KR101337837B1 - Centrifugal generating heat pump - Google Patents

Abstract

The present invention provides a centrifugal heat generating pump, which is formed to increase the inflow velocity of a fluid coming into a housing with an impeller installed in the inlet of the housing so that the fluid flowing into the housing at a fast speed through the impeller is induced to generate swirls before fluid molecules collide due to the rotation of a disc, thereby increasing friction among the fluid molecules and increasing heating efficiency.

Description

Centrifugal generating heat pump

The present invention relates to a centrifugal heat pump, and more particularly, to increase the flow rate of the fluid flowing into the housing through the inlet as well as to induce the vortex of the introduced fluid to increase the heat generation efficiency due to friction between the fluid molecules. So that it relates to one centrifugal exothermic pump.

In general, a boiler is widely used as a supply device for heating or hot water. These boilers heat water for a period of time and supply it to the water supply or heating facility through piping. Here, as a means for heating the water, it is common to provide a separate combustion chamber to heat the water.

In recent years, boilers have improved performance due to the development of technology, while handling is simplified, but the structure is complicated, which requires a high level of technology in the process cost and maintenance. In addition, the burden on the supply and demand of fuel according to the cost and high costs associated with boiler handling is increasing.

In order to solve this problem, various types of energy-saving boilers have been proposed.

However, these energy-saving boilers, like conventional boilers, have to face some limitations in saving energy in a way of heating water by burning fuel such as oil, gas, and coal.

In particular, in the reality that energy consumption resources are depleted and the total amount of energy is imported from abroad, the necessity of alternative energy means to solve such long-term high oil price burden is increasing.

In addition, security of energy resources, such as enactment of national energy conservation laws, is more important than ever due to the entry into force of the climate convention. Therefore, the development of the heating / hot water supply facilities through the use of non-fossil fuel is urgently required.

There is a centrifugal heat pump that does not use such fossil fuel, that is, to make a low-temperature fluid high temperature by using kinetic energy through axial rotational force without heat generation by combustion products.

The centrifugal heat pump has a principle of axially rotating a disk through a shaft in a housing having a constant enclosed space so that fluid molecules flowing along the inside of the housing collide with each other to cause a phase change of a low temperature fluid into a high temperature fluid. It is.

However, the conventional centrifugal heat pump has a function and efficiency of colliding fluid molecules as the fluid introduced into the inner space of the housing through the inlet is induced to cause a phase change to a high temperature fluid simply by collision between the fluid molecules due to the rotation of the disk. It has a downside.

Document 1: Korean Patent Office Publication No. 10-2013-0061469

Therefore, an object of the present invention for solving the above problems is to increase the inflow rate of the fluid flowing into the housing through the inlet as well as to induce the vortex of the introduced fluid to increase the heat generation efficiency due to friction between the fluid molecules To provide a centrifugal exothermic pump.

The present invention for achieving the above object is a centrifugal heat pump, the housing is formed with a space in the form of a cylinder and the inlet is formed on one side of the inlet for introducing fluid into the space, which is covered on both open ends of the housing The first and second cover, the second cover is provided in the outlet for discharging the fluid introduced into the inner space of the housing, the shaft is installed to pass through the inner space of the housing and rotates at high speed by the power of the motor provided outside And a first disk coupled to an outer diameter of the shaft and rotating at a high speed with the power of the shaft, and at least one penetrating through an outer surface of the first disk and passing the fluid introduced into the inner space of the housing. Axial shaft which changes the low temperature fluid into high temperature fluid by colliding the fluid according to the high speed rotation of the first disk. A stepped portion formed indented along the outer circumferential surface of the first disc, an outer edge positioned on the outside of the stepped portion and bolted to the first disc, and formed between the outer edge and the stepped portion; A passage portion through which the fluid passing through the axial hole passes through the connection with the axial hole, and a protrusion protruding in an uneven shape along the outer surface of the stepped portion of the first disk and the inner surface of the outer frame; At least one penetrating through the outer circumferential surface of the first disk is supplied to a gap between the outer frame of the first disk and the inner circumferential surface of the housing by receiving a portion of the fluid passing through the axial hole in a state connected vertically to the axial hole A side passage portion configured to discharge and activate a collision of the fluid, and at least one penetrating portion formed along a circumference of the first disc; A passage hole for inducing a collision of the fluid in the process of passing the fluid introduced into the inner space of the housing together with the directional hole and the side passage portion, and the same structure as the first disk, and a predetermined distance behind the first disk The shaft is coupled to the outer diameter of the shaft in a separated state to induce a collision of the fluid to pass the fluid in a state of changing the phase to a high temperature and the shaft in a state located between the first disk and the first cover It is coupled to the outer diameter of the, and rotates at high speed with the first to third disks in accordance with the rotational operation of the shaft to accelerate the inflow rate of the fluid flowing into the inner space through the inlet port and at the same time vortex the fluid It is characterized by including the impeller to make.

In another aspect, the present invention provides a centrifugal heat pump, a housing having a space formed therein in the form of a cylinder and an inlet for introducing fluid into the space on one side thereof, first and second covers which are covered at both ends of the housing. An outlet for discharging the fluid introduced into the inner space of the housing, the outlet being disposed across the inner space of the housing and rotating at a high speed with the power of a motor provided outside; The first disk is coupled and rotates at high speed by the power of the shaft, and at least one penetrating through the outer circumferential surface of the first disk and the high speed of the first disk in the process of passing the fluid introduced into the interior space of the housing; An axial hole for causing a fluid to collide with rotation to phase change a low temperature fluid into a high temperature fluid; A stepped portion recessed along the outer circumferential surface of the disk, a fixed frame positioned outside the stepped portion and coupled to the inner circumferential surface of the housing by a bolt, and formed between the fixed frame and the stepped portion and connected to the axial hole. A passage portion through which the fluid passing through the axial hole passes, a protrusion protruding in an uneven shape along the outer diameter of the stepped portion of the first disk and the inner diameter of the fixing frame, and a circumferential surface of the first disk. At least one through-hole is formed in the same structure as the through-hole and the first disk in the process of passing the fluid introduced into the inner space of the housing together with the axial hole and the passage portion is fixed to the rear of the first disk The second to third disks and the first disk and the first cover yarn coupled to the outer diameter of the shaft in a spaced apart state It is coupled to the outer diameter of the shaft in this state, and rotates at a high speed with the first to third disks in accordance with the rotational movement of the shaft and accelerates the inflow rate of the fluid flowing into the inner space of the housing through the inlet port And at the same time characterized in that it comprises an impeller to vortex the fluid.

The present invention is configured to increase the inflow rate of the fluid flowing into the housing by installing an impeller in the inlet of the housing, before the fluid molecules collide with the rotation of the disk, the fluid flows into the housing through the impeller at high speed By inducing the vortices in the inverted state, the friction between the fluid molecules is increased, thereby realizing the effect of increasing the exothermic efficiency.

1 is an exploded perspective view showing the configuration of a centrifugal heat pump according to a first embodiment of the present invention.
Fig. 2 is a sectional view of Fig. 1; Fig.
3 is an exploded three-dimensional view showing the configuration of a centrifugal heat pump according to a second embodiment of the present invention.
Fig. 4 is a cross-sectional view of Fig. 3; Fig.
5 is a view showing an extract of the structure of the heating bolt assembled to the first disk shown in FIG.
Fig. 6 is a sectional view of Fig. 5; Fig.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the following detailed description, exemplary embodiments of the present invention will be described in order to accomplish the above-mentioned technical problems. And other embodiments which may be presented by the present invention are replaced by descriptions in the constitution of the present invention.

In the present invention, the impeller is installed at the inlet of the housing to increase the inflow speed of the fluid flowing into the housing, before the fluid molecules collide due to the rotation of the disk, the fluid flows into the housing through the impeller at high speed The centrifugal exothermic pump is designed to increase the exothermic efficiency by increasing the friction between the fluid molecules as it induces the vortex in the set state.

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

{Example 1}

1 is an exploded view showing the configuration of a centrifugal heat pump according to a preferred embodiment of the present invention, and FIG. 2 is a cross-sectional view of FIG. 1.

As shown in FIG. 1 and FIG. 2, the centrifugal heat pump according to the first embodiment of the present invention includes a housing 10, a shaft 22, first to third disks 30, 40, and 50 and an impeller. It comprises 60.

The housing 10 constitutes the outer shape of the centrifugal heat pump according to the present invention and has a cylindrical portion 12 formed therein in the form of a cylinder, and both ends thereof are opened to the first and second covers 16 and 18. Configure each to be covered.

One side of the housing 10 is formed through the inlet 14 for supplying a fluid to the inner space 12 of the housing 10.

The second cover 18 located at the rear of the first and second covers 16 and 18 covered at both ends of the housing 10 may be formed in the state of being introduced into the inner space 12 of the housing 10. An outlet for discharging the heated fluid in a collision due to the rotation of the first to third disks 30, 40, 50 is provided.

The shaft 22 is transverse to the center of the housing 10, the front end is coupled to the second cover 18 of the housing 10 and the end thereof is in the state passing through the first cover 16 It is configured to be coupled to a shaft of a motor (not shown) which is a driving source.

The shaft 22 rotates at a high speed by the power of a motor which is a driving source and rotates the first to third disks 30, 40, and 50.

The first to third disks 30, 40, and 50 are coupled to the outer diameter of the shaft 22 while maintaining a predetermined interval to rotate at a high speed according to the rotation of the shaft 22, and the housing 10 The molecules of the fluid introduced into the space portion 12 of the collide with each other to phase change the low temperature fluid into the high temperature fluid.

Since the first to third disks 30, 40, and 50 are manufactured in the same structure, a single disk structure will be described below.

The first disk 30 is in the form of a disc, the coupling hole for coupling to the shaft 22 is formed through the center and the outer peripheral surface thereof is disposed adjacent to the inner peripheral surface of the housing 10, At least one axial hole 32 is formed around the outer circumferential surface of the first disk 30, but the stepped portion 34 is recessed on the outer surface of the first disk 30, and the stepped portion 34 is formed. In the state where the outer frame 37 is positioned between the outer surface step portion 34 and the passage portion 38 of the disk 30, the outer frame 37 is a bolt (33) to the step portion 34 To be fixed).

The passage portion 38 formed between the stepped portion 34 and the outer frame 37 is configured to communicate with the axial hole 32 of the first disk 30.

That is, the first disk 30 configured as described above, the fluid introduced into the inner space 12 of the housing 10 during the high speed rotation by the power of the shaft 22 is the first disk 30 in the rotation operation In the process of passing through the axial hole (32) of the impingement and heated to a high temperature, the heated fluid also passes through the passage portion 38 between the outer frame 37 and the stepped portion 34 of the first disk 30 During the passage, the collision more actively and increases the heat generating efficiency of the fluid.

According to the high speed rotation of the first disk 30, the fluids passing through the passage 38 and colliding with each other are passed through the space formed between the first disk 30 and the second disk 40. .

The fluid introduced into the space between the first and second disks 30 and 40 collides with each other according to the high-speed rotation of the second disk 40 again and is heated to a higher temperature of the second disk 40. After passing through the axial hole 42, it passes into the space formed between the second disk 40 and the third disk 50, the operation proceeds sequentially and as a result the heated hot water 2 is discharged to the outside through the outlet 20 of the cover (18).

The outer circumferential surface of the first disk 30 is further formed with a side passage portion 39 penetrating and connected to the axial hole 32 vertically, the side passage portion 39 is the axial hole 32 Receives a portion of the fluid passing through it is discharged to the gap between the outer frame 37 of the first disk 30 and the inner peripheral surface of the housing 10, wherein the fluid discharged to the gap is the first disk As the rotation of (30) occurs, collision between the fluid molecules occurs once again, thereby increasing the heating efficiency of the fluid.

The outer surface of the stepped portion 34 of the first disk 30 and the inner surface of the outer frame 37 may be formed to protrude at a predetermined distance from the plurality of protrusions 34a and 36a in an uneven form. This is to induce the fluid passing through the passage between the step portion 34 and the fixed frame 36 of the first disk 30 to collide more actively by the protrusions 34a and 36a.

In addition, the inner surface of the side passage portion 39 also has a concave-convex shape so that a plurality of protrusions 39a are formed to protrude at a predetermined interval apart so that a collision of the fluid occurs more actively, thereby increasing the heat generating efficiency of the fluid. do.

A separate through hole 36 is further formed in the circumferential surface of the first disk 30. The through hole 36 flows into the inner space 12 of the housing 10 like the axial hole 32 and the side passage part 34 described above. The fluid collides with each other and rotates so that the heated fluid passes through the space formed between the first disk 30 and the second disk 40.

The impeller 60 is coupled to the outer diameter of the shaft 22 in a state located between the first disk 30 and the first cover 16, and according to the rotation operation of the shaft 22. To a third disk 30, 40, 50 rotates at a high speed, and speeds up the inflow of the fluid flowing into the inner space 12 of the housing 10 through the inlet 14 as well as the housing 10. Induction into the inner space 12 and at the same time inducing vortices to increase the friction between the fluid molecules to further increase the heat generation efficiency.

In the centrifugal heat pump, after the fluid flows into the inner space 12 of the housing 10 through the inlet 14, the shaft 22 rotates at a high speed by the power of the motor, and the impeller 60 and the first to the third to The discs 30, 40, and 50 are rotated.

That is, when the impeller 60 rotates at a high speed, the inflow speed of the fluid flowing into the inner space 12 of the housing 10 through the inlet 14 may be accelerated, as well as the inner space of the housing 10 ( By inducing the vortices of the fluid introduced into 12), the friction between the fluid molecules is primarily increased.

At the same time, the first disk 30 disposed behind the impeller 60 rotates at high speed by driving the shaft 22 and vortexes in the inner space 12 of the housing 10 through the impeller 60. Molecules of the fluid causing the collision with each other in the process of passing through the axial hole 32 and the side passage portion 34 of the first disk 30 will change the low-temperature fluid into a high-temperature fluid.

Next, the fluid passing through the first disk 30 continues to collide with the rotation of the second disk 40 and the third disk 50 to change the fluid into hot water of high temperature.

{Example 2}

3 is a three-dimensional view showing the structure of the centrifugal heat pump according to the second embodiment of the present invention, Figure 4 is a view showing a cross section of FIG.

As shown in Figure 3 and 4, the centrifugal heat pump according to the second embodiment of the present invention, as in the first embodiment described above, the space portion 12 is formed inside the inlet 14 The formed housing 10, the first and second covers 16 and 18 that are covered at both ends of the housing 10, the outlet 20 provided in the second cover 18, and the housing 10. Installed in a state crossing the internal space 12 and coupled to the shaft 22 which rotates at high speed by the power of the motor, the outer diameter of the shaft 22 at a predetermined distance from each other and rotates at high speed by the power of the shaft 22 And first to third disks 130, 140, and 150 for colliding fluid molecules introduced into the inner space 12 of the housing 10 to change the low temperature fluid into a high temperature fluid. It is coupled to the outer diameter of the shaft 22 in a state located between the disk 30 and the first cover 16. The impeller 60 rotates at a high speed by the power of the shaft 22 and induces an inflow velocity of the fluid flowing into the inner space 12 of the housing 10 and a vortex of the fluid. The structure of the third disks 130, 140, and 150 is improved.

That is, as shown in FIGS. 3 and 4, the first disk 130 has a disk shape, and a coupling hole through which the first disk 130 is coupled to the shaft 22 is formed in the center thereof. 10) and adjacent to the inner circumferential surface of the first disk 130, and formed through at least one axial hole 132 around the outer circumferential surface of the first disk 130, the end of the first disk 130 The jaw portion 134 is formed to be recessed, and the fixing frame 136 fixed to the inner circumferential surface of the housing 10 is fixedly installed on the stepped portion 134 by the bolt 133, and the outer surface of the disk 130. The stepped portion 134 and the passage portion 138 are configured to be positioned therebetween, and the passage portion 138 is configured to communicate with the axial hole 132 of the first disc 130.

That is, the first disk 130 configured as described above is the fluid introduced into the inner space 12 of the housing 10 during the high-speed rotation by the power of the shaft 22 is the first disk 130 in the rotation operation In the process of passing through the axial hole 132 of the heating) and heated to a high temperature, and the heated fluid is between the fixed frame 136 in the fixed state and the stepped portion 134 of the first disk 130 in the rotating state. In the course of passing through the passage 138 collides more actively and increases the heat generating efficiency of the fluid.

At this time, the outer surface of the stepped portion 134 of the first disk 130 and the inner surface of the fixed frame 136 is preferably formed to protrude a plurality of protrusions (134a, 136a) in a predetermined distance apart in the form of irregularities. This is to induce the fluid passing through the passage between the stepped portion 134 of the first disk 130 and the fixing frame 136 to collide more actively by the protrusions 134a and 136a.

In addition, a separate through hole 139 is further formed in the circumferential surface of the first disk 130 to induce collision of the fluid passing through the through hole 139 according to the high speed rotation of the first disk 30. In the state of phase change to a high temperature to pass through the space formed between the first disk 30 and the second disk (40).

Meanwhile, a separate heating bolt 180 is further inserted into the through holes of the first to third discs 130, 140, and 150, and the heating bolt 180 more actively fluids passing through the through holes. Induces the collision to increase the heat generating efficiency of the fluid.

Referring to the structure of the heating bolt 180 is inserted into the through-hole 139 of the first disk 130 of the heating bolt 180 as shown in Figures 5 and 6 attached to, The heating bolts 180 are individually inserted into each of the through-holes 139 of the first disc 130. In this case, the outer diameter of the body 182 of the heating bolts 180 is formed in the form of a corrugated pipe, and the through-holes 139 are formed. It is preferable to configure the collision of the fluid passing through the) to actively proceed.

In addition, by making the diameter (D2) of the body 182 of the heating bolt 180 smaller than the diameter (D1) of the through hole 139, the fluid between the inner circumferential surface of the through hole (139) and the heating bolt (180). It is preferable that the clearance C is formed so that it can pass therethrough so as not to disturb the flow of the fluid.

10 housing 12 space
14: inlet 16: first cover
18: second cover 20: outlet
22: shaft 30: first disc
32: axial hole 36: through hole
37: frame 39: side passage
40: second disk 50: third disk
60: impeller

Claims (3)

In the centrifugal heat pump,
A housing 10 in which a space 12 is formed in a cylindrical shape and an inlet 14 for introducing a fluid into the space 12 is formed at one side thereof;
First and second covers (16, 18) which are covered at both ends of the opening of the housing (10);
An outlet 20 provided in the second cover 18 and discharging the fluid introduced into the inner space 12 of the housing 10;
A shaft 22 installed to penetrate the inner space 12 of the housing 10 and rotating at a high speed by the power of a motor provided outside;
A first disk 30 coupled to an outer diameter of the shaft 22 and rotating at high speed by the power of the shaft 22;
At least one penetrating through the outer surface of the first disk 30 and in accordance with the high-speed rotation of the first disk 30 in the process of passing the fluid introduced into the inner space 12 of the housing 10 An axial hole 32 for colliding the fluid to change the low temperature fluid into a high temperature fluid;
A stepped portion 34 formed along the outer circumferential surface of the first disk 30;
An outer frame (37) positioned outside the step portion (34) and coupled to the first disk (30) by a bolt (33);
A passage portion 138 formed between the outer frame 37 and the stepped portion 34 to allow fluid to pass through the axial hole 132 in a state of being connected to the axial hole 32; ;
Protrusions 34a and 36a protruding in an uneven form along an outer surface of the stepped portion 34 of the first disk 30 and an inner surface of the outer frame 37;
At least one penetrating portion is formed along the outer circumferential surface of the first disk 30 and is supplied with a portion of the fluid passing through the axial hole 32 in a state of being vertically connected to the axial hole 32. A side passage part 39 which discharges a gap between the outer frame 37 of the 30 and the inner circumferential surface of the housing 10 to activate a collision of the fluid;
At least one penetrating through the circumferential surface of the first disk 30 and the fluid flowing into the inner space 12 of the housing 10 together with the axial hole 32 and the side passage portion 34 A passage hole 36 for inducing a collision of the fluid in the passage;
It is manufactured in the same structure as the first disk 30 and coupled to the outer diameter of the shaft 22 in a state spaced apart at the rear of the first disk 30 to induce a collision of the fluid to change the fluid to a high temperature Second to third disks 40 and 50 to pass in a state of being made;
It is coupled to the outer diameter of the shaft 22 in a state located between the first disk 30 and the first cover 16, the first to third disk 30 in accordance with the rotation operation of the shaft 22 Impeller 60 to rotate at high speed with the 40, 50 and to vortex the fluid at the same time as the inflow speed of the fluid flowing into the inner space 12 of the housing 10 through the inlet 14 Centrifugal heat pump characterized in that comprises a).
In the centrifugal heat pump,
A housing 10 in which a space 12 is formed in a cylindrical shape and an inlet 14 for introducing a fluid into the space 12 is formed at one side thereof;
First and second covers (16, 18) which are covered at both ends of the opening of the housing (10);
An outlet 20 provided in the second cover 18 and discharging the fluid introduced into the inner space 12 of the housing 10;
A shaft 22 installed to penetrate the inner space 12 of the housing 10 and rotating at a high speed by the power of a motor provided outside;
A first disk (130) coupled to the outer diameter of the shaft (22) and rotating at high speed with the power of the shaft (22);
At least one penetrating through the outer surface of the first disk 130 and in accordance with the high-speed rotation of the first disk 130 in the process of passing the fluid introduced into the inner space 12 of the housing 10 An axial hole 132 for colliding the fluid to change the low temperature fluid into a high temperature fluid;
Stepped portion 134 is formed along the outer peripheral surface of the first disk 130;
A fixed frame 136 located outside the stepped part 134 and coupled to the inner circumferential surface of the housing 10 by bolts 133;
A passage portion 138 formed between the fixed frame 136 and the stepped portion 134 and passing the fluid passing through the axial hole 132 while being connected to the axial hole 132. ;
Protrusions 134a and 136a protruding in an uneven form along an outer surface of the stepped portion 134 of the first disk 130 and an inner surface of the fixing frame 136;
At least one penetrates through a circumferential surface of the first disk 130 and passes the fluid introduced into the inner space 12 of the housing 10 together with the axial hole 132 and the passage portion 138. Passing hole 139 in the process of making;
It is manufactured in the same structure as the first disk 130 and coupled to the outer diameter of the shaft 22 in a state spaced apart at the rear of the first disk 130 to induce a collision of the fluid to change the fluid to a high temperature Second to third disks 140 and 150 to pass in a state of being made;
Coupled to the outer diameter of the shaft 22 in a state located between the first disk 130 and the first cover 16, the first to third disk 130 in accordance with the rotation operation of the shaft 22 , Impeller 60 for rotating the fluid at high speed with the inlet 14 and rapidly advancing the inflow velocity of the fluid flowing into the inner space 12 of the housing 10 through the inlet 14. Centrifugal heat pump characterized in that comprises a).
3. The method of claim 2,
Centrifugal heat pump, characterized in that the heating bolt 180 is fitted into the through hole 139 of the first disk (130).

Images