KR20120122442A - a multiplex heating producer which using centrifugal force and friction force - Google Patents

Abstract

PURPOSE: A multiple heat generator with centrifugal force and friction force is provided to generate heat with a minimized installation space in a width direction as the fluid moves along the outer diameter of an impeller. CONSTITUTION: A multiple heat generator comprises a casing, a rotary impeller, a rotary shaft, and fixed impellers(400). A first fluid path penetrates through the rotary impeller. A second fluid path is connected to a rotary impeller to penetrate through the same, thereby being exposed to the outside. The fixed impellers are connected to the casing. A plurality of second guide plates is formed on one side of the fixed impeller. The second guide plates comprise different diameters in order to be alternately placed with a first guide plate.

Description

A multiplex heating producer which using centrifugal force and friction force}

The present invention is provided with a plurality of inlet holes on both sides of the casing having a space while the discharge hole is provided in the center of the inlet hole, mounted through the mechanical chamber inside the casing, a plurality of circular agent having a different diameter as a predetermined thickness An impeller having a configuration in which the first guide plate is arranged at equal intervals is connected on the rotation shaft, and a fixed impeller having a second guide plate is connected to the casing at a position corresponding to the rotary impeller of the first guide plate. The present invention relates to a heat generating apparatus using centrifugal force and friction force, which are installed to sequentially friction the guide plate while the fluid flowing through the centrifugal force moves from the center of the impeller to the outer diameter direction.

In general, the heat generating device is used for supplying heating and steam at home, industrial facilities or agricultural facilities.

The heat generating device mainly used a conventional boiler, etc., the boiler has a number of problems, such as not only complicated equipment, but also discharge various harmful substances during the operation of the boiler.

In order to improve this problem, a number of heat generating apparatuses using fluids have been disclosed, and in Korean Patent No. 780822, a rotating means coupled to a rotating shaft installed at a center of an operation space inside a casing and a fixing means coupled to an outer side of the casing are provided. It is interlocked and installed by a plurality of rotary rings and a fixed ring to form a predetermined gap in the circumferential direction, and a plurality of through-holes are formed in the rotary ring and the fixed ring of the rotating means and the fixed means is supplied through the central fluid supply pipe The fluid is discharged to the outer discharge pipe through the through hole of the rotating ring and the fixed ring in the circumferential direction by the centrifugal force of the rotating shaft to generate heat with compression and frictional force.

However, in the above technique, the fluid introduced into the fluid supply pipe is supplied in the circumferential direction by the centrifugal force of the rotating shaft, and as soon as the fluid is introduced from the fluid supply pipe, the fluid is not circumferentially supplied and distributed evenly, but the fluid is fed. There is a problem that can not maximize the compression and friction process by the rotary ring and the fixed ring has a problem that the heat generation efficiency is not maximized.

In order to improve such problems, a configuration of a heat generating device using a rotational force is disclosed in Korean Patent No. 9,4261, which is fixed as centrifugal force of a rotating shaft and a rotating disk while circulating and supplying a fluid into a casing, as shown in FIG. Cylindrical central body 10a having at least one groove 11 formed in the longitudinal direction on the inner circumference of the heat generating device that generates heat by the compression and frictional force of the disk, and having a discharge port 11a at the center of the groove. And the left and right body (10b, 10b ') is coupled to form a casing 10, the rotating disk 20 is installed in the center of the casing to be installed to drive the rotary shaft 20 to rotate on the outer periphery ( 31) and the rotary ring 32 and the fixed disk 41 and the fixed ring 42 in close contact with the inner circumference of the casing on the outer side of the rotating disk and the rotating ring into the central body (10a) At least one insert is provided to be inserted into the configuration, but one side of the rotating shaft 20 has a fluid supply hole 21 along the longitudinal direction in the inner center, the branch hole 22 and the branch hole penetrating radially of the supply hole is Is connected to form a groove 25 formed along the longitudinal direction on the outer periphery of the rotary shaft is installed to evenly supply the fluid through the center of the rotary shaft.

However, the heat generating device using the rotational force as described above, the frictional force is generated only on one side of the rotary ring supported on the rotating shaft 5, the heat transfer efficiency is lowered, so that the fluid is supplied only through one fluid supply pipe (8) There is a disadvantage that the flow of the fluid is not made smoothly.

In addition, the configuration of forming the fluid supply hole 21 penetrates the rotating shaft, and the manufacturing thereof becomes difficult, and there is a problem in that the supply of the fluid cannot be made smoothly.

An object of the present invention for improving the conventional problems as described above, to maximize the centrifugal force and frictional force to heat the fluid with less time and less power source, the guide plate while the fluid rotates along the outer diameter direction from the center of the impeller It is possible to generate heat while minimizing the installation space in the width direction by sequentially moving the structure, to enable rapid heat transfer by smoothly supplying and discharging the fluid, and to simplify the structure and make it easy to manufacture and install. It is possible to provide a multiple heat generating apparatus using centrifugal force and frictional force to minimize the damage of the sealing part due to overheating.

In order to achieve the above object, the present invention is provided with at least one inlet hole on both sides of the casing having a space, and at least one outlet hole is also provided at the center of the inlet hole. At least one rotary impeller having a configuration in which a plurality of first guide plates having different diameters are arranged at equal intervals is connected to one or more at regular intervals on the rotating shaft, and a first flow passage is provided on the rotating shaft through the rotating impeller. It is installed to be connected to the second flow path, the fixed impeller having a second guide plate to correspond to the first guide plate at a position corresponding to the rotary impeller of the first guide plate is connected to the casing, respectively, flowing through the input hole Centrifugal force and friction that are installed so that the fluid moves to the outer diameter direction from the center of the guide plate To provide a heat generating apparatus using the same.

In addition, the casing of the present invention provides a multiple heat generating apparatus using a centrifugal force and a frictional force is installed so that the filling space has a shape in which the diameter gradually increases toward the left or right side on the cross section.

In addition, the impeller of the present invention provides a multiple heat generating apparatus using a centrifugal force and a friction force in which at least one flow hole is integrally provided in the first guide plate or the second guide plate.

In addition, the casing of the present invention provides a multiple heat generating apparatus using a centrifugal force and a friction force provided with at least one of the first cooling nozzle or the second cooling nozzle interconnected to cool the mechanical chamber or the bearing unit.

Subsequently, the rotary shaft of the present invention has a multiple heat generating apparatus using a centrifugal force and a friction force, each of which is provided with a bearing unit and a mechanical seal between the casings and a third impeller for feeding fluid to one side thereof in the longitudinal direction of the rotating shaft. to provide.

In addition, the first nozzle of the present invention provides a multiple heat generator cooling water using a centrifugal force and a frictional force that is close to the rotating shaft and is installed to be sprayed at 180 degrees or more of the rotating shaft.

According to the present invention as described above, by maximizing the centrifugal force and frictional force to heat the fluid in a small time and a small power source, in the minimum installation space through the configuration in which the fluid is sequentially moved while rotating the fluid along the outer diameter direction from the center of the guide plate It is possible to generate heat, to smoothly supply and discharge fluids, to enable rapid heat transfer, and to simplify the structure, making it easy to manufacture and install, and minimizing damage to the sealing part due to overheating.

1 is a side view showing a conventional heat generator.
2 is a perspective view showing a heat generating device according to the present invention.
3 is an exploded view showing a heat generating device according to the present invention.
4 is a sectional view showing a heat generating device according to the present invention.
5 is a cross-sectional view showing a heat generating apparatus according to another embodiment of the present invention.
6 is a sectional view showing a heat generating apparatus according to another embodiment of the present invention.
7 and 8 are respectively a perspective view showing a nozzle of the heat generating apparatus according to another embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing a heat generating apparatus according to the present invention, Figure 3 is an exploded view showing a heat generating apparatus according to the present invention, Figure 4 is a cross-sectional view showing a heat generating apparatus according to the present invention, Figure 5 6 is a cross-sectional view showing a heat generating apparatus according to another embodiment of the present invention, Figure 6 is a cross-sectional view showing a heat generating apparatus according to another embodiment of the present invention, Figures 7 and 8 are each of the present invention A perspective view of a nozzle of a heat generator according to another embodiment.

The present invention is provided with at least one or more input holes 110 along the circumference of the casing 100 on both sides of the casing 100 having a space (S), respectively, between the injection holes 110 located on both sides of the casing, respectively. At least one discharge hole 130 is provided.

In this case, the casing 100 is composed of at least one assembly pipe 103 assembly structure coupled between the plurality of symmetrical side blocks 101 and the side plate 101.

In addition, the rotary impeller 200 is mounted inside the casing 100 through the mechanical chamber 310 and has a shape in which a plurality of first guide plates 210 having different diameters as a predetermined thickness are arranged at equal intervals. Is at least two are connected in the longitudinal direction of the rotary shaft (300).

At this time, the rotary impeller 200 is installed so that the first passage 203 penetrates on one side thereof and is connected to the second passage 303 provided on the rotating shaft 300 so as to penetrate through one end of the second passage 303. The rotary impeller 200 is installed to be exposed to the outside of the rotary impeller when mounted on the rotary shaft.

In addition, a plurality of second guide plates 410 having different diameters and the like may be alternately positioned on the inner surface of the casing 100 so as to alternately position the first guide plate 210 of the rotary impeller 200. Fixed impeller 400 is disposed at intervals are installed.

At this time, the fixed impeller 400 positioned in the space between the fixed impeller 400 is interposed between the rotating impeller 200 is fixed to the casing 100, the fixed impeller 400 is located in the space The third flow hole 403 is further provided at a position protruding while being larger than the diameter of the rotary impeller 200.

In addition, the first guide plate 210 or the second guide plate 410 is provided with a first flow hole 215 or a second flow hole 415.

At this time, the first flow hole 215 or the second flow hole 215 is installed to have a height corresponding to the height of the guide plate is formed to have a constant width and the right angle to the circumference.

In addition, the first flow hole 215 or the second flow hole 215 is installed to have a height corresponding to the height of the guide plate is formed to maintain a constant width and a constant angle with the circumference.

In addition, the first flow hole 215 or the second flow hole 215 is formed through one or more along the circumference on one side in the height direction of the guide plate.

Subsequently, the casing 100 is installed to have a shape in which the filling space 107 gradually expands in diameter toward the center.

In addition, the casing 100 is provided with at least one of the first cooling nozzle 315 or the second cooling nozzle 355 interconnected to cool the mechanical chamber 310 or the bearing unit 350.

Subsequently, the rotating shaft 300 is provided with a third impeller 370 to compress in the longitudinal direction of the rotating shaft of the fluid on one side while being provided with a bearing and a mechanical seal between the casing.

In addition, the first cooling nozzle 315 is configured to be close to the rotating shaft is installed so as to spray the cooling water in more than 180 degrees of the rotating shaft.

The operation of the present invention made of the above configuration will be described.

As shown in Figures 2 to 8, the present invention, after the fixed impeller 400 having the second guide plate 410 is coupled to the side block 101, the rotary shaft 300 is connected to the rotary impeller 300 ) Is fixed inside the one or more connecting tubes 103.

At this time, a fixed impeller 400 is interposed between the connection pipes 103, and second guide plates 410 are provided on both side surfaces of the fixed impeller 400, respectively.

Then, when the connecting pipe 103 and the side block 101 is coupled, the fixed impeller 400 and the rotary impeller 300 and the fixed impeller 400 along the longitudinal direction of the rotary shaft 300, the rotary impeller 300, Fixed impellers 400 are respectively positioned.

At this time, the rotating shaft 300 is easily rotated in the casing 100 through the bearing unit 350, and the leakage of the fluid supplied to the inside of the casing 100 through the mechanical chamber 310 is prevented.

In addition, the first and second guide plates 210 and 410 respectively provided in the rotary impeller 200 and the fixed impeller 400 are alternately arranged to protrude or recess, and thus the input holes of the casing 100 are formed ( A plurality of friction flow paths 109 are formed through which the fluid flowing from both sides of the casing through the 110 is directed toward the discharge hole 130.

That is, the injection hole 110 is formed at least one along the circumferential direction at both sides of the casing 100, the fluid flowing through it is introduced into the space (S) on both sides of the casing, respectively, the friction flow path between the impeller After passing through 109, it is discharged as the discharge hole 130.

In addition, the frictional motion by the fixed impeller 400 and the rotary impeller 200 is the fluid flowing through the friction flow path 109 is moved by the rotational motion of the rotary impeller 200, respectively rubbing in the guide plate to be heated do.

At this time, the fluid is directed to the discharge hole 130 without a separate pump by the rotation operation by the rotary shaft 300 can minimize the energy consumption.

In addition, the first guide plate 210 or the second guide plate 410 is provided with a first flow hole 215 or the second flow hole 415 in the circumferential direction of the centrifugal force as well as the flow hole After passing through the guide plate through the friction along the impeller and rubbing the moving fluid once again to increase the heating effect.

In this case, since the fluid flowing along the friction flow path 109 flows in the first and second flow holes 215 and 415, the fluid may smoothly move and prevent excessive fluid resistance.

In addition, the fuel flowing through the friction passage 109 and the first and second flow holes 215 and 415 collide with each other and collide with each other, so that heat is more smoothly generated.

The first flow hole 215 or the second flow hole 215 is installed to have a height corresponding to the height of the guide plate, and is formed to have a constant width and a right angle with the circumference to allow friction and movement due to a collision. It will be.

In addition, the first flow hole 215 or the second flow hole 215 is installed to have a height corresponding to the height of the guide plate is formed to have a constant width and a circumferential angle and the friction caused by the collision and natural It is possible to move.

Subsequently, the casing 100 moves the fluid in one direction to form a fluid flow toward the second flow path 303 of the rotation shaft 300 while the filling space 107 has a shape in which the diameter gradually enlarges toward the center. A third impeller 370 press-fitted is provided so that the fluid flowing into the rotating shaft toward the friction flow path 109 and the second flow path can be smoothly moved.

That is, when the first impeller 203 penetrates the rotary impeller 200 and is installed to be connected to the second impeller 303 provided on the rotating shaft 300, the fluid impregnated through the third impeller 370. The fluid to be supplied is easily supplied to the guide plate side of the rotary impeller to rub the fluid.

In addition, the casing 100 is configured to include at least one of the first cooling nozzle 315 or the second cooling nozzle 355 which are interconnected to cool the mechanical chamber 310 or the bearing unit 350. Minimize heat generation by high speed rotation of the rotary shaft 300 to prevent damage to the bearing and leakage of the mechanical seal.

In addition, the first cooling nozzle 315 is configured to be close to the rotary shaft to be installed so as to spray the coolant at more than 180 degrees of the rotary shaft to maximize the cooling effect of the mechanical chamber.

100 casing 110 hole
200 ... rotary impeller 300 ... rotary shaft
310 ... mechanical seal 350 ... bearing unit
400 ... Fixed Impeller

Claims (8)

At least one discharge hole 130 is provided on both sides of the casing 100 having a space S, each of which is provided with at least one injection hole 110 along the circumference of the casing 100 so as to be distinguished from the injection hole at one side of the casing. Equipped,
When the rotating shaft is mounted inside the casing 100 through the mechanical chamber 310, a plurality of first guide plates 210 having different diameters as a predetermined thickness are disposed on both sides at equal intervals on the rotating shaft. At least two rotary impeller 200 is connected to the longitudinal direction of the rotary shaft 300,
The rotary impeller 200 is provided so as to penetrate the first passage 203 through the second passage 303 which is provided on the rotary shaft 300 and exposed to the outside of the rotary impeller mounted on the rotary shaft,
The casing 100 has a plurality of second guide plates each having a different diameter as a predetermined thickness so as to be alternately positioned with the first guide plate 210 of the rotating impeller 200, respectively located on the side of the rotating impeller 200. Multiple heat generating device using a centrifugal force and a friction force consisting of a plurality of fixed impeller 400 is connected to the 410 is disposed on at least one surface According to claim 1, wherein the fixed impeller 400 to be positioned between the rotary impeller is formed larger than the diameter of the rotary impeller 200, characterized in that the third flow hole 403 is further provided at the protruding position Heat generator using centrifugal and frictional force The method of claim 1, wherein any one or more of the rotary impeller or the fixed impeller is a first flow hole 215 in any one or more of the first guide plate 210 or the second guide plate 410 protruding on at least one side thereof. ) Or a second heat generating device using the centrifugal force and frictional force, characterized in that the second flow hole 415 is provided The method of claim 3, wherein the first flow hole 215 or the second flow hole 215 is installed to have a height corresponding to the height of the guide plate is formed to have a constant width and the right angle to the circumference, or of the guide plate Centrifugal force and frictional force, characterized in that any one selected from the configuration that is installed to have a height corresponding to the height and having a predetermined angle with a certain width and circumference, or formed through one or more along the circumference in the height direction of the guide plate Multiple heat generator According to claim 1, The casing 100, the filling space 107 is installed so as to have a shape in which the diameter gradually increases toward the center,
At least one or more of the first cooling nozzle 315 or the second cooling nozzle 355 are provided on the rotating shaft and interconnected to further cool the mechanical chamber 310 or the bearing unit 350.
The second cooling nozzle is a multiple heat generating device using a centrifugal force and a frictional force, characterized in that is installed to pass into the space after passing through the bearing The multiple heat generating apparatus using the centrifugal force and frictional force as claimed in claim 5, wherein the first cooling nozzle 315 is formed to be close to the rotating shaft and to enclose at least 180 degrees of the rotating shaft. According to claim 1, The rotating shaft 300 is provided with a bearing unit and a mechanical seal between the casing and the third impeller 370 to compress the fluid in the longitudinal direction of the rotating shaft on one side, characterized in that each is provided Multiple heat generator using centrifugal and frictional force The method of claim 1, wherein the casing 100, the centrifugal force characterized in that the assembly structure of at least one or more connecting pipes 103 are coupled between the plurality of symmetrical side blocks 101 and the side plate 101. Heat generator using friction and friction

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