KR20220018734A - Medicinal Fluid Dispensing Device - Google Patents

Abstract

According to one embodiment of the present invention, provided is a medicinal fluid dispensing device which comprises: a housing; a dispensing nozzle provided in the housing to dispense a medicinal fluid in a mist state; a medicinal fluid supply unit provided in the housing to supply the medicinal fluid to the dispensing nozzle; and a gas supply unit provided in the housing to supply compressed gas to the dispensing nozzle, wherein the dispensing nozzle comprises a twin-fluid nozzle which dispenses the medicinal fluid in a mist state by the medicinal fluid supplied from the medicinal fluid supply unit colliding with the gas supplied from the gas supply unit.

Description

Medical Fluid Dispensing Device

The present invention relates to a chemical spraying device, and more particularly, to a chemical spraying device for spraying a chemical liquid in a mist state with small droplets in an indoor space.

A conventional mist spraying device includes a water tank for storing a liquid such as water in order to spray the liquid in a mist state, a high-pressure pump for pumping water in the water tank, and a spray nozzle for spraying water in a mist form.

However, the size of the mist (droplets) sprayed in the conventional mist spraying device is determined according to the size of the discharge hole of the spray nozzle and the pressure of the liquid supplied to the spray nozzle. In order to reduce the size of the mist, the size of the discharge hole of the spray nozzle can be reduced, but when the size of the discharge hole is reduced, there is a problem in that the amount of the discharged mist is reduced. Conversely, if the size of the discharge hole of the spray nozzle is increased in order to increase the amount of mist, there is a problem that the small size of the desired mist cannot be obtained.

Korean Patent Publication No. 10-2038911 (Cooling Air and Cooling Mist Injection System)

An object of the present invention is to provide a chemical spraying device capable of spraying a sufficient amount of mist while having a small mist size.

An object of the present invention is to provide a chemical spraying device that minimizes the non-ejected area of the spraying target by using a small-sized mist. In other words, in the present invention, even if the chemical liquid is sprayed on an area of the same size, since the size of the mist is small and sprayed in a sufficient amount, it is sprayed at a higher density on the sprayed area to widen the spray coverage area.

An object of the present invention is to provide a chemical spraying device that increases the probability of contact with viruses, bacteria and harmful organisms in the air by increasing the time to float in the air because the small size of the mistletoe is sprayed.

A chemical spraying device according to an embodiment of the present invention includes: a housing; a spray nozzle provided in the housing to spray the chemical in a mist state; a chemical solution supply unit provided in the housing to supply the chemical solution to the injection nozzle; It may include a gas supply unit provided in the housing and supplying compressed gas to the injection nozzle, wherein the injection nozzle collides the chemical liquid supplied from the chemical liquid supply unit with the gas supplied from the gas supply unit to supply the chemical liquid. It is possible to provide a chemical liquid injection device comprising a two-fluid nozzle for spraying in a mist state.

In the chemical liquid injection device according to an embodiment of the present invention, the injection nozzle may include a hydraulic nozzle that sprays only the gas supplied from the gas supply unit.

In the chemical liquid injection device according to an embodiment of the present invention, the gas supply unit,

a gas inlet provided in the housing to introduce external air into the housing; a gas filter for filtering the air introduced into the gas inlet; a gas compression unit for compressing the filtered air; and a gas flow passage communicating between the gas inlet and the injection nozzle.

In the chemical spraying apparatus according to an embodiment of the present invention, the chemical supply unit may include: a chemical container provided inside the housing to store the chemical; a chemical liquid flow path connected between the chemical liquid container and the injection nozzle to allow the chemical liquid to move; and a chemical liquid valve provided on the chemical liquid passage to block the flow of the chemical liquid.

The chemical liquid injection device according to an embodiment of the present invention may provide a chemical liquid injection device further comprising a gas branch passage connecting the gas passage and the chemical liquid passage at the rear end of the chemical liquid valve.

In the chemical spraying device according to an embodiment of the present invention, the housing may include: a first housing in which the gas supply unit and the chemical liquid supply unit are disposed; and a second housing in which the injection nozzle is disposed, wherein the second housing is rotatably provided on an upper portion of the first housing.

In the chemical spraying device according to an embodiment of the present invention, the housing may be fixed to the upper ceiling of the room using a connection bracket.

The present invention has the effect of providing a chemical spraying device capable of spraying a sufficient amount of mist while having a small mist size.

The present invention has the effect of providing a chemical spraying device that minimizes the non-ejection area of the spraying target by using a small-sized mist.

The present invention has the effect of providing a chemical spraying device capable of increasing the time to float in the air because the mistet of a small size is sprayed.

1 is a side cross-sectional view of a chemical liquid injection device according to an embodiment of the present invention.
2 is a side cross-sectional view of a chemical liquid injection device according to another embodiment of the present invention.
3 (a) to 3 (d) is a plan view showing a chemical liquid injection device according to another embodiment of the present invention.
4 is a perspective view of the air nozzle of the present invention.
5 is an exploded perspective view of FIG. 4 ;
6 is a cross-sectional view taken along line AA′ of FIG. 4 .
FIG. 7 is a cross-sectional view taken along line CC′ of FIG. 5 .
FIG. 8 is a cross-sectional view taken along line BB′ of FIG. 4 .
9 is a view showing the flow of gas and chemical liquid in the two-fluid nozzle.
10A is an enlarged view of an end of the air nozzle according to an embodiment of the present invention.
10 (b) is an enlarged view of the end of the air nozzle according to another embodiment of the present invention.
11 is a block diagram of a chemical spraying device of the present invention.

Specific structural or functional descriptions of the embodiments according to the concept of the present invention disclosed in this specification are only exemplified for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention are It may be implemented in various forms and is not limited to the embodiments described herein.

Since the embodiments according to the concept of the present invention may have various changes and may have various forms, the embodiments will be illustrated in the drawings and described in detail herein. However, this is not intended to limit the embodiments according to the concept of the present invention to specific disclosed forms, and includes all modifications, equivalents, or substitutes included in the spirit and scope of the present invention.

1 is a side cross-sectional view of a chemical liquid injection device according to an embodiment of the present invention. 2 is a side cross-sectional view of a chemical spraying device according to another embodiment of the present invention.

The chemical liquid injection device 1 according to an embodiment of the present invention may include a housing 10 , an injection nozzle 20 , a gas supply unit 30 , and a chemical liquid supply unit 40 .

As shown in FIG. 1 or FIG. 2 , the housing 10 forms the outer shape of the chemical spraying device 1 according to an embodiment of the present invention. The housing 10 may be formed of a material that is not damaged by a sterilizing or disinfecting liquid such as alcohol. For example, the housing 10 may be made of a material having a strong corrosive property, such as plastic or stainless steel.

Referring to FIG. 1 , the housing 10 includes a first housing 11 in which at least one injection nozzle 20 is located, and a second housing 13 in which a gas supply unit 30 and a chemical liquid supply unit 40 are located. may include The first housing 11 is rotatably coupled to the second housing 13 , and the first housing 11 may spray the chemical through the injection nozzle 20 while rotating.

When the second housing 13 is placed on the ground, the first housing 11 may be rotatably coupled to the upper side of the second housing 13 to spray the chemical while rotating. Alternatively, when the second housing 13 is fixed to the ceiling or wall, the first housing 11 may be rotatably coupled to the lower side or side of the second housing 13 to spray the chemical while rotating.

Referring to FIG. 2 , the housing 10 may be formed of a single housing in which at least one injection nozzle 20 , a gas supply unit 30 , and a chemical solution supply unit 40 are located. In this case, the housing 10 may be fixed to the ceiling or wall, or placed on the ground to inject the chemical through the injection nozzle 20 .

Referring to FIGS. 1 and 2 , at least one injection nozzle 20 may inject a chemical liquid into an injection target or in the air in a mist state. The chemical liquid injected from the at least one injection nozzle 20 may kill harmful organisms such as viruses or bacteria that exist on the surface of the injection target or are floating in the air.

Referring to FIG. 1 , at least one injection nozzle 20 may be provided in plurality in the first housing 11 . At least one injection nozzle 20 may be provided on one surface of the first housing 11, and may be injected to form an injection network of a certain size in the air. In other words, the injection directions of the at least one injection nozzle 20 may form an acute angle with each other. Since the first housing 11 can be rotated, even if the spray nozzle 20 is positioned on one surface of the first housing 11 , the chemical can be sprayed in the circumferential direction of the first housing 10 .

The at least one injection nozzle 20 includes at least one air nozzle 21 capable of reducing the mist size of the chemical liquid by spraying both the chemical liquid and the gas, and at least one hydraulic nozzle 23 that sprays only the gas or the chemical liquid. ) may be included. The at least one hydraulic nozzle 21 may be located closer to the center of the injection direction than the at least one hydraulic nozzle 23 . The at least one hydraulic nozzle 21 may be provided to be surrounded by the at least one hydraulic nozzle 23 .

Referring to FIG. 2 , at least one injection nozzle 20 may be provided in plurality on the outer circumferential surface of the housing 10 . The at least one injection nozzle 20 is provided in plurality on the outer side surface of the housing 10 to inject the chemical in the circumferential direction of the housing 10 .

The at least one injection nozzle 20 includes at least one air nozzle 21 capable of reducing the mist size of the chemical liquid by spraying both the chemical liquid and the gas, and at least one hydraulic nozzle 23 that sprays only the gas or the chemical liquid. ) may include at least one of.

The chemical liquid injection device 1 according to an embodiment of the present invention may further include a connection bracket 50 . The connection bracket 50 may serve to fix the chemical spraying device 1 to another object such as a ceiling or a wall in the room.

The connection bracket 50 may fix or rotatably couple the chemical liquid injection device 1 to the ceiling 52 or wall surface (not shown) of the room. Accordingly, the chemical liquid spraying device 1 can evenly spray the chemical liquid in a mist state in various directions in the room.

3 (a) to 3 (d) is a plan view showing a chemical spraying device according to another embodiment of the present invention.

The housing 10 is a rectangular parallelepiped (see Fig. 3(a)), a cylinder (see Fig. 3(b)), a pentagonal prism (see Fig. 3(c)), a hexagonal prism (see Fig. 3(d)) or a polygonal prism (see Fig. 3(d)) not shown) may be formed. In addition, the at least one injection nozzle 20 may be disposed in all or part of the outer side of the housing (10). By disposing the at least one injection nozzle 20 on the plurality of side surfaces of the housing 10, the chemical liquid can be sprayed in several directions at the same time, and the effect of increasing the space in which the chemical liquid is sprayed and reducing the injection time can be obtained.

The gas supply unit 30 and the chemical solution supply unit 40 will be described with reference to FIGS. 1 and 2 again.

1 and 2 , the gas supply unit 30 is provided in the housing 10 to supply compressed gas to the injection nozzle 20 . The gas supply unit 30 may include a gas inlet 31 , a gas filter 33 , a gas compression unit 37 , and a gas flow path 35 .

The gas inlet 31 may be provided in the housing 10 having the gas supply unit 30 therein. The gas inlet 31 may be provided in the second housing 13 provided with the gas supply unit 30 . The gas inlet 31 refers to a hole through which external air is introduced into the interior of the housing 10 .

The gas filter 33 may filter out foreign substances from the external air introduced into the housing 10 . The gas filter 33 may filter the air introduced through the gas inlet 31 . The gas filter 33 may be disposed in the inner space of the housing 10 in which the gas inlet 31 is formed. Furthermore, the gas filter 33 may be formed on the inner peripheral surface of the housing 10 in which the gas inlet 31 is formed. The gas filter 33 may be formed in the gas flow path 35 or on the gas flow path 35 .

The gas flow path 35 connects between the gas inlet 31 and the injection nozzle 20 and may serve as a passage through which the gas moves. The gas flow path 35 is a flow path (not shown) integrally formed in the housing 10, a hose (not shown) made of an elastic material, or a flow path (not shown) and a hose (not shown) integrally formed in the housing. ) can be formed by a combination of

The gas flow path 35 includes a first gas flow path 35-1 for supplying gas to the hydraulic nozzle 21, which will be described later, and a second gas flow path 35-2 for supplying gas to the hydraulic nozzle 23, which will be described later. ) may be included. The first gas flow passage 35 - 1 and the second gas flow passage 35 - 2 may be branched into a plurality according to the number of the air nozzles 21 or the hydraulic nozzles 23 .

The gas compression unit 37 may compress the air in the gas flow path 35 and supply it to the injection nozzle 20 . The gas compression unit 37 is connected to the gas flow path 35 at the front end and the rear end. Alternatively, the front end of the gas compression unit 37 may be directly connected to the gas filter 33 .

The gas compression unit 37 may be operated by receiving power, and the degree of gas compression, on/off, driving time, etc. are controlled by the control unit 60 .

The gas compression unit 37 may be formed of a pneumatic pump 37 or a combination of a motor (not shown) and a fan (not shown). The gas compression unit 37 may form a negative pressure at the front end to suck in external air through the gas inlet 31 , compress the sucked air, and discharge the compressed air at the rear end. The compressed air reaches the injection nozzle 20 through the gas flow path 35 .

In addition, the gas supply unit 30 may further include a gas branch passage (39). The gas branching flow path 39 may be branched from the gas flow path 35 to be described later and connected to the chemical liquid flow path 47 . The gas branching flow path 39 branches at the rear end of the gas compression unit 37 and may supply air compressed in the gas compression unit 37 to a chemical liquid flow path 47 to be described later. The chemical liquid remaining after being sprayed may be present in the chemical liquid passage 47 , which may cause a problem in that the chemical liquid passage 47 may be contaminated or bacteria may inhabit. The chemical liquid remaining in the chemical liquid passage 47 may be removed by compressed air supplied through the gas branch passage 39 .

In addition, the gas supply unit 30 may further include a gas sterilization unit 32 capable of sterilizing the gas passing through the gas passage 35 . The gas sterilization unit 32 may include a UV lamp or UV LED for irradiating ultraviolet light. The gas sterilization unit 32 may be installed in the gas flow path 35 , and may be installed in the gas flow path 35 between the gas compression unit 37 and the gas branch flow path 39 to sterilize the compressed air. The gas sterilization unit 32 is installed on the inner circumferential surface of the gas flow path 35 to irradiate UV light toward the central axis of the gas flow path 35 or is installed on the central axis of the gas flow path 35 to irradiate UV light in the radial direction. can Alternatively, the gas sterilization unit 32 may irradiate ultraviolet light from the outer circumferential surface of the transparent gas flow path 35 toward the center of the gas flow path 35 .

The chemical solution supply unit 40 may be provided in the housing 10 to supply the chemical solution to the injection nozzle 20 . The chemical liquid may be a liquid having a component capable of killing viruses, bacteria, or harmful organisms. The chemical liquid supply unit 40 may include a chemical liquid container 41 , a chemical liquid valve 45 , and a chemical liquid passage 43 .

The chemical liquid container 41 may supply the chemical liquid to the injection nozzle 20 by temporarily storing the chemical liquid. The chemical container 41 may be fixed or detachably coupled to the inside of the housing 10 . The chemical container 41 may be formed of a plastic material having corrosion resistance to the chemical.

The chemical container 41 may be provided in one or a plurality. When a plurality of chemical solution containers 41 are provided, each of the chemical solution containers 41 may store different types of chemical solutions, respectively. Alternatively, each of the plurality of chemical liquid containers 41 may include a chemical liquid level sensor 44 to be described later in order to sense the level of the chemical liquid in each chemical liquid container 41 .

The chemical solution supply unit 40 may further include a chemical solution temperature control unit 42 . The chemical liquid temperature control unit 42 may be disposed inside the chemical liquid container 41 to heat the chemical stored in the chemical liquid container 41 and control the temperature of the chemical liquid. The chemical solution stored in the chemical solution container 41 may be heated by the chemical solution temperature control unit 42 to convert from a liquid phase to a gas phase, or may be heated to a preset temperature or maintained at a preset temperature.

The chemical liquid flow path 43 may provide a path through which the chemical liquid may move by connecting the chemical liquid container 41 and the injection nozzle 20 . The chemical fluid flow path 43 is a flow path (not shown) formed integrally with the housing 10, a hose (not shown) made of an elastic material, or a flow path (not shown) and a hose (not shown) formed integrally with the housing. ) can be formed by a combination of

The chemical liquid valve 45 may be provided on the chemical liquid passage 43 to block the flow of the chemical liquid. The chemical liquid valve 45 is electrically controlled by the control unit 60 to open when the chemical liquid is required to be discharged through the injection nozzle 20, and can be closed when the chemical liquid is not required to be discharged. The chemical liquid valve 45 may be installed between the chemical liquid passage 43 to which the chemical liquid container 41 and the gas branch passage 39 are connected.

An operation in which the chemical liquid stored in the chemical liquid container 41 is supplied to the injection nozzle 21 will be described. When the chemical liquid is to be injected from the injection nozzle 20, the chemical liquid valve 45 is opened. The gas compressed by the gas compression unit 37 is injected from a gas discharge port 331 to be described later formed at the end of the injection nozzle 20 . The compressed gas injected from the injection nozzle 20 forms a negative pressure at the end of the injection nozzle 20 . A liquid discharge port 510 to be described later through which the chemical liquid is injected is formed at the end of the injection nozzle 20, and the chemical liquid stored in the chemical liquid container 41 is drawn through the chemical liquid passage 43 by the negative pressure formed by the compressed gas and The liquid is discharged through the discharge port 510 .

Alternatively, the chemical liquid supply unit 40 may further include a chemical liquid pump 47 or a chemical liquid piston 48 (see FIG. 2 ). The chemical liquid pump 47 may be located between the chemical liquid container 41 and the chemical liquid passage 43 to pump the chemical stored in the chemical liquid container 41 and supply it to the chemical liquid passage 43 . Alternatively, the chemical liquid piston 48 is provided in the chemical liquid container 41, and the chemical liquid flow path 43 connected to the chemical liquid container 41 by adjusting the internal volume of the chemical liquid container 41 to transfer the chemical stored in the chemical liquid container 41. ) can be supplied.

In addition, the chemical solution supply unit 40 may include a chemical solution level sensor (44). The chemical liquid level sensor 44 is located inside the chemical liquid container 41 and can sense the level of the chemical stored in the chemical liquid container 41 and deliver it to the control unit 60 .

4 is a perspective view of the air nozzle of the present invention. 5 is an exploded perspective view of FIG. 4 ; 6 is a cross-sectional view taken along line A-A' of FIG. 4 . 7 is a cross-sectional view taken along line C-C' of FIG. 5 . 8 is a cross-sectional view taken along line B-B' of FIG. 4 . 9 is a view showing the flow of gas and chemical liquid in the two-fluid nozzle.

The air nozzle 21 of the present invention will be described with reference to FIGS. 4 to 9 .

The two-fluid nozzle 21 of the present invention includes a body 100, a liquid discharge port 510 formed at an end of the body 100 through which the chemical is discharged, and the liquid discharge port 510 through which gas is discharged. A gas outlet 331 formed at the end of the 100, a liquid supply unit 500 formed inside the body 100 to supply a liquid by being connected to the liquid outlet 510, and a gas connected to the gas outlet 331 It may include a chamber 300 formed inside the body 100 to supply the.

The liquid supply unit 500 of the two-fluid nozzle 21 communicates with the chemical liquid passage 43 to receive the liquid from the chemical liquid container 41 . The chamber 300 of the air nozzle 21 communicates with the gas flow path 35 to receive compressed gas from the gas compression unit 37 . Accordingly, the chemical liquid discharged from the liquid discharge port 510 collides with the compressed gas discharged from the gas discharge port 331 , and is sprayed while being crushed to have a mist form having a small size.

The body 100 forms the external shape of the air nozzle 21 . The body 100 may include a chamber 300 formed therein for gas to flow. The chamber 300 may have a circular cross-section.

The body 100 may be formed by combining the upper body 110 and the lower body 130 . The upper body 110 may include a flange 111 and a liquid supply unit 500 . The liquid supply unit 500 may be formed to protrude downward from the flange 111 . A spiral part 900 may be provided at an end of the liquid supply part 500 . The lower body 130 may include a chamber 300 formed to open upward. When the upper body 110 and the lower body 130 are coupled, the chamber 300 has a closed space, and gas may flow in the chamber 300 . The lower body 130 may include a first gas supply unit 700 communicating with the chamber 300 .

The lower body 130 may include a spraying part 131 protruding in a downward direction at a lower end thereof. A hole 133 is formed in the center of the ejection unit 131 , and a liquid discharge port 510 is disposed in the center of the hole 133 . A gas discharge port 331 may be formed in a space between the injection unit 131 and an end of the liquid supply unit 500 . The ejection unit 131 is formed to have a smaller space in the lower direction, and through this, the gas outlet 331 may be disposed to surround the liquid outlet 510 at a distance close to the liquid outlet 510 .

The chamber 300 is formed inside the body 100, specifically, the lower body 130 and communicates with the first gas supply unit 700 to provide a space through which the gas supplied from the first gas supply unit 700 flows. At the same time, it provides a space in which the spiral part 900 is accommodated.

The chamber 300 includes an upper chamber 310 communicating with the first gas supply unit 700 and a lower chamber 330 having an injection unit 131 disposed thereunder. The cross-sectional area of the upper chamber 310 is larger than that of the lower chamber 330 . The cross-sectional area of the lower chamber 330 is narrower than the cross-sectional area of the upper chamber 310 and is inclined in the direction of the central axis of the body 100 so that the cross-sectional area becomes narrower toward the bottom. A lower portion of the lower chamber 330 communicates with the gas outlet 331 .

A lower portion of the spiral portion 900 is inserted and accommodated in the lower chamber 330 , and an upper portion of the spiral portion 900 is located in the upper chamber 310 . Accordingly, in the region where the spiral part 900 is not located in the upper chamber 310 , the gas helically rotates in the space of the upper chamber 310 .

The above-described first gas supply unit 700 , the upper chamber 310 , the lower chamber 330 , and the gas outlet 331 communicate with each other. Accordingly, the gas flowing into the upper chamber 310 through the first gas supply unit 700 is discharged to the gas outlet 331 through the lower chamber 330 .

The liquid supply part 500 is formed to protrude downward from the flange 111 of the upper body 110 , and a spiral part 900 is provided at an end of the liquid supply part 500 .

The central axis of the liquid supply unit 500 has the same central axis as the central axis of the body 100 and the central axis of the air nozzle 21 . The central axis of the liquid supply unit 500 has the same central axis as the central axis of the chamber 300 . Accordingly, the liquid supply unit 500 is disposed along the central axis of the chamber 300 . Specifically, the liquid supply unit 500 is disposed on the central axis of the chamber 300 , and is disposed in the center of the chamber 300 .

A lower portion of the liquid supply unit 500 and a lower portion of the spiral portion 900 are disposed in the lower chamber 330 of the chamber 300 . In this case, the lower part of the liquid supply part 500 and the lower part of the spiral part 900 are inserted and accommodated in the lower chamber 330 . A liquid outlet 510 is provided at the lower end of the liquid supply unit 500 . Accordingly, the liquid supplied to the liquid supply unit 500 is discharged through the liquid discharge port 510 .

The central point of the liquid discharge port 510 is disposed on the central axis of the liquid supply unit 500 . Accordingly, the liquid supply unit 500 is disposed on the central axis of the chamber 300 , and the liquid discharge port 510 and the lower surface of the air nozzle 21 , that is, the body 100 (or the lower body 130 ). is formed at the center of the lower surface of

The gas outlet 331 communicates with the lower portion of the lower chamber 330 of the chamber 300 and is disposed to surround the liquid outlet 510 . The gas discharge port 331 is formed as a space between the inner side of the injection unit 131 and the outer end of the liquid supply unit 500 . This gas discharge port 331 has a ring shape. Accordingly, the gas outlet 331 is disposed around the liquid supply unit 500 , and has a ring shape to surround the liquid outlet 510 .

The first gas supply unit 700 communicates with the front of the upper chamber 310 of the chamber 300 . In this case, the first gas supply unit 700 is disposed eccentrically to one side from the central axis of the body 100 . As the first gas supply unit 700 is eccentrically disposed on one side from the central axis of the body 100 and communicates with the front of the upper chamber 310 of the chamber 300, the upper portion through the first gas supply unit 700 When the gas is supplied to the chamber 310 , the gas is spirally rotated along the inner wall of the chamber 300 inside the chamber 300 .

As the first gas supply unit 700 is disposed eccentrically to the right from the central axis of the body 100 , as shown in FIG. 8 , the gas moves the inner wall of the chamber 300 clockwise inside the chamber 300 will rotate in a spiral.

One side of the inner wall of the first gas supply unit 700 and the chamber 300 so that a step does not occur between one side of the inner wall of the upper chamber 310 of the chamber 300 communicating with one side of the inner wall of the first gas supply unit 700 ) of the upper chamber 310 is provided with a 1-1 guide portion 710 that connects one side of the inner wall obliquely. The first-first guide part 710 may be formed to have a curvature, and the curvature may be formed to be convex in an outer direction of the chamber 300 to correspond to the shape of the inner wall of the chamber 300 .

The spiral part 900 is disposed in the chamber 300 to communicate with the gas outlet 331 . A portion of the helix 900 , ie, a lower portion of the helix 900 , is disposed to be located in the lower chamber 330 of the chamber 300 , and the remainder of the helix 900 , ie, the lower portion of the helix 900 . The upper part is disposed to be located in the upper chamber 330 of the chamber 300 .

A plurality of spiral passages 910 are formed in the spiral portion 900 to communicate a portion of the upper chamber 300 and the gas discharge port 331 . The spiral direction of the plurality of spiral flow paths 910 is formed to be the same as the direction in which the gas supplied to the chamber 300 through the first gas supply unit 700 spirally rotates in the chamber 300 . The spiral direction of the plurality of spiral flow paths 910 and the eccentric direction of the first gas supply unit 700 are formed to be the same so that the spiral rotation direction of the gas coincides, so that the spiral rotation force of the gas flowing in the chamber 300 is further increased it gets bigger

Hereinafter, the flow of gas and liquid in the two-fluid nozzle 21 of the present invention will be described.

The high-pressure compressed gas is supplied to the first gas supply unit 700 through the gas flow path 35 communicating with the first gas supply unit 700 of the air nozzle 21 . After that, it flows into the upper chamber 310 through the first-first guide part 710 . The gas flowing into the upper chamber 310 rotates in a clockwise direction based on the view from the top of the chamber 300 , and the gas flowing in a clockwise spiral rotation passes through the upper chamber 310 and the spiral part 900 . After flowing through the plurality of spiral flow paths 910 of the gas discharge port 331 is discharged.

The liquid supplied through the chemical liquid passage 43 flows through the inside of the liquid supply unit 500 and is discharged to the outside through the liquid discharge port 510 . The liquid discharged through the liquid discharge port 510 collides with the high-speed, high-pressure compressed gas discharged through the gas discharge port 331 at the bottom of the injection unit 131 to generate a mist of the mixture. In this case, the mist is converted into a form of fine water droplets when the liquid collides with a high-speed, high-pressure compressed gas and is sprayed in the form of a mist.

10A is an enlarged view of an end of the air nozzle according to an embodiment of the present invention. 10 (b) is an enlarged view of the end of the air nozzle according to another embodiment of the present invention.

FIG. 10 (a) relates to an external collision type air nozzle. The collision point between the liquid discharged from the liquid discharge port 510 and the compressed gas discharged from the gas discharge port 331 is the outside of the air nozzle, and the liquid discharge port The liquid discharged into the air in 510 collides with the compressed gas, collides with it, and is crushed to a fine size and sprayed in a mist state.

FIG. 10(b) relates to an internal collision type air nozzle, wherein the collision point between the liquid discharged from the liquid discharge port 510 and the compressed gas discharged from the gas discharge port 331 is the inside of the air pressure nozzle. may collide with the collision wall 520 and firstly be broken into a fine mist and then collide with the compressed gas discharged through the gas outlet 331 to be secondarily broken into a smaller mist and be sprayed.

11 shows a block diagram of the chemical liquid injection device 1 of the present invention.

The chemical liquid injecting device 1 of the present invention may include a control unit 60 for controlling components constituting the chemical liquid injecting apparatus 1 .

The control unit 60 may control the gas compression unit 37 to compress the gas and supply the compressed gas to the gas flow path 35 . The control unit 60 may control the gas sterilization unit 32 to sterilize the gas passing through the gas flow path 35 with ultraviolet rays. The control unit 60 may control the chemical solution temperature control unit 42 to heat the chemical solution stored in the chemical solution container 41 . The control unit 60 may determine the level of the chemical solution stored in the chemical solution container 41 based on the level signal sensed by the chemical solution level sensor 44 located inside the chemical solution container 41, and the control unit 60 is the housing ( 10) can be displayed on the display 16 installed on the outer surface of the remaining chemical liquid level display or the sprayable time using the remaining chemical liquid. The control unit 60 may control the chemical liquid valve 45 to open and close the chemical liquid passage 43 . The control unit 60 may control the chemical liquid pump 47 to pump the chemical stored in the chemical liquid container 41 and supply it to the chemical liquid passage 43 .

Meanwhile, the controller 60 may control the driving unit 15 to rotate the first housing 11 rotatably connected to the second housing 13 . The driving unit 15 includes a motor (not shown) that receives electricity and generates a rotational force, a gear (not shown) connected to the rotating shaft of the motor, and a rotating shaft (not shown) connected to the first housing 11 and rotated by meshing with the gear can do.

In addition, the control unit 60 receives a user input signal input through the user input unit 17, such as a push button or a dial button, spray time, spray mode, on/off, the first housing 11 or housing 10 It is possible to transmit a control command signal for whether to rotate, whether to start spraying, etc. to each part.

In addition, the control unit 60 is based on the user's remote signal received through the communication unit 19, spraying time, spraying mode, on/off, whether the first housing 11 or housing 10 is rotated, whether to start spraying It is possible to transmit a control command signal to each component.

Housing (10) First housing (11)
2nd housing (13) driving unit (15)
Display (16) User input unit (17)
Communication unit (19) Jet nozzle (20)
Hydraulic Nozzle (21) Hydraulic Nozzle (23)
Gas supply unit (30) Gas inlet (31)
Gas filter (33) Gas flow path (35)
Gas compression unit (37) Gas branch flow path (39)
Gas sterilization unit (32) Chemical supply unit (40)
Chemical container (41) Chemical liquid temperature control unit (42)
Chemical liquid flow path (43) Chemical liquid level sensor (44)
Chemical liquid valve (45) Chemical liquid pump (47)
Connection bracket (50) Control unit (60)

Claims (7)

housing;
a spray nozzle provided in the housing to spray the chemical in a mist state;
a chemical solution supply unit provided in the housing to supply the chemical solution to the injection nozzle; and
and a gas supply unit provided in the housing to supply compressed gas to the injection nozzle,
and the injection nozzle includes a two-fluid nozzle for spraying the chemical in a mist state by colliding the chemical liquid supplied from the chemical liquid supply unit with the gas supplied from the gas supply unit. According to claim 1,
and the injection nozzle includes a hydraulic nozzle that sprays only the gas supplied from the gas supply unit. According to claim 1,
The gas supply unit,
a gas inlet provided in the housing to introduce external air into the housing;
a gas filter for filtering the air introduced into the gas inlet;
a gas compression unit for compressing the filtered air; and
and a gas flow passage communicating between the gas inlet and the injection nozzle. 4. The method of claim 3,
The drug supply unit,
a chemical container provided inside the housing to store the chemical;
a chemical liquid passage connecting the chemical liquid container and the injection nozzle to allow the chemical liquid to move; and
and a chemical liquid valve provided on the chemical liquid passage to block the flow of the chemical liquid. 5. The method of claim 4,
The chemical liquid injection device further comprising a gas branch passage connecting the gas passage and the chemical liquid passage at the rear end of the chemical liquid valve. 5. The method of claim 4,
The housing is
a first housing in which the gas supply unit and the chemical solution supply unit are disposed; and
and a second housing in which the injection nozzle is disposed,
and the second housing is rotatably provided on an upper portion of the first housing. 5. The method of claim 4,
The housing is a chemical spraying device, characterized in that it is fixed to the upper ceiling of the room using a connection bracket.

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