KR20210011650A - Cool air and hot air dispenser - Google Patents

Abstract

The present invention provides a cooling and heating device. A configuration of the present invention comprises: a body (20) having an outlet hole (22), a cold air supply hole (24), and a hot air supply hole (26) therein; a cover (30) coupled to the body (20) and having a connection hole (38) therein; a vortex tube (40) stored inside the cover (30); a tube (50) stored inside the cover (30); and a spool (60) coupled to the body (20) to selectively open and close the cold air supply hole (24) and the hot air supply hole (26).

Description

Cool air and hot air dispenser}

The present invention relates to a cooler, and more particularly, to a cooler of a new configuration capable of selectively supplying hot air or cold air to an air jacket worn during work.

In shipyards, heavy industries, steel structure manufacturers, painting companies, and painting companies, workers often wear air jackets. The air jacket used in the workshop has a hose inside, and the hose inside the air jacket is connected to a compressed air supply device (cold air supply device) such as a compressor, so that the cold air supplied from the compressed air supply device is air jacketed. It is configured to be sprayed with the hose inside. In hot summer, cold air is supplied from the compressed air supply to the hose inside the air jacket to protect the operator from high temperatures. On the other hand, in winter when the temperature is low, the hot air supply device is connected to the hose inside the air jacket to protect the worker from the low temperature and improve work efficiency, supplying hot air to the hose inside the air jacket to keep warm by the air jacket. To be.

However, in the past, to supply cold cold air to the air jacket, the hose inside the air jacket must be connected to the cold air supply device, and to supply hot air to the air jacket, the hose inside the air jacket must be replaced and connected to the hot air supply device. There is a drawback, and since a cold air supply device and a hot air supply device are required separately, it is not preferable in terms of cost.

Korean Patent Registration No. 10-1575580 (registered on December 2, 2015) Korean Patent Registration No. 10-1200089 (registered on November 5, 2012)

It is an object of the present invention to provide hot air to the air jacket through a simple structure so as to eliminate the hassle of connecting by replacing the cold air supply device and the hot air supply device in order to select and supply hot air or cold air to the air jacket worn during work. Or, it is intended to provide a cooler of a new configuration capable of selectively supplying cold air.

According to the present invention for solving the above problems, the body having an outlet hole, a cold air supply hole, and a hot air supply hole therein; A cover coupled to the body and having a communication path therein; A vortex tube built into the cover; A tube built into the cover; A cooling and heating machine comprising: a spool coupled to the body and selectively opening and closing the cold air supply hole and the hot air supply hole.

The vortex tube is built to be disposed in a longitudinal direction between both ends of the cover, the tube is built in the cover so as to be disposed in a direction parallel to the vortex tube, and the communication hole inside the cover is provided with the vortex tube and It characterized in that it is connected to one end of the tube.

Inside the cover, a vortex tube receiving groove and a tube receiving groove extending in the longitudinal direction between the base end and the front end are provided in the cover, and the vortex tube is accommodated in the vortex tube receiving groove, and the tube receiving groove The tube is accommodated, and the vortex tube is configured to communicate with the inside of the tube through the communication hole.

One end of the cover is connected to a base end of the body, and the vortex tube and the inside of the tube are respectively connected to the cold air supply hole and the hot air supply hole formed in the body.

The body is provided with an outlet hole communicating with the cold air supply hole and the hot air supply hole, and the cold air supply hole and the hot air supply hole are configured to selectively communicate with the outlet hole by a spool built in the body. To do.

The spool is coupled to the body so as to be elevated and lowered, and the cold air supply hole and the hot air supply hole are respectively selectively communicated with the outlet hole in a push mode pressing the spool and a pulling mode pulling the spool. To do.

The body is provided with a compressed air inlet hole, and a nozzle is provided inside the body to be disposed between the compressed air inlet hole and one end of the vortex tube, and the compressed air entering through the compressed air inlet hole is It is characterized in that it is configured to generate a vortex inside the vortex tube while passing through.

Heat is generated toward the inner circumferential surface of the vortex tube by the vortex generated inside the vortex tube by the nozzle, and cool air is generated toward the center of the vortex tube.

The cold air generated from the central side of the vortex tube advances to the cold air supply hole inside the body to which one end of the vortex tube is connected, and the heat generated from the inner circumferential surface of the vortex tube passes through the communication hole inside the body and is a tube built into the body. Is introduced into the interior of the body, and the heat is configured to advance to the heat supply hole inside the body.

The cold air supply hole and the hot air supply hole inside the body are selectively opened and closed by a spool built in the body, and when the cold air supply hole is opened by the spool, cold air flows into the outlet hole formed in the body. And, when the heat supply hole is opened by the spool, heat is introduced into an outlet hole formed in the body.

According to the present invention, a body having an outlet hole, a cold air supply hole, and a hot air supply hole therein; A cover coupled to the body and having a communication path therein; A vortex tube built into the cover; A tube built into the cover; A spool coupled to the body to selectively open and close the cold air supply hole and the hot air supply hole, wherein the vortex tube is built-in so as to be disposed in a longitudinal direction between both ends of the cover, and the tube is the vortex tube It is built in the inside of the cover so as to be arranged in a direction parallel to the cover, the communication hole inside the cover is connected to the vortex tube and one end of the tube, the cover is provided with a through hole, and the inside of the cover There is provided a cooling and heating machine, characterized in that the shield member to prevent the combined.

The cover has a plurality of through holes, the through holes communicate with both sides of the cover, and the shield member has a cross-sectional channel shape, so that the shield member blocks the plurality of through holes formed on both sides of the cover. It is characterized.

The shield member is characterized in that the heat generated in the vortex tube blocks heat from being discharged from the inside of the vortex tube to the outside from the vortex tube from being discharged into the through hole to enable the use of heat.

The cooling and heating machine according to the present invention does not need to connect the hose inside the air jacket to the cold air supply device in order to supply cold cold air to the air jacket, etc., and replace the air jacket in the hot air supply device to supply hot air to the air jacket. There is no case to be connected, and a cold air supply device and a hot air supply device are not separately required, which is preferable in terms of cost.

1 and 2 are exploded perspective views of a cooling and heating machine according to the present invention
3 is a perspective view showing a base end side of the body shown in FIGS. 1 and 2
4 is a front view of the body shown in FIGS. 1 and 2
Figure 5 is a rear view of Figure 4
6 is a view showing the front end side of FIG. 4
7 is a view showing the base end side of FIG. 7
8 is a plan view of FIG. 4
9 and 10 are perspective views of a spool that is a main part of the present invention
11 is a perspective view of a vortex nozzle incorporated in the body shown in FIG. 4
12 is a view showing the base end side of FIG. 11
13 is a side view of an outlet plug coupled to the body of FIG. 4
14 is a side view of FIG. 13
15 is a perspective view showing a mode of use of cold air of a cooling and heating apparatus according to the present invention
16 is a front cross-sectional view of FIG. 15
FIG. 17 is a partially enlarged front view showing an operation of a spool in a cold air use mode of the cooler and hotter shown in FIG. 15
FIG. 18 is a rear view showing partially enlarged operation of the spool in the cold air use mode of the cooling and heating machine shown in FIG. 15
19 is a perspective view showing a mode of use of a hot air conditioner according to the present invention
20 is a front cross-sectional view of FIG. 19
FIG. 21 is a partially enlarged front view showing the operation of the spool in the hot air mode of the cooling and heating machine shown in FIG. 19
FIG. 22 is a rear view showing an enlarged part of the operation of the spool in the cold air use mode of the cooling and heating machine shown in FIG. 19
23 is a diagram schematically showing a coupling structure between a swivel plug and a body in a cooler according to the present invention
24 is a perspective view showing an exploded shield member of a cooling/heating machine according to another embodiment of the present invention
25 is a perspective view showing a state in which the shield member shown in FIG. 24 is coupled
26 is a perspective view showing the bottom of the body of the cooler according to another embodiment of the present invention
Figure 27 is a front cross-sectional view of Figure 26
FIG. 28 is a front cross-sectional view showing a hot air use mode of the cooling and heating apparatus employing the body shown in FIG. 23
FIG. 29 is a front cross-sectional view showing a cold air use mode of the cooling and hot air conditioner employing the body shown in FIG. 23

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Objects, features, and advantages of the present invention will be more easily understood by referring to the accompanying drawings and the following detailed description. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In addition, in describing the constituent elements of the present invention, terms such as first, second, A, B, (a), (b) may be used. These terms are only used to distinguish the component from other components, and the nature, order, or order of the component is not limited by the term. For example, if a component is described as being "connected", "coupled" or "connected" to another component, the component may be directly connected or connected to that other component, but between each component It should be understood that another component may be “connected”, “coupled” or “connected”.

Referring to the drawings, the cooler according to the present invention includes a body 20, a cover 30 coupled to the body 20, and a vortex tube 40 and a tube 50 embedded in the cover 30. And, a spool 60 for selectively opening and closing the cold air supply hole 24 and the hot air supply hole 26 inside the body 20 is provided.

The body 20 is formed in a block shape having an outlet hole 22, a cold air supply hole 24, and a hot air supply hole 26 therein. The body 20 is configured in a hexahedral block shape. A spool operation hole 28 is provided inside the body 20. The spool operation hole 28 communicates with the upper end and the lower end of the body 20 inside the body 20. The spool operation hole 28 is made of a circular hole. That is, the spool operation hole 28 is made of a circular hole extending a predetermined length in the vertical direction of the body 20 when viewed from the front of the body 20.

A vortex nozzle insertion hole 23 is provided inside the body 20. The vortex nozzle insertion hole 23 extends a predetermined depth from the base end of the body 20 to the inside of the body 20. The vortex nozzle insertion hole 23 has a circular hole shape.

The cold air supply hole 24 communicates with the spool operation hole 28. A cold air supply hole 24 is communicated from an inner end of the vortex nozzle insertion hole 23 formed to a predetermined depth from one end of the body 20 toward the spool operation hole 28. The cold air supply hole 24 is configured in a long hole shape. The cold air supply hole 24 is formed in a long hole shape extending a predetermined length in the front and rear directions of the body 20. Accordingly, the inner end of the cold air supply hole 24 is configured in a long hole shape horizontally extending along the circumferential direction of the spool operation hole 28.

The body 20 is provided with a swivel plug boss 21. The swivel plug boss 21 protrudes from the front of the body 20 for a predetermined length. The inner end of the swivel plug boss 21 is connected to the front surface of the body 20. The swivel plug boss 21 is configured in a cross-sectional circular boss shape.

The swivel plug boss 21 is provided with a pinhole 21H. The pinhole 21H is formed to communicate in a direction orthogonal to the longitudinal direction, which is a path between the inner end and the outer end of the swivel plug boss 21. The pinhole 21H is composed of an upper pinhole 21H and a lower pinhole 21H. When viewed from the front of the body 20, upper and lower pinholes 21H and 21H are provided on the upper and lower portions of the swivel plug boss 21. The upper pinhole 21H and the lower pinhole 21H are configured to communicate from one peripheral portion of the swivel plug boss 21 to the other peripheral portion. An upper pinhole 21H and a lower pinhole 21H are provided at each of the left and right sides of the swivel plug boss 21 as a reference. The upper pinhole 21H and the lower pinhole 21H communicate from the outer peripheral surface of the swivel plug boss 21 to the inner peripheral surface. That is, the upper pinhole 21H and the lower pinhole 21H communicated from two outer peripheral surfaces of the swivel plug boss 21 to the inner peripheral surface are provided in the swivel plug boss 21.

The swivel plug 25 is coupled to the swivel plug boss 21. The swivel plug 25 is provided with a circular plug, and the swivel plug is inserted into the swivel plug boss 21 in the shape of a cross-sectional circular tube, and thus the swivel plug ( 25) is connected. At this time, a pin coupling groove (25PG) is provided on the outer circumferential surface of the circular plug part, and the upper pin (PU) and the lower pin (PL) are coupled to the upper pinhole (21H) and the lower pinhole (21H) of the swivel plug boss (21). ) Is inserted into the pin coupling groove 25PG of the circular plug, so that the swivel plug 25 rotatably contacts the swivel plug boss 21 provided in the body 20 and at the same time, the swivel plug boss 21 ), the swivel plug 25 is prevented from coming off. The upper pin (PU) and the lower pin (PL) are inserted into the pin coupling groove (25PG) provided in the circular plug portion of the swivel plug 25, so that the circular plug portion is separated from the swivel plug boss (21) of the body (20). Since the swivel plug 25 is prevented from being separated from the swivel plug boss 21 of the body 20, the swivel plug 25 can rotate with respect to the swivel plug boss 21 at the same time. .

A compressed air inlet hole 27 is provided inside the body 20. The compressed air inlet hole 27 communicates with the inside of the swivel plug boss 21 and the vortex nozzle insertion hole 23. The compressed air inlet hole 27 is disposed between the vortex nozzle insertion hole 23 and the cold air supply hole 24. An inner end of the compressed air inlet hole 27 is disposed between the outer end of the cold air supply hole 24 and the outer end of the vortex nozzle insertion hole 23.

A compressed air supply device such as a compressor is connected to the swivel plug 25, and compressed air through the swivel plug 25 passes through the compressed air inlet hole 27 inside the body 20, and the vortex nozzle insertion hole It is structured to be able to flow into (23).

The vortex nozzle 42 is coupled to the vortex nozzle insertion hole 23 inside the body 20. The vortex nozzle 42 includes a center hole 42CH and a plurality of vortex guide holes 42PH disposed around the center hole 42CH. The vortex guide hole 42PH communicates from the outer peripheral surface of the vortex nozzle 42 toward the center hole 42CH. At this time, the vortex guide hole 42PH is formed to be inclined at an angle from the outer peripheral surface of the vortex nozzle 42 toward the center hole 42CH. The outer inlet end and the inner inlet end of the vortex guide hole 42PH are not disposed on the same line toward the center of the center hole 42CH, but the inner inlet end is located at a position away from the outer inlet end toward the center of the center hole 42CH. By being disposed, the vortex guide hole 42PH is formed to be inclined at a predetermined angle from the outer peripheral surface of the vortex nozzle 42 toward the center hole 42CH. The vortex guide hole 42PH communicates with the compressed air inlet hole 27 inside the body 20. When compressed air enters the compressed air inlet hole 27 inside the body 20, the compressed air passes through the vortex guide hole 42PH inclined at a certain angle toward the center hole 42CH of the vortex nozzle 42. An air vortex is generated inside the vortex tube 40 disposed on the same line as the center hole 42CH of the vortex nozzle 42.

The hot air supply hole 26 is provided inside the body 20 so as to be disposed at a position out of the cold air supply hole 24. The hot air supply hole 26 communicates with the spool operation hole 28. The cold air supply hole 24 communicates from one end of the body 20 toward the spool operation hole 28. The hot air supply hole 26 is configured in a long hole shape. The heat supply hole 26 is configured in a long hole shape extending a predetermined length in the front and rear directions of the body 20. Accordingly, the inner end of the hot air supply hole 26 is configured in a long hole shape horizontally extending in the circumferential direction of the spool operation hole 28. When viewed from the front of the body 20, the cold air supply hole 24 is disposed above and the hot air supply hole 26 is disposed below. The cold air supply hole 24 is disposed at a position close to the upper end of the body 20 and the hot air supply hole 26 is disposed at a position close to the lower end of the body 20.

The body 20 includes an outlet plug boss 29 at a tip portion opposite to an end portion in which the cold air supply hole 24 and the hot air supply hole 26 are formed. When the end of the body 20 to which the cover 30 is connected is referred to as the base end, the outlet plug boss 29 protrudes from the body 20 to a tip end opposite to the base end. The inner end of the outlet plug boss 29 is connected to the distal end of the body 20 so that the outlet plug boss 29 protrudes from the distal end of the body 20. In addition, a pinhole 21H is provided in the outlet plug boss 29. The pinhole 21H is provided in a direction orthogonal to a longitudinal direction that is a path between an inner end and an outer end of the outlet plug boss 29. The pinhole 21H is configured to communicate from one outer peripheral surface of the outlet plug boss 29 to the other outer peripheral surface.

The body 20 is provided with a silencer boss 20SB. The silencer boss 20SB protrudes from the front or rear surface of the body 20. In the present invention, the silencer boss 20SB protrudes from the front surface of the body 20. The silencer boss 20SB is composed of a cold air silencer boss 20SB and an open silencer boss 20SB. When viewed from the front of the body 20, the cold air silencer boss 20SB is disposed above and the open silencer boss 20SB is disposed below.

The body 20 is provided with a cold air drain hole 20CH and a hot air drain hole 20HH. The cold air drain hole 20CH is communicated from the spool operation hole 28 of the body 20 to the inside of the cold air silencer boss 20SB. At this time, the cold air drain hole 20CH has a long hole shape. When viewed from the front of the body 20, the cold air drain hole 20CH is formed in a long hole shape extending laterally. Accordingly, the cold air drain hole 20CH is formed in a long hole shape extending a predetermined length in the circumferential direction of the spool operation hole 28. Meanwhile, a silencer SM is provided inside the cold air silencer boss 20SB. In addition, a silencer filter SF covering the silencer SM is coupled to the cold air silencer boss 20SB.

The open drain hole 20HH is communicated from the spool operation hole 28 of the body 20 to the inside of the open silencer boss 20SB. When viewed from the front of the body 20, the cold air drain hole 20CH is disposed at the top, and the hot drain hole 20HH is disposed at the bottom. At this time, the open drain hole 20HH has a long hole shape. When viewed from the front of the body 20, the opening drain hole 20HH is formed in a long hole shape that extends sideways. Accordingly, the open drain hole 20HH is formed in a long hole shape extending a predetermined length in the circumferential direction of the spool operation hole 28. Meanwhile, a silencer SM is provided inside the open side silencer boss 20SB. In addition, a silencer filter SF covering the silencer SM is coupled to the open side silencer boss 20SB.

The body 20 is provided with a stop pin hole (20SPH). The stop pin hole 20SPH communicates with the upper end of the body 20 from the inside of the body 20. The stop pin hole (20SPH) is provided in a position outside the spool operation hole (28). The stop pinhole (20SPH) is configured in a cylindrical long hole shape. When viewed from the top of the body 20, a stop pinhole (20SPH) is provided at an outer position of the spool operation hole (28), and the stop pinhole (20SPH) is configured in a cylindrical long hole shape of a predetermined length.

The body 20 is provided with a nut receiving groove 20NG. A nut receiving groove 20NG is provided at a position adjacent to the base end of the body 20. The nut receiving groove 20NG is provided at a position adjacent to the base end of the body 20. Since the body 20 has a hexahedral block shape, nut receiving grooves 20NG are provided in the front and rear upper and lower positions adjacent to the base end of the body 20. Four nut receiving grooves (20NG) are provided in the body (20). In addition, the body 20 is provided with a bolt insertion hole (20BH) communicated with the nut receiving groove (20NG) at the base end. When viewed from the base end of the body 20, the bolt insertion hole 20BH is provided in the up and down front and rear positions. At this time, the two upper and lower bolt insertion holes 20BH provided at positions adjacent to the rear surface of the body 20 pass through the nut receiving groove 20NG and communicate with the front end of the body 20.

The body 20 is configured to be coupled with a belt hanger 70. The belt hanger 70 includes a main hanger plate portion 72, an engaging hanger plate portion 73 extending in a direction crossing one end portion of the main hanger plate portion 72, and the other end of the main hanger plate portion 72. A connection hanger plate portion 74 extending in an intersecting direction, an inner hanger plate portion 75 extending in a direction facing the main hanger plate portion 72 from the connection hanger plate portion 74, and the inner hanger plate portion 75 It includes a plurality of fixing pieces 76 extending in a direction parallel to the extending direction of the connecting hanger plate portion 74. In this case, a bolt hole meeting the bolt insertion hole 20BH formed in the body 20 is provided in the coupling hook plate part 73. In addition, the fixing hook piece is provided with a bolt hole on the fixing side that meets the bolt insertion hole 20BH communicated toward the base end of the body 20.

The cover 30 is configured in a block shape. The cover 30 is configured in a rectangular block shape in which the length between the upper end and the lower end is smaller than the length between the distal end and the base end. The cover 30 has a vortex tube receiving groove and a tube receiving groove therein. The vortex tube receiving groove and the tube receiving groove extend a predetermined length in the longitudinal direction between the base end and the front end of the cover 30. In the cover 30, a plurality of cover thinner pieces 32 are arranged at regular intervals between the front end and the base end, and the vortex tube 40 insertion holes are in communication with both sides for each of the plurality of cover thinner pieces 32. The vortex tube receiving groove is formed inside the cover 30 by the insertion holes of the vortex tube 40. The insertion hole of the vortex tube 40 is a circular hole, so that the vortex tube receiving groove has a circular groove shape in cross section. The cover 30 is formed with a plurality of through holes 34. A through hole 34 is provided between the plurality of cover thinner pieces 32, and a plurality of through holes 34 are formed in the cover 30 at regular intervals along the length direction. The through hole 34 communicates with both sides of the cover 30. That is, the through hole 34 communicates with the front and rear surfaces of the cover 30. In addition, the tube receiving groove formed inside the cover 30 has a circular groove shape in cross section. The vortex tube receiving groove and the tube receiving groove are arranged parallel to each other. When viewed from the front end surface of the cover 30, the vortex tube receiving groove is disposed above and the tube receiving groove is disposed below.

A communication hole 36 is provided inside the cover 30. A communication hole 36 is provided inside the cover 30 adjacent to the base end. The communication hole 36 extends in the direction of the upper and lower ends of the cover 30, and the upper and lower ends of the communication hole 36 are connected to the vortex tube receiving groove and the tube receiving groove inside the cover 30. The vortex tube receiving groove and the tube receiving groove extend in the longitudinal direction of the cover 30, and the communication hole 36 is connected to the vortex tube receiving groove and the tube receiving groove while extending in the vertical direction of the cover 30. do.

The cover 30 is provided with a flange portion 38 at the front end. The flange portion 38 is provided with a cover-side bolt hole penetrating through both sides. The cover-side bolt hole is provided in plural in the flange portion 38 of the cover 30. A cover-side bolt hole is provided in the upper and lower front and rear positions of the flange portion 38, respectively. The cover-side bolt hole is aligned to meet the bolt hole formed at the base end of the body 20.

The front end of the cover 30 is connected to the base end of the body 20. At this time, the belt hanger 70 is also mounted on the body 20 together with the cover 30. Nuts (NT) are accommodated in each nut receiving groove (20NG) provided in the body (20), and the coupling hanger plate portion (73) of the belt hanger (70) is the base end of the body (20) and the plan of the cover (30). It is interposed between the branches 38 and the fixing piece 76 of the belt hanger 70 is disposed at the front end of the body 20, and the cover-side bolt hole formed in the flange 38 of the cover 30 and Pass the bolt through the bolt hole formed in the coupling hook plate part 73 and the bolt insertion hole 20BH formed in the body 20 and fasten it to the nut NT, and then the two upper and lower bolt insertion holes on the back side of the body 20 ( 20BH), the belt hanger 70 and the cover 30 can be simultaneously coupled to the body 20 by engaging the bolt hole formed on the fixing piece 76 of the belt hanger 70 to the bolt hole on the fixed side. have. The main hanger plate portion 72 of the belt hanger 70 is spaced a certain distance from the rear surface of the body 20, so that the user's trousers are placed in the spaced space between the main hanger plate portion 72 and the rear surface of the body 20. By passing the belt to be worn, the user can wear the body 20 and the cover 30 by the belt hanger 70. The cooling and heating machine of the present invention can be worn by the user in the vicinity of the waist by using the belt hanger 70.

A vortex tube 40 is embedded in the cover 30. The vortex tube 40 is seated in the vortex tube receiving groove formed inside the cover 30, thereby taking a structure in which the vortex tube 40 is embedded in the cover 30. The vortex tube 40 has a circular tube shape. At this time, the base end of the vortex tube 40 is connected to the communication hole 36 inside the cover 30. A vortex tube 40 is connected to an upper side of the communication hole 36. A vortex nozzle 42 embedded in the body 20 is connected to the front end of the vortex tube 40. The front end of the vortex tube 40 is connected to the cold air supply hole 24 provided in the body 20 through the center hole 42CH of the vortex nozzle 42. The inside of the vortex tube 40 communicates with the cold air supply hole 24 of the body 20.

The tube 50 is embedded in the cover 30. The tube 50 is seated in the tube receiving groove formed inside the cover 30, thereby taking a structure in which the tube 50 is embedded in the cover 30. The vortex tube 40 is disposed in the longitudinal direction of the cover 30, the tube 50 is also disposed in the longitudinal direction of the cover 30, and the tube 50 is disposed in parallel with the vortex tube 40. The tube 50 has a circular tube shape. At this time, the base end of the tube 50 is connected to the communication hole 36 inside the cover 30. The tube 50 is connected to a lower side of the communication hole 36. A heat supply hole 26 provided in the body 20 is connected to the distal end of the tube 50. The inside of the tube 50 communicates with the hot air supply hole 26 provided in the body 20. The front end of the tube 50 is inserted into the tube insertion hole 20TH provided at the base end of the body 20, and the heat supply hole 26 inside the body 20 is in communication with the tube insertion hole 20TH, The inside of the tube 50 is in communication with the hot air supply hole 26 provided in the body 20.

A spool 60 for selectively opening and closing the cold air supply hole 24 and the hot air supply hole 26 is coupled to the body 20. The spool 60 includes a spool shaft coupled to the spool operation hole 28 of the body 20, and is provided on the outer circumferential surface of the spool shaft, the outlet hole 22 and the cold air supply hole 24 of the body 20, and It includes an upper end adjustment protrusion piece 62 and a lower end adjustment protrusion piece 63 for selectively communicating the hot air supply hole 26. In addition, the spool 60 includes a pair of upper intermediate protrusion pieces 65 and lower intermediate protrusion pieces 66 on the outer circumferential surface of the spool shaft. The upper end adjustment protrusion piece 62 and the lower end adjustment protrusion piece 63 are arranged on the same line based on the length direction of the spool 60, and the upper intermediate protrusion piece 65 and the lower intermediate protrusion piece 66 are spools ( It is disposed at a position deviated from the upper end adjustment stone piece 62 and the lower end adjustment stone piece 63 by a predetermined angle from the center of 60). The pair of upper intermediate protrusion pieces 65 and lower intermediate protrusion pieces 66 are disposed on the same line based on the longitudinal direction of the spool 60. In addition, the spool 60 includes a pair of upper and lower end packing grooves, and a pair of upper and lower intermediate packing grooves on the outer circumferential surface.

The spool 60 is coupled to the spool operation hole 28 formed inside the body 20 so as to be elevating. The outer circumferential surface of the pair of upper and lower end adjustment protrusion pieces 63 and the pair of upper intermediate protrusion pieces 65 and lower intermediate protrusion pieces 66 provided in the spool 60 is formed as a circumferential surface, and the The spool operation hole 28 has a circular hole shape, so that the circumferential surface of the upper end adjustment piece and the lower end adjustment protrusion piece 63 and a pair of the upper intermediate protrusion piece 65 and the lower intermediate protrusion piece 66 is the spool operation hole ( The spool 60 is configured to rotate in close contact with the hole wall of 28).

The spool 60 includes a pair of upper end packing grooves and lower end packing grooves formed on the outer circumferential surface, and a pair of upper middle packing grooves and lower intermediate packing grooves have an upper end packing (60UEP) and a lower end packing (60LEP) and an upper part. The intermediate packing (60UMP) and the lower intermediate packing (60LMP) are combined, and the upper end packing (60UEP) and the lower end packing (60LEP), the upper intermediate packing (60UMP) and the lower intermediate packing (60LMP) are the body 20 The spool 60 is configured to rotate in the spool operation hole 28 of the body 20 in a state in close contact with the hole wall forming the spool operation hole 28 of the body 20. The upper intermediate packing (60UMP) and the lower intermediate packing (60LMP) to selectively supply cold and hot air to the outlet hole 22 of the body 20 inside the spool operation hole 28 of the body 20 A supply chamber is formed, and a cold air drain chamber is formed in the spool operation hole 28 of the body 20 by the upper end packing 60UEP and the upper intermediate packing 60UMP, and the lower end packing 60LEP And by the lower intermediate packing (60LMP), a hot drain chamber is formed in the spool operation hole 28 of the body 20.

A lever 61 is provided at the upper end of the spool 60. A stop pin 61SP protrudes from the bottom of the lever 61, and the stop pin 61SP is inserted into a stop pin hole 20SPH formed in the body 20. As the spool 60 is rotated in the spool operation hole 28 of the body 20, the stop pin 61SP can move along the circumferential trajectory in the stop pin hole 20SPH of the body 20.

A stopper 67 is provided at the lower end of the spool 60. The stopper 67 is provided with a coupling pin protruding upward in the central portion, and a pin insertion hole communicated to the lower portion is formed in the inside of the spool 60, and the coupling pin is inserted into the pin insertion hole so that the spool 60 The stopper 67 is coupled to the lower end of the body 20, the stopper 67 is disposed outside the lower end of the body 20, the stopper 67 is caught on the circumferential wall of the spool operation hole 28 of the body 20 It is structured to be able to lose. The stopper 67 coupled to the lower end of the spool 60 can be hooked to the lower end of the body 20.

The cooling and heating machine according to the present invention having the above-described configuration is mainly used to supply cold air or hot air to the air jacket, and can be switched between a cold air use mode and a hot air use mode.

<Cold use mode>

In the cold air mode, the spool 60 is raised. The lever 61 provided at the upper end of the spool 60 floats upward from the upper end of the body 20, and the stopper 67 at the lower end of the spool 60 contacts the lower end of the body 20.

In the cold air use mode, the upper end adjustment protrusion 62 provided in the spool 60 is located outside the cold air supply hole 24 provided in the body 20, so that the supply secured in the spool operation hole 28 The cold air supply hole 24 of the body 20 communicates with the chamber.

On the other hand, in the cold air mode, the lower end adjustment protrusion 63 provided in the spool 60 is in a state in which the hot air supply hole 26 provided in the body 20 is blocked, so that the body 20 by the spool 60 ) In the supply chamber secured in the internal spool operation hole 28, the heat supply hole 26 of the body 20 is blocked.

When compressed air enters the compressed air inlet hole 27 of the body 20, compressed air passes through the vortex nozzle 42 and a vortex of compressed air occurs inside the vortex tube 40, and the inside of the vortex tube 40 A vortex of compressed air is generated in the vortex tube 40 so that heat is generated toward the inner circumferential surface of the vortex tube 40 and flows into the tube 50 through the circulation hole inside the body 20, and cold air is passed through the center of the vortex tube 40. It is generated and advances to the cold air supply hole 24 of the body 20 at a predetermined pressure.

Since the cold air supply hole 24 of the body 20 is open, the cold air generated in the vortex tube 40 flows into the supply chamber formed by the spool 60 inside the body 20 and the body 20 When cold air is discharged through the outlet hole 22 of the outlet, and the hose of the air jacket is connected to the supply plug connected to the outlet hole 22, cold air is supplied to the hose inside the air jacket, so the air jacket can be used as a cold air air jacket. I can. At this time, in the cold air use mode, since the lower end adjustment protrusion 63 provided in the spool 60 blocks the heat supply hole 26 of the body 20, the heat supplied to the inside of the tube 50 is It is shut off without being supplied to the supply chamber.

Meanwhile, in the cold air mode, heat generated from the vortex tube 40 and supplied to the tube 50 may be discharged to the outside of the body 20. A part of the hot air supply hole 26 is opened by rotating the spool 60. When the spool (60) is rotated while the stopping pin provided on the lever (61) of the spool (60) is in contact with the first inner end of the stop hole of the body (20), the stopping pin (20) The upper intermediate protrusion piece 65 which is in contact with the second inner end of the stop hole and provided on the outer circumferential surface of the spool 60 at the same time blocks a part of the cold air supply hole 24 inside the body 20 The lower end adjustment protrusion 63 opens the heat supply hole 26 of the body 20. At this time, by the lower intermediate packing (60LMP) and lower end packing (60LEP) provided in the spool (60) in the spool operation hole (28) inside the body (20), a hot air drain chamber isolated from the supply chamber is formed. In the hot air drain hole formed in the body 20, the hot air exiting the partially open hot air supply hole 26 exits the hot air drain chamber formed in the spool operation hole 28 of the body 20 by the spool 60 Passes through (20HH), passes through the silencer (SM), passes through the filter, and can be removed to the outside. After exhausting the heat from the inside of the body 20, the spool 60 is rotated to its original position so that the stop pin 61SP comes into contact with the first inner end of the stop hole of the body 20 again. .

<Open use mode>

In the hot air mode, the spool 60 is in a lowered state. The lever 61 provided at the upper end of the spool 60 is in contact with the upper end of the body 20 and the stopper 67 at the lower end of the spool 60 is spaced downward from the lower end of the body 20.

In the hot air mode, the lower end adjustment protrusion 63 provided in the spool 60 is located outside the hot air supply hole 26 provided in the body 20, and thus the supply secured in the spool operation hole 28 The heat supply hole 26 of the body 20 communicates with the chamber.

On the other hand, in the hot air mode, the upper end adjustment protrusion 62 provided in the spool 60 is in a state in which the cold air supply hole 24 provided in the body 20 is blocked, and the body 20 by the spool 60 ) In the supply chamber secured in the internal spool operation hole 28, the cold air supply hole 24 of the body 20 is blocked.

When compressed air enters the compressed air inlet hole 27 of the body 20, compressed air passes through the vortex nozzle 42 and a vortex of compressed air occurs inside the vortex tube 40, and the inside of the vortex tube 40 A vortex of compressed air is generated in the vortex tube 40 so that heat is generated toward the inner circumferential surface of the vortex tube 40 and flows into the tube 50 through the circulation hole inside the body 20, and cold air is passed through the center of the vortex tube 40. It is generated and advances to the cold air supply hole 24 of the body 20 at a predetermined pressure.

Since the heat supply hole 26 of the body 20 is open, the heat generated in the vortex tube 40 flows into the supply chamber formed by the spool 60 inside the body 20 and the body 20 When heat is discharged through the outlet hole 22 of and the air jacket hose is connected to the supply plug connected to the outlet hole 22, heat is supplied to the hose inside the air jacket, so the air jacket can be used as an insulating air jacket. I can. At this time, in the hot air mode, since the upper end adjustment protrusion 62 provided in the spool 60 blocks the cold air supply hole 24 of the body 20, the cold air supplied to the inside of the tube 50 is It is shut off without being supplied to the supply chamber.

Meanwhile, in the hot air mode, cold air generated from the vortex tube 40 and supplied to the tube 50 may be discharged to the outside of the body 20. A part of the cold air supply hole 24 is opened by rotating the spool 60. When the spool (60) is rotated while the stopping pin provided on the lever (61) of the spool (60) is in contact with the first inner end of the stop hole of the body (20), the stopping pin (20) The lower intermediate protrusion piece 66 which is in contact with the second inner end of the stop hole and provided on the outer circumferential surface of the spool 60 at the same time blocks a part of the heat supply hole 26 inside the body 20 The upper end adjustment protrusion 62 opens the cold air supply hole 24 of the body 20. In this case, a cold air drain chamber isolated from the supply chamber is formed in the spool operation hole 28 inside the body 20 by the upper intermediate packing 60UMP and the upper end packing 60UEP provided in the spool 60. In the cold air drain hole formed in the body 20, the cold air that has escaped through the partially open cold air supply hole 24 exits the cold air drain chamber formed in the spool operation hole 28 of the body 20 by the spool 60 It passes through (20CH), passes through the silencer (SM), passes through the filter, and can be removed to the outside. After exhausting the cold air from the inside of the body 20, the spool 60 is rotated to its original position so that the stop pin 61SP comes into contact with the first inner end of the stop hole of the body 20 again. .

Therefore, the cooling and heating machine according to the present invention does not need to connect the hose inside the air jacket to the cold air supply device in order to supply cold cold air to the air jacket, etc., and to supply the hot air to the air jacket, the air jacket etc. There is no case to be replaced and connected, and since a cold air supply device and a hot air supply device are not separately required, it is preferable in terms of cost.

In addition, the cold air mode and the hot air mode can be easily switched by using the spool 60, which is very convenient in use.

Meanwhile, in the present invention, the supply amount of cold air and the supply amount of hot air can be easily adjusted according to the degree of turning the spool 60. When the spool 60 is rotated, the lower end adjustment protrusion 63 and the upper end adjustment protrusion 62 provided in the spool 60 are provided with the cold air supply hole 24 and the hot air supply hole 26 inside the body 20. The degree of opening and closing can be adjusted.

In addition, in the present invention, a silencer SM is provided in each of the hot drain hole 20HH and the cold drain hole 20CH of the body 20 when discharging hot air in the cold air mode or when discharging cold air in the hot air mode. Noise can be minimized when exhausting cold or hot air.

The swivel plug 25 is rotatably connected to the swivel plug boss 21 of the body 20 by a pair of pins, so that the swivel plug 25 is connected to the position of the hose of the compressed air supply device. The swivel plug 25 may be connected by rotating it, and thus the swivel plug 25 may be connected to the hose of the compressed air supply device without restriction by rotating the position of the swivel plug 25 corresponding to the position of the operator.

In addition, in the present invention, a pair of linear pin coupling holes extending in the longitudinal direction to the supply plug, and a first cross pin coupling hole connected in a direction perpendicular to one of the pair of linear pin coupling holes, and , It is provided in a second cross pin coupling hole connected in a direction perpendicular to the other linear pin coupling hole and extending in a direction opposite to the first cross pin coupling hole.

The supply plug is pushed into the plug boss of the body 20 while aligning the pair of linear pin coupling holes communicated with the end of the supply plug with the support pins coupled to the plug boss of the body 20. Then, the support plate is positioned in the first cross pin coupling hole and the second cross pin coupling hole connected to the inner ends of the pair of linear pin coupling holes, and in this state, the supply plug is rotated in one direction. Then, since the support pin enters and is caught in the pair of the first cross pin coupling hole and the second cross pin coupling hole, the supply plug is prevented from being separated from the state connected to the plug boss of the body 20.

Accordingly, there is a quick and convenient effect when connecting the supply plug to the plug boss of the body 20.

In addition, the supply plug is rotated in the opposite direction from the plug boss of the body 20 while being caught in the first cross pin coupling hole and the second cross pin coupling hole of the supply plug. Then, the support pin coupled to the plug boss of the body 20 is aligned in the pair of linear pin coupling holes, and the state in which the supply plug is caught in the first cross pin coupling hole and the second cross pin coupling hole is released. In the state, the supply plug can be removed by pulling it out from the plug boss of the body 20.

Therefore, when removing the supply plug from the plug boss of the body 20, the supply plug needs to be rotated in a direction not caught in the first cross pin coupling hole and the second cross pin coupling hole. ), it has a quick and convenient effect when removing it from the plug boss.

In addition, an air guider 3 is further provided inside the vortex tube. The air guider 3 has a vertical guide space and a horizontal guide space and is configured in a cross shape when viewed from the front. The air guider 3 is built into the base end side of the vortex tube 40, and the heat generated by the vortex generation in the vortex tube 40 passes through the communication hole 36 inside the body 20 by the vertical guide space. It is guided so as to flow into the tube 50 more smoothly through the passage, and the cold air generated by the vortex generation in the vortex tube 40 is supplied from the central portion of the vortex tube 40 by the horizontal guide space. It is guided to advance more smoothly into the hole 24.

In addition, in the present invention, a shield member 39 covering both sides of the cover 30 is further provided. The shield member 39 is configured such that blocking shield pieces 39BS are provided at both ends of the connecting shield piece 39CS, so that both sides of the cover 30 are removed while the shield member 39 is coupled to the cover 30. A pair of blocking shield pieces 39BS are covered, so that the through holes 34 communicated to both sides of the cover 30 are covered by a pair of blocking shield pieces 39BS of the shield member 39.

Therefore, when the present invention is used in the hot air use mode, the heat is not discharged through the through holes 34 communicated to both sides of the cover 30, and the heat can be used more, such as an air jacket, which further enhances the heat use efficiency. Has an effect.

Meanwhile, in the present invention, two stop pinholes 20SPH may be formed in the body 20 in a symmetrical direction. A stop pin hole 20 SPH communicating with the upper surface of the body 20 and a stop pin hole 20 SPH communicating with the bottom surface of the body 20 are provided. The stop pin hole (20 SPH) is formed on the upper surface of the body 20 and one is formed on the bottom surface, so that a pair of stop pin holes (20 SPH) are formed symmetrically up and down based on the center line between the upper surface and the bottom surface of the body 20. I can. See Figures 26 to 29.

In this case, the spool 60 may be connected to the spool operation hole 28 of the body 20 in an upright position, or the spool 60 may be coupled to the spool operation hole 28 of the body 20 in a reversed state. When the spool 60 is turned over and inserted into the spool operation hole 28 of the body 20, the stopping pin provided in the lever 61 of the spool 60 slides into the stop pin hole 20SPH under the bottom of the body 20. It becomes a structure that can be combined.

As described above, when the lever 61 of the body 20 is turned over and coupled to the spool operation hole 28 of the body 20 so as to be disposed on the bottom surface of the body 20, the lever 61 of the spool 60 is When it is pulled so as to float in the air, it becomes a hot air use mode (see FIG. 28), and when the lever 61 of the spool 60 is pressed so as to contact the bottom surface of the body 20, it becomes a cold air use mode (see FIG. 29). In the case where the spool 60 is inserted into the spool coupling hole 28 of the body 20, since the hot air mode and the cold air mode are the same as the hot air mode and the cold air mode in the above-described embodiment, a duplicate description thereof will be omitted. , Since the functions and effects are also the same as those of the above-described embodiment, a redundant description thereof will be omitted.

Terms such as "include", "consist of" or "have" described above, unless otherwise stated, mean that the corresponding component may be present, and thus other components are not excluded. It should be interpreted as being able to further include other components. All terms, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art, unless otherwise defined, to which the present invention belongs. Terms generally used, such as terms defined in the dictionary, should be interpreted as being consistent with the meaning of the context of the related technology, and are not interpreted as ideal or excessively formal meanings unless explicitly defined in the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Therefore, the embodiments described above are provided to completely inform the scope of the invention to those of ordinary skill in the technical field to which the present invention belongs, and should be understood as illustrative and non-limiting in all respects, The invention is only defined by the scope of the claims.

20. Body 20CH. Cold air drain hole
20HH. Open drain hole 20SPH. Stop pinhole
20NG. Nut receiving groove NT. nut
20BH. Bolt insertion hole 20SB. Silencer boss
SM. Silencer 21. Swivel plug boss
21H. Pinhole PU. Upper pin
PL. Lower pin 22. Outlet hole
23. Vortex nozzle insertion hole 24. Cold air supply hole
25. Swivel plug 25PG. Pin coupling groove
26. Hot air supply hole 27. Compressed air inlet hole
28. Spool operation hole 29. Outlet plug boss
30. Cover 32. Shrinking cover
34. Through hole 36. Communication hole
38. Flange 40. Vortex tube
42. Vortex Nozzle 42CH. Center Hall
42PH. Vortex guide hole 50. Tube
60. Spool 60UEP. Upper end packing
60LEP. Lower end packing 60UMP. Upper middle packing
60LMP. Lower middle packing 61. Lever
61SP. Stop pin 62. Upper end adjustment stone piece
63. Lower end adjustment stone piece 65. Upper middle stone piece
66. Lower middle stone piece 67. Stopper
70. Belt hanger 72. Main hanger plate
73. Hook plate part 74. Hook plate part
75. Inner hanging plate 76. Fixing piece

Claims (10)

A body 20 having an outlet hole 22, a cold air supply hole 24, and a hot air supply hole 26 therein;
A cover 30 coupled to the body 20 and having a communication hole 38 therein;
A vortex tube 40 built into the cover 30;
A tube 50 built into the cover 30;
And a spool (60) coupled to the body (20) to selectively open and close the cold air supply hole (24) and the hot air supply hole (26).
The method of claim 1,
The vortex tube 40 is built to be disposed in a longitudinal direction between both ends of the cover 30, and the tube 50 is inside the cover 30 so as to be disposed in a direction parallel to the vortex tube 40. And the communication hole (36) inside the cover (30) is connected to one end of the vortex tube (40) and the tube (50).
The method of claim 2,
The inside of the cover 30 is provided with a vortex tube receiving groove and a tube receiving groove extending in the longitudinal direction between the base end and the front end, and the vortex tube 40 is accommodated in the vortex tube receiving groove, and the tube receiving groove The tube (50) is accommodated in, characterized in that configured to communicate the inside of the vortex tube (40) and the tube (50) in the communication hole (36).
The method of claim 3,
One end of the cover 30 is connected to the base end of the body 20 so that the vortex tube 40 and the inside of the tube 50 are formed inside the body 20. A cooling and heating machine, characterized in that communicating with the cold air supply hole 24 and the hot air supply hole 26, respectively.
The method of claim 4,
The body 20 is provided with an outlet hole 22 communicating with the cold air supply hole 24 and the hot air supply hole 26, and the cold air is supplied by a spool 60 built into the body 20 A cooler and warmer, characterized in that the hole (24) and the hot air supply hole (26) are configured to selectively communicate with the outlet hole (22).
The method of claim 5,
The spool 60 is coupled to the body 20 so as to be elevated and lowered, the cold air supply hole 24 and the opening in a push mode pressing the spool 60 and a pulling mode pulling the spool 60 The supply hole 26 is configured to selectively communicate with the outlet hole 22, respectively.
The method of claim 1,
The body 20 is provided with a compressed air inlet hole 27, and a nozzle is provided inside the body 20 so as to be disposed between the compressed air inlet hole 27 and one end of the vortex tube 40 Is configured to generate a vortex inside the vortex tube 40 while the compressed air entering through the compressed air inlet hole 27 passes through the nozzle.
The method of claim 7,
Heat is generated toward the inner circumferential surface of the vortex tube 40 by the vortex generated inside the vortex tube 40 by the nozzle, and cold air is generated toward the center of the vortex tube 40 Cooler and warmer.
The method of claim 8,
The cold air generated from the center side of the vortex tube 40 advances to the cold air supply hole 24 inside the body 20 to which one end of the vortex tube 40 is connected, and is generated from the inner peripheral surface side of the vortex tube 40. Heat flows into the inside of the tube 50 built into the body 20 through the communication hole 36 inside the body 20, and the heat flows into the heat supply hole 26 inside the body 20 Cooler and warmer, characterized in that configured to advance to.
The method of claim 9,
The cold air supply hole 24 and the hot air supply hole 26 inside the body 20 are selectively opened and closed by a spool 60 built into the body 20, and the spool 60 When the cold air supply hole 24 is opened, cold air is introduced into the outlet hole 22 formed in the body 20, and when the hot air supply hole 26 is opened by the spool 60, the body A cooling and heating machine, characterized in that heat flows into the outlet hole 22 formed in (20).

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