KR101860822B1 - Fluid heating pump using frictional heat - Google Patents

Abstract

More particularly, the present invention relates to a fluid heating pump. More particularly, the present invention relates to a fluid heating pump, and more particularly, to a fluid heating pump capable of smoothly flowing a fluid by forming a vortex in a process of flowing fluid through an inlet socket, And also allows the fluid to self-heat through rotation of the head instead of indirect heating such as resistance heating using chemical fuels or electric heating lines, thereby improving energy saving and heating efficiency, In addition, a friction protrusion having a plurality of discharge holes is formed on the outer circumferential surface of the turbine, and the discharged fluid has a molecular momentum due to repetition of expansion and compression due to a change in space between the friction protrusions and the housing, And also forms a magnetic field in accordance with the flow of the fluid to decompose the fluid molecules, The bubble generation ring can generate a large number of bubbles in the fluid discharged from the turbine and store the bubbles in the bubbles in the space where the bubbles are generated. To a fluid heating pump using a frictional heat.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a fluid heating pump using frictional heat,

The present invention relates to a fluid heating pump, and more particularly, to a fluid heating pump that induces smooth fluid flow during rotation and promotes molecular motion of fluid due to effective decomposition, thereby improving fluid heating performance. Pump.

Generally, a heating device that heats fluids such as water for hot water supply or heating uses a chemical fuel or electricity to heat the fluid, directly use the heated fluid, or to heat the room at a constant temperature through the heated fluid.

On the other hand, in the heating apparatus using the chemical fuel, a large amount of pollutants are discharged during the combustion process of the chemical fuel, and there is a problem that the thermal efficiency is lowered compared to the consumed chemical fuel. In addition, a heating device using electric energy has a risk of electric leakage or fire depending on the properties of the fluid due to the use of electric resistance or a friction heating which generates heat through the fluid flow. In addition, There is a problem that it takes much time to heat a large amount of fluid.

Recently, a friction heating apparatus in which a fluid is flowed through electric energy and a fluid is directly heated by the flow of the fluid is used. At this time, the friction heater heats the fluid through frictional, cavitation, etc. of the fluid, and in order to promote it, it is important to increase the flow rate and turbulent flow of the fluid.

Thus, the frictional heating has been improved so as to include a case and a cylindrical head rotated inside the case, to generate heat by rubbing the fluid between the head and the case through rotation of the head.

However, if the space is too wide, the amount of friction of the fluid is insufficient and the heating is not performed properly. If the space is too narrow, There is a problem that it takes much time to heat a large amount of fluid.

However, it has a disadvantage in that it can not sufficiently provide a turbulent flow or fluid friction and flow velocity necessary for raising a large amount of fluids.

Korean Patent Publication No. 10-2011-0027157.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for controlling the flow of a fluid, The present invention provides a fluid heating pump using frictional heat for achieving a remarkable improvement in fluid heating performance.

According to an aspect of the present invention, there is provided a base plate, comprising: a base having a plurality of base plates formed at a lower portion of the base plate;

A drive motor which is formed on one side of the upper portion of the base plate and protrudes forward of the drive shaft for generating bi-directional rotational force, and which is closed around the drive shaft by a windshield;

And a front cover having a front end through which a driving shaft penetrates, a front cover through hole formed at the center of the front cover, and a bracket fixed to the base plate, A housing having a plurality of friction ribs formed radially in the longitudinal direction of the inner peripheral surface;

And a first impeller having a through-hole flow path having a spiral protrusion at the center and having a first wing portion at the center thereof, and a second impeller having a second wing portion at the rear end thereof. A second impeller having a second wing portion different from the first wing portion at the front end thereof is fixed to the drive shaft, a plurality of flow grooves are formed at the rear end thereof, and a drive shaft A turbine having protruding frictional protrusions;

A cover ring which is formed at the center and which is coupled to the flat cover, an inlet socket which is inserted into the covering hole and has a through-hole formed at its center on the inner circumferential surface thereof with a vortex generating vane, An inlet formed of a covering end plate;

A magnetizing ring which is formed on an upper portion of the housing and communicates with the heating space of the housing and has a vortex generating protrusion formed on an inner circumferential surface thereof, a magnetizing ring surrounding the outlet tube, a thermometer for measuring the temperature of the fluid formed in and discharged from the outlet tube, A discharge portion formed in the pressure gauge and measuring pressure of the fluid; And

And a case formed on the base plate and covering the drive motor, the housing, the inflow section, and the discharge section,

On the inner peripheral surface of the rear end of the housing,

Further comprising a bubble generating ring,

And a plurality of bubble generating fins each having a ball-shaped protrusion at an end thereof protruded toward the inner side on the inner circumferential surface of the bubble generating ring.

As described above, in the fluid heating pump using frictional heat according to the present invention, a vortex is formed in the process of flowing fluid through the inlet socket, so that the fluid can flow smoothly, and a magnetic field can be formed on the fluid to be introduced, The effect of facilitating heat generation can be obtained.

In addition, it is possible to achieve energy saving and heating efficiency by allowing the fluid to self-heat through rotation of the head instead of indirect heating such as resistance heating using a chemical fuel or a heating wire.

In addition, a friction protrusion having a plurality of discharge holes is formed on the outer circumferential surface of the turbine, and the discharged fluid has a molecular momentum due to repetition of expansion and compression due to a change in space between the friction protrusions and the housing, It is possible to obtain the effect of enabling the above-mentioned effect.

In addition, a magnetic field is formed according to the flow of the fluid to dissolve the fluid molecules, thereby remarkably improving the heating efficiency and preventing the scale from being generated in the process of flowing the fluid.

In addition, it is possible to generate innumerable bubbles with respect to the fluid discharged from the turbine through the bubble generating ring, and to obtain the effect that heat can be stored in the bubble space with respect to the heated fluid.

1 is a perspective view of a fluid heating pump using frictional heat according to the present invention.
2 is an exploded perspective view of a fluid heating pump using frictional heat according to the present invention.
3 is a sectional view of a fluid heating pump using frictional heat according to the present invention.
4 is a perspective view of a housing of a fluid heating pump using frictional heat according to the present invention.
5 is a front perspective view of a turbine of a fluid heating pump using frictional heat according to the present invention.
6 is a rear perspective view of a turbine of a fluid heating pump using frictional heat according to the present invention.
7 is a cross-sectional view of the fluid heating pump using the frictional heat of the present invention on the turbine side.
8 is a sectional front view of a turbine middle portion of a fluid heating pump using frictional heat according to the present invention.
9 is a first sectional front view of a turbine end portion of a fluid heating pump using frictional heat according to the present invention.
10 is a second front sectional view of the turbine end of the fluid heating pump using frictional heat according to the present invention.
11 is a sectional front view of the third end of the turbine tip of the fluid heating pump using frictional heat according to the present invention.
12 is a main part view of an inlet of a fluid heating pump using frictional heat according to the present invention.
Fig. 13 is a main part of a discharge section of a fluid heating pump using frictional heat according to the present invention. Fig.
14 is a flowchart of a fluid heating pump using frictional heat according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

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

FIG. 1 is a perspective view of a fluid heating pump using frictional heat according to the present invention, FIG. 2 is an exploded perspective view of a fluid heating pump using frictional heat according to the present invention, and FIG. 3 is a sectional view of a fluid heating pump using frictional heat.

1 to 3, a fluid heating pump 1 using frictional heat according to the present invention includes a base 100, a driving motor 200, a housing 300, a turbine 400, 500, a discharge unit 600, and an external case 700.

The base 100 forms a base of the fluid heating pump 1 using the frictional heat according to the present invention. The base plate 110 is first formed in the shape of a rectangular plate, The vibration isolator 120 is not provided newly but may be a vibration isolating pad spring or the like in order to prevent the pump 1 from being transmitted to the bottom when the pump 1 is driven. .

The driving motor 200 is formed at one side (corresponding to the right side in the drawing, corresponding to the rear end) of the upper portion of the base plate 110 so as to be capable of imparting bidirectional rotational force. And the tip end of the drive shaft 210 is closed with the windshield 220.

Referring to FIG. 4, the housing 300 is formed into a cylindrical shape that is open to both sides and has a heating space 301 formed therein, and a rear end thereof is coupled to the windshield 220 through bolting or the like.

At this time, the housing 300 is formed with a rear cover 320 through which the driving shaft 210 passes through the rear end inner circumferential surface.

The front end of the housing 300 is formed with a front cover through hole 331 at the center thereof and a front cover 330 having a plurality of front magnets 332 radially formed. A bracket 340 is formed at a lower portion thereof and is fixed to the base plate 110 and coupled to the housing 300 through bolting or the like.

The housing 300 has a plurality of friction ribs 310 radially formed on an inner circumferential surface of the housing 300. The friction ribs 310 each have a longitudinal direction of the housing and are protruded toward the heating space 301 do.

In the housing 300, a plurality of housing magnets 302 are formed in the portion corresponding to the thickness of the housing 300 so as to be radially arranged in the longitudinal direction of the housing 300.

The housing 300 further includes a bubble generating ring 800 on the inner surface of its rear end.

At this time, the bubble generating ring 800 has a plurality of bubble generating fins 810 and 810 'radially formed on the inner peripheral surface thereof. The bubble generating ring 800 has a plurality of bubble generating fins 810 and 810' Shaped projecting portion 811 is formed.

Also, a heater block 350 is further included in the lower portion of the housing 300, and a plurality of heater rods 351 are formed in the heater block 350.

At this time, the operation of the heater rod 351 is not limited. For example, it is preferable that the heater rod 351 is configured to be operable at 0 캜 before the normal water is released through a separate control means (not shown).

5 to 11, the turbine 400 has a cylindrical shape in which a turbine flow path 401 is opened at both ends in the center. The turbine 400 has a first blade portion 412 The front end of the first impeller 410 protrudes from the front end of the front cover 330 and the front end of the first impeller 410 is closed by the first impeller 410 having the flow path 411 formed on the inner circumferential surface thereof. (Not shown in the figure) or the like, and is configured so as not to receive rotational interference.

At this time, a plurality of helical projections 411a are further formed on the inner circumferential surface of the flow path 411 to generate a vortex flow to the fluids flowing through the helical projections 411a to smooth flow into the turbine flow path 401, .

The turbine 400 further includes a step portion 402 protruding toward the inner circumferential surface of the turbine 400. The step portion 402 has second and third blades 421 and 421 ' The second impeller 420 is coupled to the step portion 402 through a bolt or the like and is rotated together with the driving shaft 210 .

At this time, the second and third wing portions 421 of the second impeller 420 are configured to generate vortices in different directions. When the second wing portion 421 rotates in the right direction, The third wing portion 421 'is configured to generate a leftward vortex when it rotates leftward. This is because the operation of the driving motor 200 capable of bi-directional driving and the generation This is to make it possible.

That is, the first wing portion 412 of the first impeller 410 generates a spiral vortex in a direction to flow into the turbine flow path 401, and the second and third wing portions 421 of the second impeller 420 It is possible to generate a helical vortex in both directions in the turbine flow path 401, thereby imparting the multi-directionality of the fluid flow.

A friction protrusion 430 protruding rearward and surrounding the drive shaft 210 is formed at the rear end of the turbine 400. The friction protrusion 430 has a plurality of radially large and large flow grooves 431 And the flow grooves 431 are formed in a radial straight groove with the turbine flow path 401 as a center or as a plurality of grooves radially in the end portions of the friction protrusions 430.

In addition, a plurality of second head magnets 404 are formed in the frictional protrusion 430 so as to be closed by the inside and the stopper 405.

The first friction lug 440, the friction lug 460 and the second friction lug 450 are repeated radially on the outer circumference of the turbine 400. That is, the first friction lug 440, 2 friction protrusions 450 and friction grooves 460 are sequentially formed in a radial direction and the first friction protrusions 440 protrude higher than the second friction protrusions 450, .

Each of the first friction lug 440 and the second friction lug 450 is divided into multiple means in the longitudinal direction of the turbine 400. The first friction lug 440 and the second friction lug 450 are formed in a multi- A ring-shaped groove portion 470 is formed between the projections 450 and the friction grooves 460.

Each of the first friction lugs 440 is formed so that a first discharge hole 441 is communicated with the turbine flow passage 401 and the first discharge hole 441 is communicated with the first discharge hole 441 at both sides thereof, And a first friction hole 442 communicating with the friction groove 460 is formed.

Each of the second friction projections 450 is formed so that a second discharge hole 451 is formed so as to communicate with the turbine flow path 401 and the first and second friction holes 450 and 450 are formed on both sides of the first friction hole 450, A second friction hole 452 is formed.

The turbine 400 also has symmetrical shapes, each having a ring-shaped groove portion 470 therebetween, a first friction protrusion 440 and a third friction protrusion 440 ', and a second friction protrusion 450' The first and second friction protrusions 440 and 450 and the friction grooves 460 and 460 'are formed to extend from the first and second friction protrusions 440 and 450' (460) of the turbine (400).

At this time, a total of nine third friction holes 443 are formed on the outer circumferential end of the third friction protrusion 440 ', three in the longitudinal direction and three in the width direction, and the third friction holes 443 are formed on the second friction groove 460' The fourth friction holes 444 in the third row are arranged such that the fourth friction holes 444 on both sides of the fourth friction holes 444 are in contact with the third friction holes 444, And the fourth friction hole 444 at the center is configured to be horizontal. These different tilts correspond to the rotational directions of the turbine 400 when the turbine 400 is bi-directionally rotated .

Two fifth friction holes 453 are formed on both sides in the longitudinal direction at the outer peripheral end of the fourth friction lug 450 'and a third friction hole 453 is formed at the second friction groove 460' The sixth friction holes 454 are formed so as to be inclined in different directions so as to face the outer circumference of the sixth friction holes 454. The inclination is intended to enable the turbine 400 to be able to correspond to the respective rotational directions during bidirectional rotation.

At this time, the inclination of the fourth friction holes 444 on both sides may be formed to be in communication with the sixth friction hole 454 and to have the same inclination.

The turbine 400 is further configured such that a plurality of first head magnets 403 are radially inserted into the thickness of the turbine 400. Each of the first head magnets 403 is configured to be in the longitudinal direction of the turbine 400 .

Referring to FIG. 12, a covering through hole 511 is formed at the center of the inlet 500 to guide the fluid to the turbine 400, And the covering through hole 511 is configured to be in communication with the front cover through hole 331. [

In the covering 510, a plurality of covering magnets 512 are formed radially.

The inflow part 500 is formed with an inflow socket 520. The inflow socket 520 is inserted into the covering through hole 511. The tip of the inflow socket 520 penetrates through the covering through hole 511 And an inflow hole 521 having a spiral vortex generating vane 522 radially formed on an inner circumferential surface thereof is formed through the center.

In the inflow socket 520, a plurality of inflow magnets 523 are formed radially.

The covering finishing plate 530 is configured to penetrate the center of the covering finishing plate 530 and to cover the inflow socket 520 and to be coupled to the covering 510 through bolts or the like .

Referring to FIG. 13, the discharging part 600 is protruded from the upper part of the housing 300, and the housing 300 is provided with the discharge part 600. The discharge part 600 is configured to discharge the heated fluid in the heating space 301 of the housing 300, And a vortex generating protrusion 611 which communicates with the heating space 301 of the vortex generating unit 300 and vortexes in a direction of being discharged to the inner circumferential surface.

At this time, a magnetizing ring 620 is wrapped around the discharge tube 610, and a plurality of magnetizing ring magnets 621 are formed radially in the magnetizing ring 620.

The discharge unit 600 is connected to the discharge pipe 610 to form a thermometer 630 for measuring the temperature of fluid in the housing 300.

A pressure gauge 640 is formed in the discharge part 600 to measure the pressure of the fluid inside the housing 300.

The outer case 700 is formed as an enclosure having an opened lower portion and is configured to be coupled to the base plate 110 of the base 100 through bolts or the like and includes the driving motor 200, The inflow portion 500, and the discharge portion 600, and can be closed and protected.

Hereinafter, the operation of the fluid heating pump using the frictional heat according to the present invention will be described in detail with reference to the accompanying drawings.

First, in implementing the fluid heating pump 1 using frictional heat according to the present invention, although not shown in the drawing, the inflow sockets 520 are connected to a fluid storage tank or the like to supply fluid, (610) is connected to a pipe for heating or hot water supply.

Therefore,

The fluid heating pump 1 using frictional heat as shown in FIG. 1 through FIG. 3 with reference to FIGS. 1 through 3 is configured such that the fluid flows through the inlet 500 and flows into the housing 300 by rotation of the turbine 400 inside the housing 300 And the frictional heat is discharged through the generating and discharging unit 600.

In detail,

First, when the turbine 400 in the housing 300 is rotated by driving the driving motor 200, the first and second impellers 410 and 420 coupled to the turbine 400 rotate together The first wing portion 412 of the first impeller 410 forms a first vortex and the fluid flows through the inlet portion 500 into the turbine flow passage 401 of the turbine 400 .

At this time, the inflow fluid is formed with a vortex generating vane 522 formed on the inner circumferential surface of the inflow socket 520, thereby generating a vortex with respect to the inflow fluid, thereby inducing smooth inflow of the fluid.

Referring to FIG. 12, a plurality of inflowing magnets 523 are radially formed in the inflow socket 520, and a magnetic field is formed in the inflow of the fluid to decompose the fluid molecules. The fluid is activated by the decomposition, and scale formation in the inlet sockets 520 can be prevented.

The covering 510 surrounding the inflow socket 520 is formed with a plurality of covering magnets 512 in a radial direction and forms a magnetic field in the course of the inflow of the fluid through the covering magnet 512, Thereby accelerating the decomposition of the catalyst.

The fluid introduced into the turbine 400 flows through the flow path 411 of the first impeller 410 to the inner turbine flow path 401 of the turbine 400 and is then introduced into the turbine 400 The fluid molecules having a high molecular momentum collide with the friction ribs 310 of the housing 300 and the inner circumferential surface of the housing 300 to emit a large amount of energy, .

Here, the friction heating is performed by heating due to friction or collision between fluid molecules, heat generation due to bubble formation and rupture due to acceleration / decompression and deceleration / pressure increase of the fluid, collision between the fluid and the turbine 400 and the housing 300 And heat due to viscous friction, and the like.

The fluid flowing into the turbine flow path 401 of the turbine 400 first generates a first vortex flow in the turbine flow path 401 through the first impeller 410 and the second impeller 420 generates the first vortex flow in the first In this process, the first and second vortices collide with each other to generate fluid frictional heat, and a large number of turbulent flows are generated by the puddle of the vortex flow, The frequency of friction is increased and the heating of the fluid is promoted.

Then, the fluid acting as described above is pressed to the inner circumferential surface of the turbine flow path 401 by the centrifugal force resulting from the rotation of the turbine 400, and the fluid thus pressurized flows through the first friction protrusions 440 and the second friction protrusions 440, The flow velocity is increased in the process of discharging and discharging through the first discharge hole 441 and the second discharge hole 451 communicated with the first discharge hole 450 and the bubbles are formed and the inner wave is promoted,

3 to 11, the fluid discharged through the first discharge hole 441 and the second discharge hole 451 is discharged to the outside of the first friction protrusion 440 and the second friction protrusion 450 The fluid is compressed in a narrow space between the first and second friction protrusions 440 and 450 and the housing 300 when the turbine 400 rotates and the friction groove 460 and the ring shaped groove portion 470 And the housing 300. The repetition of the compression and expansion of the fluid increases the momentum of the fluid molecules and increases the frequency of friction between the fluid molecules, .

The fluid discharged through the first discharge hole 441 of the first rubbing protrusion 440 at the high stage is discharged to the outside of the housing 300, The fluid that is discharged through the second discharge hole 451 of the second friction protrusion 450 at the lower end is moved away from the inner circumferential surface of the housing 300, And collides with the housing 300 at a time difference from the fluid discharged to the first discharge hole 441.

That is, since the turbine 400 protrudes from the outer circumferential surface of the turbine 400 with different steps, the fluid flowing along the rotating direction of the turbine 400 is guided by the first friction protrusion 440, the housing 300 and the second friction protrusions 450, The amount of energy of the fluid molecules is increased. Accordingly, since the fluid can emit a large amount of energy, the temperature rises more rapidly than when it is formed by the same step, .

The first friction lug 440 and the second friction lug 450 each have a first friction hole 442 and a second friction hole 452. The first friction lug 440 and the second friction lug 450 The second friction hole 450 is formed with a lower end than the first friction protrusion 440. The second friction hole 450 has a lower friction coefficient than the first friction hole 450, The fluid is discharged from the hole 452 in the direction toward the outer periphery. In this process, the fluid discharged into the first friction hole 442 and the second friction hole 452 collide with each other to generate a turbulent flow The friction between the first friction hole 442 and the second friction hole 452 causes the fluid to collide with the friction groove 460 to increase the momentum of the fluid molecule.

The third and fourth friction protrusions 440 'and 450' formed at both ends of the turbine 400 are provided with a plurality of third friction holes 443 and fifth friction holes 453 and a third friction hole The fourth friction hole 444 and the sixth friction hole 454 which are in communication with the fifth friction hole 443 and the fifth friction hole 453 and have different inclination are formed. 301) in a plurality of directions while introducing a turbulent flow by collision of fluids and inducing collision of fluids to increase bubble generation and momentum of fluid molecules.

That is, the fluid heating pump 1 using the frictional heat of the present invention enables the fluid discharged from the turbine 400 to heat the fluid by friction and collision between fluids that collide with and discharge from the housing 300, The bubbles are formed during the friction and the collision so that the heating speed of the product is improved.

The front magnet 332, the housing magnet 302 and the first head magnet 403 are formed in the housing 300 and the turbine 400 in the process of friction and impact of the fluid, The fluid is decomposed to form a magnetic field and the fluid molecules are decomposed to thereby activate the fluid and prevent scale from being formed in the turbine 400 and the housing 300.

The fluid to be filled in the heating space 301 of the housing 300 as described above may be formed by forming a plurality of flow grooves 431 in the friction protrusion 430 formed at the rear end of the turbine 400 The fluid is caused to collide with the flow grooves 431 to generate vortices and the vortex generated in the bubble generating ring 800 formed on the inner peripheral surface of the rear end of the housing 300 Collides with the pins 810 and 810 'to generate bubbles, and the bubbles of the heated fluid accumulate heat therein, thereby allowing the heated fluid to be kept warm.

In addition, a plurality of second head magnets 404 are formed in the friction protrusions 430, and the fluid is activated by the decomposition of the fluid molecules in the course of generating vortices.

The fluid heated in the heating space 301 of the housing 300 is discharged through the discharge unit 600 and discharged through the discharge pipe 610 as described above.

At this time, a magnetizing ring 620 having a magnetizing ring magnet 621 is formed around the discharge tube 610. This magnetizing ring magnet 621 generates a scale in the discharge tube 610 while inducing the activation of the fluid. .

In addition, a vortex generating projection 611 is formed inside the discharge pipe 610, and vortices are generated with respect to the discharged fluid, so that the fluid can be smoothly discharged and the flow velocity can be increased.

A heater block 350 having a heater rod 351 formed therein is formed at a lower portion of the housing 300 to constitute the fluid heating pump 1 using the frictional heat according to the present invention. It is possible to prevent the freezing of the paper when the paper is not used.

That is, the heater rod 351 can be configured to be connected to a separate control means through a separate electric wire (not shown in the figure) or the like. When the temperature of the fluid reaches 0 ° C, 300 can be prevented from freezing the fluid remaining in the heating and heating space 301, thereby preventing freezing in winter. Such frost prevention can protect the pump.

100: Base 110: Base plate
120: seismic bridge
200: drive motor 210: drive shaft
220: Windshield
300: housing 301: heating space
310: Friction rib 320: Rear cover
330: Front cover 340: Bracket
350: heater block
400: Turbine 401: Turbine flowrate
410: first impeller 420: second impeller
430: frictional protrusions 440 and 440 ': first and third frictional protrusions
450, 450 ': second and fourth friction projections 460: friction groove
470: ring-shaped groove
500: inlet 510: covering
520: inlet socket 530: covering finishing plate
600: discharge part 610: discharge pipe
620: magnetizing ring 630: thermometer
640: pressure gauge 700: external case
800: bubble generating ring 810, 810 ': bubble generating pin
811:

Claims (6)

A base plate 110 and a plurality of base plates 110 formed at a lower portion of the base plate 110;
A driving motor 200 protruded forward of the driving shaft 210 formed on one side of the upper surface of the base plate 110 to generate bi-directional rotational force and closed around the driving shaft 210 with a windshield 220;
And a rear cover 320 through which the driving shaft 210 passes is formed on the inner circumferential surface of the rear end of the rear cover 320. The front end of the rear cover 320 penetrates through the front cover, A plurality of frictional ribs 310 are formed on the inner circumferential surface of the housing 300 and the plurality of frictional ribs 310 are radially formed on the inner circumferential surface of the housing 300 );
And a through-hole flow path 411 having a spiral projection 411a on the inner circumferential surface at the center thereof is provided at the front end thereof. The through-hole flow path 411 is formed in the front cover through- A first impeller 410 having a first wing 412 formed at the rear end thereof and a step 402 having an inner circumferential surface protruding inwardly at a rear end thereof to allow a fluid to flow in a bidirectional direction Is fixed to the drive shaft 210 through a second impeller 420 having second and third wing portions 421 and 421 'in different rotational directions, a plurality of flow grooves 431 are formed at a rear end thereof, A turbine 400 having a frictional protrusion 430 protruding from the turbine 400;
A cover ring 510 having a cover through hole 511 formed at the center thereof and coupled to the front cover 330 and a through hole 500 having a through hole 521 penetrating into the covering through hole 511 and having a vortex generating vane 522 at its center, An inflow part 500 formed of an inflow socket 520 formed with a cover 521 and a center through type covering finishing plate 530 closing the end of the covering 510;
A discharge pipe 610 which is formed on the upper part of the housing 300 and communicates with the heating space 301 of the housing 300 and has an inner circumferential surface formed with a vortex generating projection 611 and a magnetizing ring 620 surrounding the circumference of the discharge pipe 610 And a pressure gauge 640 formed on the housing 300 to measure the pressure of the fluid. The pressure gauge 640 may be disposed on the discharge pipe 610 to measure the temperature of the fluid discharged from the discharge pipe 610. And
A fluid using frictional heat which is formed on the base plate 110 and includes an external case 700 covering the driving motor 200, the housing 300, the inflow part 500, and the discharge part 600 In the heating pump,
In the housing 300,
A plurality of housing magnets 302 are further included in a radial portion corresponding to the thickness,
In the front cover 330,
A plurality of front magnets 332 are further included in the radial direction,
In the covering 510,
And is configured to further include a plurality of covering magnets 512 in a radial direction,
In the inlet socket 520,
A plurality of inflow magnets 523 are further included in the radial direction,
In the magnetizing ring 620,
And a plurality of magnetizing ring magnets (621) are further included in the radial direction.
delete The method according to claim 1,
The turbine (400)
A plurality of first friction protrusions 440, a friction groove 460 and a second friction protrusion 450 are repeatedly formed radially around the outer circumference of the first friction protrusion 440, ≪ / RTI >
The first friction protrusions 440 and the second friction protrusions 450 are divided into multiple means by multiple means in the longitudinal direction of the turbine 400. Each of the first friction protrusions 440 and the second friction protrusions 450 450 and the friction grooves 460 are formed as ring-shaped groove portions 470,
In each of the first rubbing protrusions 440,
A first discharge hole 441 communicating with the turbine flow path 401 is formed so as to penetrate the outer circumference and a first friction hole 442 communicated with the first discharge hole 441 and opened to the friction groove 460 side is formed on both sides. ),
In each of the second friction protrusions 450,
A second discharge hole 451 communicating with the turbine flow path 401 is formed so as to penetrate the outer circumference and a second friction hole 452 formed on both sides of the second discharge hole 451 is inclined toward the first friction hole 442,
A plurality of first head magnets 403 are formed radially in the thickness portion between the outer circumference and the turbine flow path 401,
Wherein a plurality of second head magnets (404) are radially formed in the friction protrusions (430) to be closed by an inner and a cap (405).
The method of claim 3,
At both ends of the turbine 400,
A third rubbing protrusion 440 'extending in a symmetrical form with a first rubbing protrusion 440 and a fourth rubbing protrusion 450' extending from the second rubbing protrusion 450, respectively, 450 and the friction groove 460 and the second friction groove 460 'extending from the friction groove 460 and the second friction groove 460' In the longitudinal direction,
A total of nine third friction holes 443 are formed at three outer peripheral edges of the third friction lug 440 'in the longitudinal direction and a width direction of the third friction lug 440' A third friction hole 444 communicating with the third friction hole 443,
The fourth friction holes 444 in the third row are configured such that the fourth friction holes 444 on both sides thereof are inclined in different directions so as to face the outer circumference, and the fourth friction holes 444 in the middle are configured to be horizontal And,
Two fifth friction holes 453 are formed on both sides in the longitudinal direction of the fourth friction lug 450 'and a fifth friction hole 453 is formed in the width direction on the second friction groove 460' And a sixth friction hole 454 communicating with the sixth friction hole 454,
And the sixth row of sixth friction holes (454) are inclined in different directions so as to face the outer periphery.
The method according to claim 1,
In the lower portion of the housing 300,
And a heater block (350) having a plurality of heater rods (351) inside the heater block (350).
The method according to claim 1,
On the inner peripheral surface of the rear end of the housing 300,
Further comprising a bubble generating ring (800)
And a plurality of bubble generating pins 810 and 810 'having an elliptical protrusion 811 at their ends are protruded inward from the inner circumferential surface of the bubble generating ring 800. Heating pump.

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