KR102420181B1 - A cooling turbine apparatus for air cooling device without refrigerant - Google Patents

Abstract

The present invention relates to a cooling turbine device for a non-refrigerant cooling device, capable of reducing energy consumed for cooling, which comprises: an intake (200); a casing (100) having an outlet (102) for discharging cooling air formed on an upper portion; and an impeller (300) rotatably provided in a hollow part (201) of the intake (200).

Description

A COOLING TURBINE APPARATUS FOR AIR COOLING DEVICE WITHOUT REFRIGERANT}

The present invention relates to a cooling turbine device for a refrigerant-free cooling device, and more particularly, it is easy to manufacture due to the simplification of the cooling device as air is introduced due to forced external air to rotate the impeller to activate air circulation. It relates to a cooling turbine device for a non-refrigerant air conditioner capable of reducing energy consumed for cooling as well as cooling.

A blower refers to a mechanical device that generates the energy of a fluid, and generally consists of an impeller that causes a fluid flow, and a casing that guides the flow into and out of the impeller.

In addition, centrifugal blowers usually use a helical casing so that the impeller inlet flow is in the direction of the axis of rotation but the outlet flow is perpendicular to the axis of rotation, and a tubular casing is used so that both the impeller inlet and outlet flows are in the direction of the axis of rotation. cases are largely distinguished.

A turbo blower, a type of centrifugal blower, refers to a centrifugal blower with a relatively high pressure ratio, and the impeller rotates at high speed in the container to make the gas flow radially. , a turbo blower, and a pressure ratio higher than that is called a centrifugal blower or turbo blower.

Such a turbo blower includes a main body forming an exterior, a driving unit provided inside the main body to substantially pressurize air, and a control unit controlling the driving of the driving unit, and the air introduced into the main body through an air inlet formed in the main body is supplied to the driving unit. It is discharged after being pressurized to a certain pressure or more. However, in the prior art, noise generated from the internal driving unit was largely transmitted to the outside, and an internal structure for properly cooling the internal components of the driving unit was not provided, so the lifespan of the internal components decreased, thereby reducing the durability of the entire driving unit. .

Cooling of the inside of the driving unit is usually made in a manner using intake air or gas introduced into the impeller, or blowing a large amount of air through an air gap formed between the rotor and the stator or a cooling hole formed in the stator. used

However, the former method has the disadvantage that although the power required for cooling is small, the sensitivity to the impeller is very high because the cooling system itself has a structure that closely interworks with the impeller, and the overall size of the turbo device increases due to the characteristics of the cooling system have

On the other hand, the latter method has a disadvantage in that cooling efficiency is very low because a large amount of air is blown at a considerable pressure using a cooling fan. Therefore, there is a need for a method capable of increasing the cooling efficiency for cooling the driving unit while using the latter method.

1. Republic of Korea Patent No. 10-1173518 (refrigerant-free air conditioner) 2. Republic of Korea Patent No. 10-2003981 (Double cooling structure of turbo motor composed of bidirectional impeller)

The present invention aims to provide a cooling turbine device for a refrigerant-free air conditioner that can provide an excellent cooling environment by supplying sufficiently cooled air even under a non-refrigerant condition. .

In one embodiment of the present invention for achieving the above object, an upper guide hole communicating with the hollow part is formed while forming a hollow part, and a plurality of air injection passages for communicating the inner and outer peripheral surfaces are formed in the lower injection part, the intake is fixed to the inside, and an intake distribution space is formed between the outer and inner surfaces of the intake injection unit, and an intake port that communicates with the intake distribution space and introduces external air is formed on one surface of the outer side, and is separated from the intake distribution space, and is separated from the intake guide hole and A casing that is connected and an outlet for discharging cooling air is formed in the upper portion, and is rotatably provided in the hollow portion of the intake, rotates by the air injected through the air injection passage, cools the injected air, and guides it in the axial direction of the intake In the cooling turbine device comprising an impeller to be discharged to the outlet of the casing through the guide hole,

Provided is a cooling turbine device for a refrigerant-free air conditioner having a shape in which the air injection passage is formed radially in a curved shape and has an internal cross-sectional area that gradually becomes narrower toward the hollow portion.

On the other hand, it is installed in the injection part of the intake so that intake holes corresponding to the number and shape of the air injection passages are formed, and the intake holes and the air injection passages are installed adjacent to each other so that they communicate with each other, and are mutually symmetric on the outer peripheral surfaces of both sides of the intake holes Provided is a cooling turbine device for a refrigerant-free air conditioner including a cylindrical suction induction plate in which a pair of inclined induction tabs protrude in the form of protrusion.

On the other hand, a pair of horizontal tabs are protruded between the intake holes and the intake holes of the suction induction plate, and the width between the horizontal tabs and the horizontal tabs is formed to correspond to the vertical width of the intake hole. provide the device.

On the other hand, there is provided a cooling turbine device for a refrigerant-free air conditioner in which cylindrical tabs protruding in the circumferential direction of the suction induction plate are formed on both ends of the outer peripheral surface of the suction induction plate, respectively.

On the other hand, there is provided a cooling turbine device for a refrigerant-free air conditioner in which an induction guide protruding from an outer peripheral end of an intake hole formed on an outer peripheral surface of the suction induction plate is formed, and an upper portion of the induction guide is formed to be inclined.

On the other hand, it is coupled between the air injection passage of the intake injection unit and the intake hole of the intake induction plate, and has a width corresponding to the vertical width of the intake induction plate, a thin plate-shaped support plate formed in a horizontal length and an intake hole in the center of the support plate Correspondingly, an air induction part having a guide hole is installed,

A first direction guiding part is formed, which consists of inclined pieces protruding and extending obliquely from both ends of the guide hole of the support plate facing the air injection passage, respectively, and protruding pieces protruding from the front end of the guide hole and having both ends connected to one end of the inclined piece on both sides. ,

Provided is a cooling turbine device for a refrigerant-free air conditioner in which a first direction guide portion and a symmetrical second direction guide portion are formed in a guide hole of a support plate facing the intake hole.

According to the present invention as described above, as described above, the present invention provides a cooling device capable of saving energy while reducing manufacturing cost by providing air cooled by a refrigerant-free cooling turbine device for a cooling device.

1 is a cross-sectional structural view of a cooling turbine device for a non-refrigerant cooling device according to an embodiment of the present invention.
2 is a separate and coupled view of a cooling turbine device for a non-refrigerant cooling device according to an embodiment of the present invention.
3 is a front view (a) of an intake and a cut-away perspective view (b) of an injection unit in a cooling turbine device for a refrigerant-free air conditioner according to an embodiment of the present invention.
4 is a structural diagram of a coupling structure between an injection part of an intake and a suction induction plate in a cooling turbine device for a refrigerant-free air conditioner according to an embodiment of the present invention.
5 is a perspective view of a suction induction plate in a cooling turbine device for a refrigerant-free cooling device according to an embodiment of the present invention.
6 is a partial structural diagram (a) in which an inclined induction tab is formed around the intake hole of the intake induction plate in the cooling turbine device for a refrigerant-free air conditioner according to an embodiment of the present invention (a) and a partial structural diagram (b) in which a horizontal tab is formed; .
7 is a partial structural diagram (a) in which circumferential tabs are formed at both ends of the suction induction plate in the cooling turbine device for a refrigerant-free air conditioner according to an embodiment of the present invention (a) and a partial structural diagram in which guide guides are formed outside the intake hole ( b).
8 is a lower perspective view (a), an upper perspective view (b), and a side view (c) of an air guide part having a first two-way guide part formed in a guide hole of a support plate in a refrigerant-free cooling turbine device for an air conditioner according to an embodiment of the present invention; ).
9 is a partial perspective view (a) and a partial plan view (b) in which a direction guide part is formed in an intake hole of an intake guide plate in a cooling turbine device for a refrigerant-free air conditioner according to an embodiment of the present invention.
10 is a cross-sectional structural view of an air inlet mounted to an intake port of a casing in a cooling turbine device for a refrigerant-free air conditioner according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail through specific examples with reference to the drawings.

In the embodiment of the present invention, as shown in FIGS. 1 to 3, an upper guide hole 202 communicating with the hollow part 201 is formed while forming the hollow part 201, and a plurality of An air injection passage 211 is formed in the lower injection unit 210, the intake 200, the intake 200 is fixed to the inside, the intake 200, between the outer surface and the inner surface of the injection unit 210 As the intake distribution space 103 is formed, a suction port 101 that communicates with the intake distribution space 103 and introduces external air is formed on one surface of the outside, and is separated from the intake distribution space 103, and the guide hole of the intake 200 ( 202) and provided rotatably in the hollow portion 201 of the casing 100 and the intake 200 having an outlet 102 for discharging cooling air formed thereon and spraying through the air injection passage 211 Including an impeller 300 that cools the air rotated and sprayed by the air and guides it in the axial direction to be discharged to the outlet 102 of the casing 100 through the guide hole 202 of the intake 200 In the cooling turbine device,

The air injection passage 211 provides a cooling turbine device 10 for a refrigerant-free air conditioner having a shape in which the internal cross-sectional area is gradually narrowed toward the hollow part 201 while being radially formed in a curved shape.

The cooling turbine device 10 is mounted on the lower inner side of the casing 100 and the casing 100 for discharging cooling air through the impeller 300 while introducing the external air, the introduced external air impeller (300) It is mounted on the intake 200 that sprays air for accelerated injection into the intake 200 and the hollow portion 201 of the intake 200 and rotates by the air injected from the intake 200 to the outlet 102 of the casing 100. Consists of an impeller 300 for discharging cooling air.

The intake 200 has an integral structure divided into an upper mounting part 220 and a lower spraying part 210, and has a hollow part 201 inside, and an upper guide communicating with the hollow part 201 The ball 202 is formed through, and a plurality of air injection passages 211 for communicating the inner peripheral surface and the outer peripheral surface of the injection part 210 are formed.

In addition, the plurality of air injection passages 211 of the injection unit 210 are formed in a radially curved shape and are formed as a cycloid curve having a shape in which the inner width gradually becomes narrower toward the hollow portion 201 while being formed in a curved shape. When air flows into the air injection passage 211, the passage shape of the air injection passage 211 is curved, and the internal cross-sectional area gradually decreases to increase the speed of the air. At the end of the air injection passage 211 , the accelerated air is diffused and injected to increase the rotational speed of the impeller 300 located in the hollow portion 201 .

The cycloid curve has the characteristics of the shortest descent curve that descends the fastest when the same object descends from the same arbitrary position, and the isochronous curve that falls simultaneously to the bottom when an object in a stationary state at different positions on the cycloid curve descends. The branch means a curve, and while the air is amplified and accelerated by the air injection passage 211 to which the cycloidal curve is applied, and discharged into the hollow portion, the impeller 300 located in the hollow portion 201 is rapidly rotated at a constant speed.

And, as shown in FIGS. 1 and 2 , the casing 100 has an intake 200 fixed therein, and an intake distribution space 103 between the outer and inner surfaces of the intake 200 and the injection unit 210 . As this is formed, a suction port 101 communicating with the intake air distribution space 103 to introduce external air is formed on one surface of the outside, and it is separated from the intake air distribution space 103 and is connected to the guide hole 202 of the intake 200 for cooling. An outlet 102 for discharging air is formed at the top.

The outlet 102 connected to the casing 100 may be integrally connected to the casing 100 or may have a mutual assembly structure in a separated form.

An intake air distribution space 103 is formed in the casing 100 in a manner that surrounds the air injection passage 211 of the intake 200 so that air is distributed on the outside of the air injection passage 211 of the intake 200, External air forcedly blown by the device (not shown) for forcibly transporting the The space is formed in a spiral shape in the same direction as the direction of the air flow, and after acceleration of the external air, it is sprayed into the hollow part 201 of the intake 200 along the air injection passage 211 .

That is, the intake air distribution space 103 introduced through the suction port 101 is formed in the shape of a snail shell whose cross-sectional area is gradually narrowed to increase the flow rate and pressure of the air to close the air injection passage 211 of the injection unit 210 . air is rapidly expelled through the

The air sprayed into the hollow part 201 rotates the impeller 300 located in the hollow part 201, and at this time, the air introduced by the rotation of the impeller 300 is cooled and guided in the axial direction of the intake 200. It is discharged to the outlet 102 of the casing 100 through the guide hole 202 .

And, the rotation shaft 310 is coupled to the center of the impeller 300, and the rotation shaft 310 is axially installed in the center of the lower surface of the impeller 300 opposite to the outlet 102, and at this time, the rotation shaft 310 to the lower part of the casing 100 ( 310) and another impeller (not shown) and another casing (not shown) are combined to discharge cooling air in a different direction, or an electric generator (not shown) is coupled to the rotating shaft 310 to rotate the rotating shaft 310 . A structure capable of generating electricity through the electricity generating device may be further added.

In addition, the external air in the intake air distribution space 103 may be guided to the air injection passage 211 by the discharge pressure of the cooling air discharged through the rotation of the impeller 300 to be introduced into the impeller 300 .

In addition, a cover plate 400 supporting the rotation shaft 310 of the impeller 300 is coupled to a lower portion of the casing 100 .

In addition, the following structure is included in order to induce the external air introduced into the intake distribution space 103 of the casing 100 to be rapidly sucked into the air injection passage 211 of the intake 200 .

As shown in FIGS. 4, 5 and 6 (a), the intake holes 501 are mounted on the injection unit 210 of the intake 200 and correspond to the number and shape of the air injection passages 211. ) is formed, the intake hole 501 and the air injection passage 211 are installed adjacent to each other to communicate with each other, and a pair of inclined induction tabs 510 are formed on both sides of the intake hole 501 formed on the outer circumferential surface in a mutually symmetrical form. It provides a cooling turbine device for a refrigerant-free cooling device including a protruding cylindrical suction induction plate (500).

The suction induction plate 500 has an intake hole 501 formed at a position corresponding to the air injection passage 211 while wrapping the outer peripheral surface of the injection portion 210 of the intake 200 in a close contact, and at this time, the intake hole 501 ) has the same shape as the inlet shape of the air jet passage 211 .

A pair of inclined induction tabs 510 are formed to be spaced apart from each other on both sides of the intake hole 501 formed on the outer circumferential surface of the suction induction plate 500, and are formed in a mutually symmetrical form with respect to the intake hole 501, At this time, the inclination induction tab 510 is formed in a shape in which the width between the inclination induction tabs 510 on both sides facing each other is gradually reduced based on the intake hole 501 according to the direction of air flow. It is quickly sucked in through the intake hole 501 by inducing rapid collection and entry between the inclined induction tabs 510 to flow in an accelerated state to the air injection passage 211 .

And, as shown in (b) of FIG. 6, a pair of horizontal tabs 520 are protruded between the intake holes 501 and the intake holes 501 of the suction induction plate 500, and the horizontal tabs ( Provided is a cooling turbine device for a refrigerant-free air conditioner in which the width between the 520 and the horizontal tab 520 corresponds to the vertical width of the intake hole 501 .

The outside air has a direction of air flow in a spiral direction due to the spiral shape of the intake air distribution space 103. At this time, when the outside air flows into the intake hole 501 of the suction induction plate 500, the intake hole 501 ), the airflow may change as the outside air collides with the surrounding area, and a pair of horizontal tabs 520 protrude between the intake hole 501 and the intake hole 501 to induce the flow of air. The width between the 520 and the horizontal tab 520 is formed to correspond to the vertical width of the intake hole 501 , which induces the flow of air by the horizontal tab 520 to maximize entry into the intake hole 501 . will induce

And, as shown in (a) of FIG. 7 , a refrigerant-free cooling device in which a columnar tab 530 protruding in the circumferential direction of the suction induction plate 500 is formed at both ends of the outer peripheral surface of the suction induction plate 500 , respectively. It provides a cooling turbine device for

Circular tabs 530 each protruding from both ends of the outer circumferential surface of the suction induction plate 500 to induce suction into the intake holes 501 without reducing the flow rate of external air along the outer peripheral surface of the suction induction plate 500 . ) is formed.

And, as shown in (b) of Figure 7, the intake hole 501 formed on the outer peripheral surface of the suction induction plate 500, the entire inner peripheral end of the protruding guide guide 540 is formed, the guide 540 To provide a cooling turbine device for a refrigerant-free cooling device in which the upper end of the inclined is formed.

The guide guide 540 protrudes upward from the inner periphery of the intake hole 501 and has an open top while communicating with the intake hole 501. In this case, the intake air distribution space 103 of the casing 100 . The upper end of the induction guide 540 formed at a position adjacent to the inner circumferential surface of to prevent laminar flow or turbulence when air enters, that is, the guide guide 540 corresponding to the air entry direction of the intake hole 501 connects the ends of the side pieces 540-1 and the side pieces 540-1 on both sides. It is composed of a longitudinal piece 540-2 on one side, and in this case, the horizontal piece 540-1 has a shape structure formed in an inclined shape that increases in height toward the longitudinal piece 540-2.

Accordingly, the air is easily introduced into the intake hole 501 , and is rapidly induced to be introduced into the air injection passage 211 in an accelerated form.

And, as shown in FIG. 8, it is coupled between the air injection passage 211 of the injection unit 210 of the intake 200 and the intake hole 501 of the suction induction plate 500, and An air induction unit 600 having a thin plate-shaped support plate 610 having a width corresponding to the vertical width and formed in a horizontal length, and a guide hole 611 formed to correspond to the intake hole 501 in the center of the support plate 610. is installed,

The inclined pieces 621 protruding and extending obliquely on both ends of the guide hole 611 of the support plate 610 facing the air injection passage 211 and the guide hole 611 protrude from the front end of the guide hole 611, so that both ends are inclined on both sides. A first direction guide portion 620a composed of a protruding piece 622 connected to one end of the piece 621 is formed,

Provided is a cooling turbine device for a refrigerant-free air conditioner in which a first direction guide portion 620a and a symmetrical second direction guide portion 620b are formed in the guide hole 611 of the support plate 610 facing the intake hole 501. do.

The air induction unit 600 uniformly enters the air into the air injection passage 211 of the intake 200 while inducing the air flow to the intake hole 501 of the intake induction plate 500, and at the same time controls the directionality. will do

The air induction unit 600 is in the form of a thin plate, that is, as a curved surface having a shape corresponding to the inner circumferential surface of the suction induction plate 500 and the outer circumferential surface of the injection unit 210, a guide of a shape corresponding to the intake hole 501 in the center. A support plate 610 having a ball 611 formed thereon, an inclined piece 621 protruding obliquely from both ends of the guide hole 611 of the support plate 610, respectively, and a guide hole 611 facing the air injection passage 211 ( 611) has a structure in which a first direction guide portion 620a and a symmetrical second direction guide portion 620b are formed.

In detail, the inclined piece 621 is connected obliquely from the center of each of both ends of the intake hole 501 to the front end corner angle, and the protruding piece 622 protrudes upward from the front end of the intake hole 501 to both ends. It is connected with the end of this inclined piece 621.

The first direction guiding part 620a is positioned to be inserted into the air injection passage 211, and the second direction guiding part 620b protrudes to the outside of the intake hole 6501 of the suction induction plate 500. have a form

The second direction guide portion 620b has the same shape as the inclined piece and the protruding piece constituting the first direction guide portion, and is only formed in a symmetrical shape with the first direction guide portion, that is, the inclined piece 621 has the intake hole 501 ) is connected obliquely from the center of each of both ends to the corner angle of the rear end, and the protruding piece 622 protrudes upward from the rear end of the intake hole 501 so that both ends are connected to the end of the inclined piece 621. A second direction induction part (620b).

The second direction guiding part 620b induces the inflow of air into the intake hole 501 into the air injection passage 211, and the first direction guiding part 620a is intake by the first direction guiding part 620a. The air introduced into the ball 501 is guided in the direction of entry to the second direction induction part 620b inclined inside the inlet of the air injection passage 211 and minimizes frictional resistance, so that it naturally flows into the inner curved passage of the air injection passage 211. In addition to inducing the flow, it can be accelerated to a speed greater than a linear laminar flow.

And, a concave engraved groove (not shown) corresponding to the shape of the support plate 610 is formed on the inner surface of the suction induction plate 500 facing the upper surface of the air induction unit 600, so that the suction induction plate 500 is When the air induction part 600 is mounted while being coupled to the injection part 210 of the intake 200, the outer peripheral surface of the injection part 210 and the inner peripheral surface of the suction induction plate 500 are closely coupled.

In addition, although not shown in the drawing, the air induction part 600 is not installed, and the same first and two-way guide parts 620a and 620b formed in the air induction part 6000 are the intake holes ( 501), that is, the first direction guide portion 620a is formed in the intake hole 501 inside the suction induction plate 500 facing the air injection passage 211, and the intake induction plate 500 outside the intake hole ( 501), the second direction guide portion 620b is formed, that is, the first direction guide portion 620a is formed on the inner surface facing the air injection passage 211 based on the intake hole 501 of the suction guide plate 500. A second direction induction part 620b is positioned on the outer surface of the intake hole 501 of the suction induction plate 500 on which the first direction guide part 620a is formed.

And, the first and two-way induction parts 620a and 620b of the above-described air induction part 600 or the first and two-way guide parts 620a and 620b of the suction induction plate 500 are inclined at the top of which an inclined surface is formed. As the piece 621 is formed, the protruding piece 622 is also formed to be inclined in the inward direction of the intake hole 501 so that air is quickly introduced into the intake hole 501 when the air enters.

And, as shown in FIG. 9, the directional rib 551 and the directional rib 551 are respectively formed at the corners of the intake hole 501 of the suction induction plate 500, and have a "B"-shaped cross-section having the same width. A direction guide portion 550 composed of a direction piece 552 extending diagonally from the inner edge of the The lower portion of the direction guide portion 550 of 501 extends downward to a predetermined length,

The upper portion of the direction guide portion 550 of the intake hole 501 located outside the intake guide plate 500 corresponding to the direction of the outside air moving in the intake distribution space 103 of the casing 100 protrudes upward by a predetermined length. If the extending, upwardly protruding direction guide part 550 is located at the rear side of the intake hole 501 , the upper end of the direction guide part 550 located on the front side of the intake hole 501 has a structure located inside the intake hole 501 . A cooling turbine device for a refrigerant-free cooling device is provided.

The direction guide parts 550 respectively formed at the corners of the intake holes 501 of the intake guide plate 500 induce the external air moving through the intake distribution space 103 of the casing 100 while amplifying and accelerating a large amount of the air. Air moves to the intake hole 501 .

The direction guide portion 550 includes a direction rib 551 having a “L”-shaped cross section corresponding to the corner corner of the intake hole 501 and a direction piece 552 extending diagonally from the inner corner of the direction rib 551 . and the lower portion of the direction guide portion 5500 of the intake hole 501 located inside the intake guide plate 500 protrudes downward to a predetermined length so as to be introduced into the air injection passage 211 of the injection portion 210 and extends downward.

And, a direction inducing part 550 formed in a corner adjacent to the rear side of the intake hole 501 to accelerate by pushing air into the intake hole 501 against the direction of the air moving in the intake distribution space 103 of the casing 100 . ) extends upward to a predetermined length, and on the contrary, the upper end of the direction guide part 550 formed at the adjacent corner of the front side of the intake hole 501 is located inside the intake hole 501 to minimize friction with air.

And, as shown in FIG. 10, it is mounted on the inlet 101 of the casing 100, and an inlet 701 on one side and an outlet 702 on the other side are formed to communicate the inlet 701 and the outlet 702. A conduit 703 is formed, and the conduit 703 has a shape that gradually increases in diameter toward the outlet 702, and a plurality of through holes 704 are formed at equal intervals on the peripheral peripheral surface of the inlet 701 at equal intervals. , and the end is connected to the acceleration path 704-1 and the acceleration path 704-1 extending diagonally through the through hole 704 and extending symmetrically with the direction of the acceleration path 704-1. The air inlet 700 is further included in which a reduced pressure passage 704-2 passing through the inner circumferential surface of the pipeline 703 to communicate with the pipeline 703 is formed, and the air inlet 700 is the inlet of the casing 100 ( When external air is introduced into 101), the acceleration of the air is lowered so that it moves naturally to the intake air distribution space 103 of the casing 100 while reducing the air pressure flowing backward when pressurized in the intake air distribution space 103.

The inlet 701 of the air inlet 700 has a shape in which the inner diameter is gradually reduced, and a pipe 703 connecting the inlet 701 and the outlet 702 in the inner center of the air inlet 700 ) is formed, but has a shape in which the diameter gradually decreases toward the outlet 702.

In addition, a plurality of vents 704 are formed in a circumferential shape so that external air is introduced through the inner peripheral surface of the inlet 701 through the inner peripheral surface of the conduit 703, and the vent 704 is an acceleration path As an air movement path divided into a 704-1 and a decompression path 704-2 and interconnected, if the acceleration path 704-1 is formed in an oblique direction, the decompression path 704-2 is an acceleration path 704- 1) It is formed in a direction symmetrical to the diagonal direction, and at this time, the inner diameter of the decompression path 704-2 has a larger inner diameter than that of the acceleration path 704-1 and is moved through the acceleration path 704-1. When the air reaches the decompression path 704 - 2 , the pressure of the moved air is reduced and flows into the conduit 703 .

The above description is merely illustrative of the technical idea of the present embodiment, and those skilled in the art to which this embodiment pertains may make various modifications and variations without departing from the essential characteristics of the present embodiment. Accordingly, the present embodiments are for explanation rather than limiting the technical spirit of the present embodiment, and the scope of the technical spirit of the present embodiment is not limited by these embodiments. The protection scope of this embodiment should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present embodiment.

Casing 100 Inlet 101 Outlet 102
Intake distribution space 103 Intake 200 Hollow part 201
Guide hole 202 Injection part 210 Air injection passage 211
Mounting part 220 Impeller 300 Suction induction plate 500
Intake hole 501 Inclined induction tap 510 Horizontal tap 520
Circumferential tap 530 Guide guide 540 Direction guide part 550
Directional rib 551 Directional side 552 Air induction part 600
Support plate 610 First direction guide part 620a Second direction guide part 620b
Inclined piece 621 Projected piece 622 Air inlet 700

Claims (7)

While forming the hollow part 201, the upper guide hole 202 communicating with the hollow part 201 is formed, and a plurality of air injection passages 211 for communicating the inner and outer peripheral surfaces are provided in the lower injection part 210. The formed intake 200 and the intake 200 are fixed to the inside, and the intake distribution space 103 is formed while the intake distribution space 103 is formed between the outer and inner surfaces of the injection unit 210 of the intake 200. A suction port 101 that communicates with and introduces external air is formed on one surface of the outside, and is connected to the guide hole 202 of the intake 200 while being separated from the intake air distribution space 103. An outlet 102 for discharging cooling air. The casing 100 formed on the upper portion and the hollow portion 201 of the intake 200 are rotatably provided to rotate by the air injected through the air injection passage 211 and cool the injected air in the axial direction. In the cooling turbine device comprising an impeller (300) for guiding to be discharged to the outlet (102) of the casing (100) through the guide hole (202) of the intake (200),
The air jet passage 211 has a shape in which the inner cross-sectional area is gradually narrowed toward the hollow part 201 while being radially formed in a curved shape,
It is mounted on the inlet 101 of the casing 100, and an inlet 701 on one side and an outlet 702 on the other side are formed, and a conduit 703 communicating the inlet 701 and the outlet 702 is formed,
The conduit 703 has a shape that gradually increases in diameter toward the outlet 702,
A plurality of through holes 704 are formed in a cylindrical shape at equal intervals on the peripheral peripheral surface of the inlet 701,
An acceleration path 704-1 extending obliquely through the hole 704 and a pipe 703 connected to the acceleration path 704-1 and extending symmetrically with the direction of the acceleration path 704-1 A cooling turbine device for a refrigerant-free air conditioner, characterized in that it further includes an air inlet (700) having a reduced pressure passage (704-2) passing through the inner circumferential surface of the pipeline (703) to communicate with the air inlet (700). According to claim 1,
It is mounted on the injection part 210 of the intake 200 and the intake holes 501 corresponding to the number and shape of the air injection passages 211 are formed while the intake holes 501 and the air injection passages 211 are formed. are installed adjacent to each other to communicate with each other, and a cylindrical suction induction plate 500 in which a pair of inclined induction tabs 510 protrude in a mutually symmetrical form on both sides of the intake hole 501 formed on the outer circumferential surface is included. Cooling turbine system for refrigerant-free air conditioning system. 3. The method of claim 2,
A pair of horizontal tabs 520 protrude between the intake hole 501 and the intake hole 501 of the suction induction plate 500, and the width between the horizontal tab 520 and the horizontal tab 520 is A cooling turbine device for a refrigerant-free air conditioner, characterized in that it is formed to correspond to the vertical width of the intake hole (501). 3. The method of claim 2,
An induction guide 540 in which the entire inner peripheral end of the intake hole 501 formed on the outer peripheral surface of the suction induction plate 500 protrudes and extends is formed,
A cooling turbine device for a refrigerant-free cooling device, characterized in that the upper end of the induction guide (540) is formed to be inclined. 3. The method of claim 2,
The intake 200 is coupled between the air injection passage 211 of the injection unit 210 and the intake hole 501 of the suction induction plate 500, and has a width corresponding to the vertical width of the intake induction plate 500 An air induction unit 600 having a thin plate-shaped support plate 610 and a guide hole 611 formed to correspond to the intake hole 501 in the center of the support plate 610 are installed.
The inclined pieces 621 protruding and extending obliquely on both ends of the guide hole 611 of the support plate 610 facing the air injection passage 211 and the guide hole 611 protrude from the front end of the guide hole 611, so that both ends are inclined on both sides. A first direction guide portion 620a composed of a protruding piece 622 connected to one end of the piece 621 is formed,
Cooling for a refrigerant-free air conditioner, characterized in that a first direction guide portion 620a and a symmetrical second direction guide portion 620b are formed in the guide hole 611 of the support plate 610 facing the intake hole 501 turbine device. 3. The method of claim 2,
The directional rib 551 and the directional rib 551 are formed at the corners of the intake holes 501 of the suction induction plate 500 and have the same width and are diagonally extended from the inner corners of the ribs 551. A direction guide part 550 composed of a direction piece 552 is formed, and the direction guide part 550 of the intake hole 501 located inside the suction guide plate 500 so as to be introduced into the air injection passage 211 of the intake 200 . ) the lower part extends downward to a predetermined length,
The upper portion of the direction guide portion 550 of the intake hole 501 located outside the intake guide plate 500 protrudes upward to a predetermined length, and the direction guide portion 550 protrudes upward is located at the rear side of the intake hole 501 . If so, the upper end of the direction inducing part 550 located on the front side of the intake hole 501 has a structure located inside the intake hole 501. delete

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