use. I would have to.

Referring to FIG. 6, a plurality of first cell disks 610 and second cell disks 620 are respectively provided on the first shaft shaft 510 and the second shaft shaft 520 in the housing 200. It can be constructed.

The number of the first cell disk 610 and the second cell disk 620 formed in the first shaft shaft 510 and the second shaft shaft 520 in the housing 200 depends on the supply water. The intensity of the generated heat energy is changed, thereby increasing the efficiency of the generation of heat energy.

1 to 8, the first cell disk 610 and the second cell disk 620 should have heat generating grooves h formed on one side or both sides thereof.

The heat generating groove h is provided with the first cell disk 610 and the second cell disk 620 facing each other, and the first cell disk 610 and the second supply water supply heat energy generated by rotating in opposite directions. The heat source h is formed in the cell disk 620 to reach the heat energy.

When the centrifugal heating method using the above configuration is described, an inlet for receiving the supply water from the outside and a discharge port for discharging the supply water are provided and connected to the housing through which the supply water moves, and through the housing. In the centrifugal heating method comprising a shaft shaft which is rotated by the operation of the drive device, and the cell disk is connected to the shaft shaft inside the housing, the shaft shaft 510, penetrating to the opposite sides of the housing 200 The cell disks 610 and 620 connected to the 520 may be configured to correspond to each other, and both sides of the cell disks 610 and 620 may be driven to rotate individually in opposite directions by using the driving device 300.

By rotating the shaft shafts 510 and 520 on both sides with one driving device 300, the effect of the coagulation can be increased by achieving the same rotation speed of the cell disks 610 and 620.

When described in detail with reference to Figures 1 to 8 the action according to the centrifugal heating device using the bidirectional rotation of the present invention configured as described above,

As shown in FIGS. 3, 4, and 5, the centrifugal heating apparatus 100 introduces the supply water into the housing 200 and applies heating power to the supply water by using rotational energy to generate heating and hot water. As supplying, the supply water is introduced through an inlet 210 configured at one side of the housing 200, and the supply water introduced into the housing is configured at one side of the housing 200. The first shaft shaft 510 is operated by the driving of the 310, and is connected to the first shaft shaft 510 inside the housing 200 due to the rotation of the first shaft shaft 510. The first cell disk 610 is to be rotated. In this case, the first bearing part 410 serves to help the rotation of the first shaft shaft 510.

In addition, the second shaft shaft 520 operates due to the driving of the second driving device 320 configured on the other side of the housing 200, and the housing rotates due to the rotation of the second shaft shaft 520. The second cell disk 620 configured to be connected to the second shaft shaft 520 inside the 200 is rotated in a direction opposite to the rotation direction of the first cell disk 610. In this case, the second bearing part 420 serves to help the rotation of the second shaft shaft 520.

As described above, each of the first cell disks 610 and the second cell disks 620 configured in the housing 200 rotate in opposite directions to rotate the supply water in the housing 200 to generate heat energy. It can be done.

In addition, referring to FIG. 8, a shaft having a single driving device 300 is provided so as to be connected to each shaft shaft 510 and 520 by dividing the driving from the driving device 300 to both sides. 510 and 520 may be driven in opposite directions.

In order to increase the generation efficiency of the thermal energy, each of the first cell disk 610 and the second cell disk 620 may be configured and driven, and each of the first cell disk 610 and the second cell disk may be driven. The heat generating groove (h) is formed in 620 to supply water to the heat generating groove (h), thereby increasing the rotational force to increase the generation efficiency of thermal energy.

Conventionally used centrifugal heating apparatus has a limitation on the heat energy generated by rotating the supply water by the driving of one drive unit, the bearing unit, the shaft shaft and the cell disk, in the present invention, the first cell disk 610 and By rotating the second cell disk 620 in opposite directions, the effect of coagulation is doubled so that a large amount of thermal energy can be generated even with a small force.

100: centrifugal heating device
200: housing 210: inlet 220: outlet
300: driving device 310: first driving device 320: second driving device
410: first bearing part 420: second bearing part
510: first shaft axis 520: second shaft axis
610: first cell disk 620: second cell disk
h: fever groove

Claims (7)

A housing having an inlet for receiving supply water from the outside and a discharge port for discharging the supply water to the outside, the housing for moving the supply water;
A shaft shaft connected through the housing and rotating by operation of a driving device;
In the centrifugal heating device consisting of a cell disk is connected to the shaft shaft inside the housing,
The first cell disk 610 is configured to rotate the first shaft shaft 510 is connected to one side of the housing 200 by the operation of the first drive device 310,
The second cell disk 620 is configured to be connected to the second shaft shaft 520 by the operation of the second driving device 320 on the other side of the housing 200 so that the first cell disk 610 is connected. Centrifugal heating device using two-way rotation, characterized in that configured to rotate in the opposite direction of rotation of the
A housing having an inlet for receiving supply water from the outside and a discharge port for discharging the supply water to the outside, the housing for moving the supply water;
A shaft shaft connected through the housing and rotating by operation of a driving device;
In the centrifugal heating device consisting of a cell disk is connected to the shaft shaft inside the housing,
One side of the housing 200 is configured to rotate the first cell disk 610 which is connected to the first shaft shaft 510 by the operation of the driving device 300.
The second cell disk 620 of the first cell disk 610 is connected to the other side of the housing 200 so that the second shaft shaft 520 is rotated by the operation of the driving device 300. Centrifugal heating device using bidirectional rotation, characterized in that configured to rotate in the opposite direction of rotation
3. The method according to claim 1 or 2,
The first cell disk 610 and the second cell disk 620 may be configured in plural on the first shaft shaft 510 and the second shaft shaft 520 in the housing 200, respectively. Centrifugal heating device using bidirectional rotation
3. The method according to claim 1 or 2,
The first cell disk 610 and the second cell disk 620, the heating groove (h) is formed on one side or both sides, the centrifugal heating device using bidirectional rotation, characterized in that
3. The method according to claim 1 or 2,
The first cell disk 610 and the second cell disk 620 which face each other in the housing 200 are selectively spaced apart to increase the frictional force of the feed water.
A housing having an inlet for receiving supply water from the outside and a discharge port for discharging the supply water to the outside, the housing for moving the supply water;
A shaft shaft connected through the housing and rotating by operation of a driving device;
In the centrifugal heating method consisting of a cell disk is connected to the shaft shaft inside the housing,
The cell disks 610 and 620 connected to the opposite sides of the housing 200 and connected to the shaft shafts 510 and 520 are respectively configured to correspond to each other, so that the respective driving devices 300 are used. Centrifugal heating method using bi-directional rotation, characterized in that to increase the coagulation effect by individually rotating the cell disk (610, 620) in the opposite direction
The method according to claim 6,
Centrifugal heat generation using bi-directional rotation, characterized in that to rotate the shaft shafts (510, 520) of both sides with one drive device 300 to achieve the same rotational speed of the cell disk (610, 620) to increase the effect of the coagulation Way

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