KR101506808B1 - The flow rate of the water to rising heat that is equipped with an open-cell disk device and the cell disk - Google Patents

Abstract

The present invention relates to a heat generator equipped with an open type cell disk increasing the flow rate of water and the cell disk thereof and, more specifically, to a heat generator equipped with an open type cell disk increasing the flow rate of water to allow water to flow into a penetration groove to maximize the flow rate of the water when the cell disk rotates and the cell disk thereof. According to the present invention, the heat generator comprises: a housing; an inlet to supply water to the inner portion of the housing; and an outlet to flow the water in the inner portion thereof to the outside, wherein a shaft shaft grounding with a bearing and a plurality of the cell disks composed on the shaft in the housing rotate to rub and heat the water to flow the same to the outside.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a heat generating device having an open cell disk for increasing the flow rate of water,

The present invention relates to a heat generating device having an open cell disk for increasing the flow rate of water and a cell disk therefor. More particularly, the present invention relates to a heat generating device comprising a cell disk having a depth different from that of the cell disk, The present invention relates to a heat generating device having an open cell disk for forming a penetrating groove into the formed plate to increase the flow rate of water that can maximize the cavitation effect on water by flowing water into the penetrating groove, .

Generally, a boiler is widely used as a heating or hot water supply device by heating fluid (water). These boilers heat the water for a certain period of time and supply it to the water supply or heating system through piping. Here, as a means for heating water, a separate combustion chamber is usually provided to heat the water.

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

The boiler has been improved in performance due to the improvement of the technology, which makes it easier to handle. However, the structure of the boiler is complicated, requiring a high level of skill in construction, maintenance and repair. Also, Fuel costs are increasing due to high oil prices.

In order to solve these problems, various types of energy saving boilers have been introduced due to the reduction of fuel loss. However, there is a limit to energy saving remarkably by burning fuel such as oil, gas and coal to heat water There was no.

In addition, the boilers have a considerable amount of wasted fuel due to a decrease in efficiency relative to fuel, and the harmful gas generated when the fuel is burned is a social problem as a main cause of environmental pollution.

In particular, the need for alternative energy means is increasing more and more because energy conservation resources are depleted in recent years and high oil prices continue for a long time.

Looking at recent boilers,

No. 10-0426376 relates to a 'hot water boiler', in which a combustion chamber having a sight window and a burner is formed in a lower portion of a boiler body formed with a waste gas guide plate, and a second hot water transfer passage A primary and secondary waste gas transfer passages are formed in a plane with an inner diameter and an outer diameter of a heat exchange pipe and a heat exchange pipe divided into a primary and a secondary in the center, a primary hot water transfer passage is formed outside the combustion chamber, Is a hot water boiler in which a waste gas collecting chamber and a waste gas discharge port are formed, the waste gas collecting chamber and the water inlet are formed, and a waste gas final discharge port is formed outside the boiler body.

Open No. 10-2001-0107891 relates to a 'domestic boiler'. In a combustion chamber formed in a boiler body, a sight window and a burner are installed, and a plurality of dual pipe heat exchange pipes, in which an electric combustion chamber and a waste gas collecting tank are fixed, The pump is installed in the lower part of the boiler body so that water can be injected into the pump inlet. When the water is injected into the pump inlet, the water is instantaneously turned into hot water through the combustion chamber outer wall hot water transfer passage, When the hot water is collected in the hot water storage tank, the hot water heat exchanger pipe installed in the hot water storage tank is heated and the water injected into the hot water inlet of the hot water heat exchanger pipe is heated by the hot water And discharged to the hot water outlet. The hot water collected in the hot water storage tank is discharged to the hot water discharge outlet and used for heating hot water or drying heat. In order to increase the efficiency of the boiler, the heat exchange pipe in the water collecting tank is fixed and installed to reuse the heat of the waste gas. When the exhaust gas is discharged to the lower side of the waste gas discharge port so that the outside of the heat exchange pipe can be heated again by the heat of the waste gas collected in the waste gas discharge hole collected in the waste gas collecting tank, And it is discharged to the final discharge port after colliding with the waste gas blocking plate which is made to stay for a long period of time, thereby increasing the efficiency of the boiler and reducing the fuel consumption.

As described above, the conventional boiler has a complicated structure of the boiler due to the formation of the conduit in which the hot water generated due to the heat is generated by generating the heat, and the thermal efficiency is lowered compared with the structure of the boiler. A plurality of pipelines have to be formed for the purpose of generating heat, or a configuration for additional heat generation has to be added.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art described above, and it is an object of the present invention to provide a cell- And a plurality of through grooves connecting the grooves and the grooves having different depths are formed in the inside of the plate, so that when the cell disk is rotated, The present invention has been accomplished on the basis of providing a heat generating device and a cell disk having the open cell disk for increasing the flow rate of water that can maximize the flow rate to water.

According to an aspect of the present invention, there is provided an air conditioner comprising: a housing; an inlet for supplying water to the inside of the housing; and an outlet for discharging water from the inside of the housing to the outside, A heat generating device that frictionally heats water by rotating a plurality of cell discs formed on a shaft shaft that rotates by the operation of a driving device and is grounded with a bearing and an inner shaft shaft of the housing and flows out to the outside, A first plate and a second plate having different sectional areas are formed between the first groove and the second groove, wherein the first plate and the second plate have different depths from the outer peripheral surface to the center, And a second groove formed between the first groove portion and the second groove portion and having a through groove for connecting the first groove portion and the second groove portion, And an open cell disc formed between the first groove and the first groove and increasing a flow velocity of water formed in the through groove connecting the second groove and the first groove, and a cell disc .

According to the present invention, there is provided a heat generating device including an open cell disk for increasing the flow rate of water, and water flowing into the housing of the heat generating device is formed in each plate having a different cross- The cavitation effect is generated by increasing the flow rate in the rotating direction by forming each of the plates having different cross sectional areas when the cell disk rotates by raising the cation effect on water flowing into the through grooves and flowing into the through grooves A plurality of the through grooves are formed and the through grooves are selectively formed to be wide or narrow according to use so as to maximize the cavitation effect on water and further increase the efficiency of the heat generating device, It is an invention that can improve the quality.

1 is a side sectional view showing a heat generating device to which the present invention is applied;
2 is a front view showing a cell disk in the configuration of the present invention;
FIG. 3 is a front cross-sectional view showing the cell disc of FIG. 2 in detail;
Figure 4 is a side cross-sectional view of the cell disk of Figure 2;
Figure 5 is a front section view of the water flow for the cell disk of Figure 3;
Figure 6 is a side cross-sectional view showing the flow of water for A in Figure 5;
Fig. 7 is a side sectional view showing another embodiment of the through-hole in Fig. 6
8 is a side sectional view showing an embodiment of a heat generating apparatus to which the present invention is applied
FIG. 9 is a front view showing another embodiment of the cell disk in the structure of the present invention; FIG.
Fig. 10 is a side sectional view showing the cell disk of Fig. 7
Fig. 11 is a side sectional view showing a protrusion formed on the cell disc,
12 is a side sectional view showing a groove formed in a cell disk,
13 is a front view showing a groove portion having a different depth to the cell disk in the configuration of the present invention
Fig. 14 is a front view showing another embodiment of the cell disk in the configuration of the present invention

Referring to FIGS. 1 to 14, a heat generating device including an open cell disk for increasing the flow rate of water according to the present invention and a structure of the cell disk will be described. The housing 100 is provided, An inlet 110 for supplying water to the housing 100 and an outlet 120 for discharging water to the outside of the housing 100. The housing 100 is connected to the housing 100 through the housing 100, A heat generating device 10 that frictionally heats water and discharges the water to the outside by rotation of a plurality of cell discs 500 formed on the inner shaft shaft 400 of the housing 100 The cell disc 500 includes a cell disc 500 having a first groove 510 and a second groove 520 having a predetermined depth from an outer circumferential surface to a center of the cell disc 500, The first groove portion 510 and the second groove portion 520 are formed between the groove portions 520, A first plate 600 having a through groove 610 for connecting the first groove portion 520 and the first groove portion 510 and a second groove portion 520 formed between the second groove portion 520 and the first groove portion 510, 510) are formed in the second plate (700).

The present invention relates to a cell disk 500 among the structures of the heat generating device 10 and the housing 100 excluding the cell disk 500, the driving device, the bearing, and the shaft shaft 400 are generally used And thus the above description is omitted.

Referring to FIG. 1 to FIG. 14, a cell disk 500 according to the present invention will be described.

Generally, the cell disk 500 has a circular shape and is connected to a shaft axis 400 inside the housing 100, and the cell disk 500 rotates by the rotation of the shaft axis 400.

At this time, the water flowing through the inlet 110 of the housing 100 is heated by the rotation of the cell disk 500, and the heated water is discharged through the outlet 120.

Referring to FIG. 1 through FIG. 14, the cell disc 500 will be described in detail.

The cell disc 500 is formed with a first groove 510 and a second groove 520 by forming grooves having a predetermined depth in the direction from the outer circumferential surface to the center.

A plate is formed between the first groove part 510 and the second groove part 520. The plate includes a first plate 600 formed between the first groove part 510 and the second groove part 520, And a second plate 700 formed between the second trench 520 and the first trench 510.

In detail, the cell disc 500 has a generally circular shape, and the structure of the cell disc 500 will be sequentially described. The cell 500 includes a first groove 510, a first plate 600, A second groove portion 520, and a second plate 700 are sequentially formed.

The first plate 600 and the second plate 700 may be formed in a plurality of the first and second plates 600 and 700. In this case, The first and second plates 600 and 700 can be formed by forming the first and second grooves 520 and 520, respectively.

A first plate 600 and a second plate 520 are sequentially formed on the first plate 600 and the second plate 700. The first plate 600, A second plate 700, a first groove 510a, a first plate 600a, a second groove 520a, and a second plate 700a are sequentially formed.

13, the depths of the first and second trenches 510 and 520 may be different from each other. The first depth 530 and the second depth 530 of the first trench 510 and the second trench 520 may be different from each other. The second depths 540 of the second groove 520 are different from each other and the sectional areas of the first plate 600 and the second plate 700 are different from each other, To increase the cavitation effect.

Through holes 610 and 710 are formed in the first plate 600 and the second plate 700, respectively.

Referring to FIGS. 3 to 7 and 9 to 12, the through-holes 610 and 710 will be described in detail.

The through hole 610 formed in the first plate 600 penetrates the inside of the first plate 600 and connects the first groove 510 and the second groove 520 with each other.

The through hole 710 of the second plate 700 penetrates the inside of the second plate 700 like the through hole 610 of the first plate 600 to form the second groove portion 520 and the first groove portion 510).

One or more through grooves 610 and 710 may be formed in the first and second plates 600 and 700, respectively.

A plurality of through grooves 610 and 710 formed in the first and second plates 600 and 700 may be formed to form a plurality of through grooves 610 and 710, So that they can flow through the through grooves.

In this case, the cell disc 500 having one or a plurality of through grooves may be applied according to the use of the heat generating device 10, and the cell disc 500 having one or a plurality of through grooves may be sequentially formed have.

When a plurality of through grooves 611, 612, 613, 711, 712, and 713 are formed as compared with the one through grooves 610 and 710, the cavitation effect can be increased by increasing the flow velocity with respect to water.

Referring to FIGS. 3 to 7, 11, and 12, a plurality of through-holes formed in the first and second plates 600 and 700 will be described.

First through holes 611, second through holes 612, and third through holes 613 having different sectional sizes are formed in the through holes 610 formed in the first plate 600, Respectively.

The first through-hole 711, the second through-hole 712, and the third through-hole 713 having different cross-sectional sizes are sequentially formed in the through-hole 710 formed in the second plate 700, .

The first through grooves 611 and 711 formed in the first and second plates 600 and 700 and the second through grooves 612 and 712 and the third through grooves 613 and 713 have different sizes And it can be formed by varying the water according to the cavitation effect generated when the water penetrates through the through grooves 610 and 710.

Referring to FIGS. 3 to 7 and FIGS. 9 to 14, the through-holes 610 and 710 having the plurality of holes are described in detail.

612, 613, 711, 712, and 713 are different from each other when the plurality of through-holes 610 and 710 are formed, and the cross- 611, 612, 613, 711, 712, and 713 having different sizes can be used and they can be formed variously in use.

The through grooves 610 and 710 respectively formed in the first and second plates 600 and 700 may be formed to be wide or narrow.

This may be applied to one or more through grooves 610 and 710, respectively. The shape of the through grooves 610 and 710 may be circular or polygonal.

The protrusions 550 or grooves 560 are selectively formed in the through grooves 610 and 710 formed in the first and second plates 600 and 700 as shown in FIGS.

The protrusions 550 or grooves 560 are formed inside the through grooves 610 and 710 and can maximize the cavitation effect on the water due to the protrusions 550 or the grooves 560, As shown in FIG.

As a result of the cavitation effect, the cell disk 500 is rotated at high speed through the shaft axis 400 in the housing 100 having a certain closed space, so that water flowing along the inside of the housing 100 collides with each other, Cavitation phenomenon (the phenomenon that the gas in the water is separated and bubbles are generated when the flow is accelerated in the water and a low pressure is generated), thereby causing the phase change of the low temperature fluid to the high temperature fluid.

In contrast, the operation of the heat generating device including the open cell disk for increasing the flow rate of water according to the present invention and the operation of the cell disk will be described with reference to FIGS. 1 to 14,

The housing 100 is provided with an inlet 110 through which the water flows and an outlet 120 through which the water flows. The shaft 100 is rotated by driving the driving device provided in the housing 100, The shaft axis 400 extends to penetrate the inside of the housing 100 and the cell disk 500 connected to the shaft axis 400 inside the housing 100 rotates.

Water flowing through the inlet 110 of the housing 100 can maximize the cavitation effect due to the rotation of the cell disc 500, thereby shortening the heat generation time at a high temperature for water.

To explain the heat generated by the water supplied to the housing 100 in more detail,

The water supplied to the inside of the housing 100 comes into contact with the rotating cell disc 500 and the water that comes into contact with the cell disc 500 flows through the through holes 610 and 710 And the inflow water is cavitated due to the rotation of the cell disc 500 and the through grooves 610 and 710.

In order to explain the cavitation effect on the water, the water introduced into the housing 100 is rotated by the shaft shaft 400, and the cavitation effect is generated in the water by rotating the cell disk 500, Water flows into the through grooves 610 and 710 formed in the upper and lower plates 600 and 700 and penetrates the through grooves 610 and 710 to generate a cavitation effect.

When the water flows into the through grooves 610 and 710, if a plurality of the through grooves 610 and 710 are formed, the size of the through grooves 610 and 710 increases.

In addition, the protrusion 550 or the groove 560 may be selectively formed in the through grooves 610 and 710 through which the water flows in and out, thereby maximizing the cavitation effect on the water.

As described above, according to the present invention, the water introduced into the housing 100 of the heat generating device 10 passes through the through holes (not shown) formed in the plates 600 and 700 having different sectional areas when the cell disc 500 rotates 610 and 710 so as to increase the effect of water on the water flowing into the through grooves 610 and 710 and to prevent the plates 600 and 700 having different sectional areas when the cell disk 500 rotates 612, 613, 711, 712, and 713 are formed in a plurality of the through grooves 610, 710, and the cavities 611, 612, 613, 711, 712, And thus the cavitation effect on the water is maximized. Further, the efficiency of the heat generating device 10 can be increased, which is an invention that can improve the quality of the product.

10: Heat generating device
100: housing 110: inlet 120: outlet
400: shaft shaft
500: cell disk
510: first groove portion 520: second groove portion 530: first depth
540: second depth 550: projection 560: groove
600: first plate 610: penetrating groove 611: first penetrating groove
612: second through groove 613: third through groove
700: second plate 710: penetrating groove 711: first penetrating groove
712: second through groove 713: third through groove

Claims (9)

A cell disc 500 having a first groove 510 and a second groove 520 having a predetermined depth from the outer circumferential surface to the center,
A first plate 600 formed between the first groove 510 and the second groove 520 and having a through groove 610 connecting the first groove 510 and the second groove 520, Wow,
A second plate 700 formed between the second groove 520 and the first groove 510 and having a through groove 710 connecting the second groove 520 and the first groove 510, Characterized in that an open cell disk for increasing the flow rate of water
The method according to claim 1,
Wherein a depth of the first groove portion (510) and a depth of the second groove portion (520) formed in the cell disc (500) are different from each other.
The method according to claim 1,
Wherein the through holes (610, 710) formed in the first and second plates (600, 700) are selectively formed to be wide or narrow.
The method according to claim 1,
Wherein protrusions (550) or grooves (560) are selectively formed in the through grooves (610, 710) formed in the first and second plates (600, 700)
The method according to claim 1,
Wherein at least one through hole (610, 710) formed in each of the first and second plates (600, 700) is formed.
6. The method of claim 5,
The first through-hole 611, the second through-hole 612, and the third through-hole 613, which have different cross-sectional dimensions, are sequentially formed in the through-hole 610 formed in the first plate 600, Characterized in that the open cell disk
6. The method of claim 5,
The first through-hole 711, the second through-hole 712, and the third through-hole 713 having different cross-sectional sizes are sequentially formed in the through-hole 710 formed in the second plate 700, Characterized in that the open cell disk
The method according to claim 1,
Wherein a plurality of the first plate (600) and the second plate (700) are sequentially formed.
An inlet 110 for supplying water to the inside of the housing 100 and an outlet 120 for discharging water inside the housing 100 are provided in the housing 100, A shaft shaft 400 connected to the shaft shaft 400 through a driving shaft of the driving unit and grounded with a bearing and a plurality of cell discs 500 formed on the inner shaft shaft 400 of the housing 100, In the heat generating device (10) which frictionally heats and exits to the outside,
Characterized in that the cell disc (500) comprises the cell disc (500) of any one of claims 1 to 8. A heat generating device (100) comprising an open cell disc

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