KR102563366B1 - Fluid dispensing apparatus - Google Patents

Abstract

The present invention relates to a nozzle assembly and an injection system including the same. The present invention has an outlet through which the first fluid and the second fluid are discharged at one end, connected to the first supply line at the other end, and connected to the second supply line to one side, and a base body inserted into the base body, the surface And an inserter having a guide groove disposed on the base body, wherein the first pressure of the first fluid supplied from the first supply line corresponds to the second pressure of the second fluid supplied from the second supply line. smaller, and the inserter passes through the inner space, the first fluid moves to the outlet, and the second fluid moves to the outlet along the guide groove.

Description

Fluid dispensing apparatus {Fluid dispensing apparatus}

The present invention relates to injection systems and fluid dispensing devices.

In general, a spraying device that sprays water through a plurality of nozzles is used to grow crops for plant growth, to lower the temperature of barns such as poultry farms or pig houses, or to lower the heat island temperature of exterior walls or roads in summer, etc. is widely used as

The spraying device needs to be configured to supply water at high pressure to the spray pipe in order to spray water in the form of mist through a plurality of nozzles connected to the spray pipe. As the pressure of the water supplied to the spray pipe increases, the effect of atomizing the water increases. However, there is a limit to setting the water at a high pressure, and it is difficult to maintain durability of parts when the water is set at a high pressure. In addition, since it is important to very atomize the water to be sprayed, research and development on this is necessary.

An object of the present invention is to provide a fluid dispensing device and an injection system capable of setting a flow path of different fluids. However, these tasks are illustrative, and the scope of the present invention is not limited thereby.

One aspect of the present invention is a first line into which a first fluid is introduced at one end, a first electromagnetic valve disposed at the other end of the first line, a second fluid is introduced at one end, and the first electronic valve is disposed at the other end. A second line on which a valve is disposed, and one end extending from the first electromagnetic valve, and the first fluid moving along the first line or the second fluid moving along the second line according to the opening and closing of the first electromagnetic valve. A third line into which two fluids are introduced, a fourth line having one end branched from the second line and moving the second fluid, and a second electromagnetic valve disposed at the other end of the fourth line; A fifth line connected to the electromagnetic valve, through which the first fluid or the second fluid moving the third line, and one end extend from the second electromagnetic valve, and according to the opening and closing of the second electromagnetic valve A fluid distribution device including a sixth line through which one of the second fluid moving along the fourth line or the first fluid and the second fluid moving along the fifth line is discharged.

The electronic device may further include a third electromagnetic valve disposed in the second line and a seventh line extending from the third electromagnetic valve.

In addition, it is disposed on any one of the second line and the fourth line, it may further include a flow control valve for adjusting the flow rate of the second fluid flowing from the second line to the fourth line.

In addition, a controller controlling opening and closing of the first electromagnetic valve and the second electromagnetic valve may be further included.

In addition, the controller adjusts the first electromagnetic valve to connect the first line and the third line to discharge the first fluid to the third line, or to connect the second line and the third line. By connecting, the second fluid may be discharged to the third line.

In addition, the controller adjusts the second electromagnetic valve to connect the fourth line and the sixth line to discharge the second fluid to the sixth line, or to separate the fifth line and the sixth line. The fluid introduced into the fifth line may be discharged through the sixth line.

Another aspect of the present invention is an A line having a first inlet into which a first fluid flows and a first outlet communicating with the first inlet, a first electromagnetic valve disposed on the A line, and the A line A second inlet through which the fluid discharged from is recovered, a B line having a second outlet connected to the second inlet, a second electromagnetic valve disposed on the B line, and the first electromagnetic valve and the second A C line connected to the electromagnetic valve and supplying a second fluid different from the first fluid to at least one of the first electromagnetic valve and the second electromagnetic valve, and opening and closing of the first electromagnetic valve and the second electromagnetic valve. It is possible to provide a fluid distribution device including a controller for controlling.

In addition, the controller may adjust the first electromagnetic valve so that the C line communicates with the first outlet.

In addition, the controller may adjust the second electromagnetic valve so that the C line communicates with the second outlet.

The injection system and the fluid distribution device according to the present invention may set flow paths of the first fluid and the second fluid according to various modes.

The injection system and the fluid distribution device according to the present invention have a simple and compact structure and can set various fluid movement paths.

1 is a diagram illustrating an injection system according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating the fluid dispensing device of FIG. 1;
FIG. 3 is a cross-sectional view illustrating a nozzle mounted on the nozzle unit of FIG. 1 .
4 to 7 are diagrams illustrating a driving mode of the fluid distribution device.
8 is a diagram showing an injection system according to another embodiment of the present invention.

Since the present invention can apply various transformations and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. Effects and features of the present invention, and methods for achieving them will become clear with reference to the embodiments described later in detail together with the drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and when describing with reference to the drawings, the same or corresponding components are assigned the same reference numerals, and overlapping descriptions thereof will be omitted. .

In the following embodiments, terms such as first and second are used for the purpose of distinguishing one component from another component without limiting meaning.

In the following examples, expressions in the singular number include plural expressions unless the context clearly dictates otherwise.

In the following embodiments, terms such as include or have mean that features or components described in the specification exist, and do not preclude the possibility that one or more other features or components may be added.

In the following embodiments, when a part such as a film, region, component, etc. is said to be on or on another part, not only when it is directly above the other part, but also when another film, region, component, etc. is interposed therebetween. Including if there is

In the drawings, the size of components may be exaggerated or reduced for convenience of description. For example, since the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, the present invention is not necessarily limited to the illustrated bar.

1 is a diagram illustrating an injection system according to an embodiment of the present invention.

Referring to FIG. 1 , the injection system 1 may inject different fluids. The injection system 1 may include a reservoir 10 , a pump 20 , a compressor 30 , a nozzle unit 40 and a fluid dispensing device 100 .

The reservoir 10 may store the first fluid. The first fluid may be variously set according to the installation location and purpose of the injection system 1 . For example, the first fluid may be a liquid such as water or a chemical solution.

The reservoir 10 is connected to the pump 20 so that the first fluid can be supplied to the fluid distribution device 100 . In addition, the reservoir 10 is connected to the sixth line L6 discharged from the fluid distribution device 100, so that the first fluid can be recovered or the second fluid can be injected.

The pump 20 may supply the first fluid stored in the reservoir 10 to the fluid distribution device 100 . The pump 20 may be disposed between the reservoir 10 and the fluid distribution device 100 to move the first fluid from the reservoir 10 to the fluid distribution device 100 . The pump 20 is not limited to a specific specification and may have various shapes capable of pumping the first fluid.

As an alternative embodiment, the pump 20 may be assembled to the fluid distribution device 100 and installed on one side of the fluid distribution device 100 .

The compressor 30 may deliver the second fluid to the fluid distribution device 100 . The compressor 30 may set the pressure of the second fluid to a preset pressure. The compressor 30 is not limited to a specific specification and may have various forms capable of compressing the second fluid.

As an alternative embodiment, the compressor 30 may be assembled to the fluid distribution device 100 and installed on one side of the fluid distribution device 100 .

The nozzle unit 40 is connected to the fluid distribution device 100 and may spray at least one of a first fluid and a second fluid supplied from the fluid distribution device 100 .

The nozzle unit 40 may include a plurality of injection nozzles and inject at least one of the first fluid and the second fluid through the injection nozzles. In addition, the nozzle unit 40 may split the first fluid by introducing the second fluid diverged from the compressor 30 . This will be explained below.

FIG. 2 is a diagram illustrating the fluid dispensing device of FIG. 1;

Referring to FIG. 2 , the fluid distribution device 100 includes a first electromagnetic valve 110 and a second electromagnetic valve 120, and may have a line through which the first fluid and the second fluid can move.

In one embodiment, the fluid distribution device 100 is a first line (L1), a second line (L2), a third line (L3), a fourth line (L4), a fifth line (L5), a sixth line (L6) and a seventh line (AL).

The first line L1 may be defined as a line through which the first fluid flows into the fluid distribution device 100 . A first fluid may flow into the first line L1 at one end.

The first line L1 may be connected to the first fluid supply line LW extending from the pump 20 . The first fluid supply line LW is connected to the first inlet 101 of the first line L1 so that the first fluid can flow into the fluid distribution device 100 .

The first electromagnetic valve 110 may be disposed at the other end of the first line L1. The first electromagnetic valve 110 may adjust the movement path of the first fluid or the second fluid. In the first electromagnetic valve 110, the first line L1, the second line L2, and the third line L3 are connected, and the first line L1 and the third line L3 are connected, or The second line L2 and the third line L3 may be connected.

The first electromagnetic valve 110 is defined as a valve that regulates a fluid flow path, and is not limited to specific specifications or standards. For example, the opening degree of the first electromagnetic valve 110 may be controlled by an electrical signal, and the moving path of the fluid may be changed by adjusting the opening degree of the first electromagnetic valve 110 .

Opening and closing of the first electromagnetic valve 110 may be controlled by manipulation of a controller (not shown). The first electromagnetic valve 110 connects the first line L1 and the third line L3 to set a movement path of the first fluid and block the movement of the second fluid to the third line L3. . In addition, the first electromagnetic valve 110 connects the second line (L2) and the third line (L3) to set the movement path of the second fluid and block the movement of the first fluid to the third line (L3). can

The second line L2 may be defined as a line through which the second fluid moves to the first electromagnetic valve 110 . In the second line L2, the second fluid is introduced at one end and a first electromagnetic valve may be disposed at the other end.

The second line L2 may be connected to the second fluid supply line LA extending from the compressor 30 . In the compressor 30, the second fluid may move to the second line L2.

The third line L3 may be defined as a line through which the fluid discharged from the first electromagnetic valve 110 moves. The third line L3 may have one end extending from the first electromagnetic valve 110 and the other end extending to the first outlet 102 .

The third line (L3) may supply the first fluid or the second fluid to the injection nozzle 400 of the nozzle unit 40. In the third line L3, the first fluid moving along the first line L1 or the second fluid moving along the second line L2 moves along the third line L3 according to the opening and closing of the first electromagnetic valve 110, and the injection A first fluid or a second fluid may be supplied to the nozzle 400 .

The fourth line L4 may be defined as a line through which the second fluid moves to the second electromagnetic valve 120 . The fourth line L4 may have one end branched from the second line L2 and the other end connected to the second electromagnetic valve 120 . Thus, the second fluid can move to the second electromagnetic valve 120 in the second line L2.

As an alternative embodiment, the flow control valve 130 may be disposed on any one of the second line L2 and the fourth line L4. The flow control valve 130 may control the flow rate of the second fluid flowing from the second line L2 to the fourth line L4.

The flow control valve 130 may control the flow rate of the second fluid moving to the first electromagnetic valve 110 and the second electromagnetic valve 120 .

For example, if a large amount of second fluid needs to be supplied to the nozzle unit 40, the flow control valve 130 reduces the flow rate of the second fluid moving to the fourth line L4, so that the first electromagnetic valve 110 ) can increase the flow rate of the second fluid. In addition, if a large amount of the second fluid needs to be supplied to the reservoir 10, the flow control valve 130 reduces the flow rate of the second fluid directed to the first electromagnetic valve 110, so that the second electromagnetic valve 120 ) can increase the flow rate of the second fluid.

The second electromagnetic valve 120 may be disposed at the other end of the fourth line L4. The second electromagnetic valve 120 may adjust the movement path of the first fluid or the second fluid. In the second electromagnetic valve 120, the fourth line L4, the fifth line L5, and the sixth line L6 are connected, and the fourth line L4 and the sixth line L6 are connected, or The fifth line L5 and the sixth line L6 may be connected.

The second electromagnetic valve 120 is defined as a valve that regulates a fluid flow path, and is not limited to specific specifications or standards. For example, the opening degree of the second electromagnetic valve 120 may be controlled by an electrical signal, and the moving path of the fluid may be changed by adjusting the opening degree of the second electromagnetic valve 120 .

Opening and closing of the second electromagnetic valve 120 may be controlled by manipulation of a controller (not shown). The second electromagnetic valve 120 may connect the fourth line L4 and the sixth line L6 to set a movement path of the second fluid and block the fifth line L5. In addition, the second electromagnetic valve 120 connects the fifth line (L5) and the sixth line (L6) to set a movement path of the fluid moving in the fifth line (L5) and blocks the fourth line (L4). can

The fifth line L5 may be defined as a line through which fluid is recovered from the nozzle unit 40 to the fluid distribution device 100 . That is, the first fluid or the second fluid passing through the nozzle unit 40 may be introduced into the fifth line L5 of the fluid distribution device 100 again.

The fifth line (L5) has one end connected to the second inlet 103 and the other end connected to the second solenoid valve 120, the first fluid moved in the third line (L3) and the nozzle unit 40 B. The second fluid can move.

The sixth line L6 may be defined as a line through which the fluid discharged from the second electromagnetic valve 120 moves. The sixth line L6 may have one end extending from the second electromagnetic valve 120 and the other end extending to the second outlet 104 .

The sixth line (L6) is the second fluid that moves along the fourth line (L4) according to the opening and closing of the second electromagnetic valve 120, the first fluid and the second fluid that moves along the fifth line (L5) One of them can be released.

In detail, when the fourth line (L4) and the sixth line (L6) are connected, the high-pressure second fluid may move along the sixth line (L6) and be discharged from the second outlet (104). When the fifth line L5 and the sixth line L6 are connected, the first fluid or the second fluid returned from the nozzle unit 40 moves along the sixth line L6 and exits the second outlet 104. may be discharged.

Also, referring to FIG. 1, the sixth line L6 is connected to the reservoir 10 so that the first fluid is recovered to the reservoir 10 or the second fluid is stored in the reservoir 10. It can be sprayed into the fluid.

The third electromagnetic valve 140 is disposed between the compressor 30 and the first electromagnetic valve 110, and may partially extract the second fluid and directly supply it to the nozzle unit 40. The third electromagnetic valve 140 may be disposed at a position capable of distributing the flow rate of the second fluid moving from the second fluid supply line LA to the second line L2 and the seventh line AL.

In one embodiment, the third electromagnetic valve 140 is connected to the second fluid supply line LA, the second line L2 and the seventh line AL, and moves the second fluid to the nozzle unit 40. can make it

The third electromagnetic valve 140 may connect the second fluid supply line LA and the second line L2 or connect the second fluid supply line LA and the seventh line AL. Also, the third electromagnetic valve 140 may distribute the flow rate of the second fluid from the second fluid supply line LA to the second line L2 and the seventh line AL.

In another embodiment, the third electromagnetic valve 140 may be disposed on the second line L2, and the second fluid supply line LA and the seventh line AL may be connected. The opening degree of the third electromagnetic valve 140 is adjusted so that the flow rate of the second fluid moving from the second fluid supply line LA to the second line L2 and the seventh line AL may be distributed.

In another embodiment, the third electromagnetic valve 140 may be disposed on the seventh line AL, and the second fluid supply line LA may be connected to the second line L2. The opening degree of the third electromagnetic valve 140 is adjusted so that the flow rate of the second fluid moving from the second fluid supply line LA to the second line L2 and the seventh line AL may be distributed.

The seventh line AL may extend from the third electromagnetic valve 140 . One end of the seventh line AL may be connected to the third electromagnetic valve 140 and the other end may be connected to the nozzle unit 40 .

As an alternative embodiment, the filter unit 150 may be installed in the first line L1. The filter unit 150 may filter the first fluid flowing into the fluid distribution device 100 to prevent the inside of the fluid distribution device 100 or the inside of the nozzle unit 40 from being clogged with foreign substances.

A controller (not shown) may control opening and closing of the first electromagnetic valve 110 and the second electromagnetic valve 120 . In addition, the controller may adjust the opening or closing of the third electromagnetic valve 140 .

The controller adjusts the first electromagnetic valve 110 to connect the first line L1 and the third line L3 to discharge the first fluid to the third line L3 or to the second line L2. And the third line (L3) is connected to the second fluid can be discharged to the third line (L3).

The controller adjusts the second electromagnetic valve 120 to connect the fourth line L4 and the sixth line L6 to discharge the second fluid to the sixth line L6 or to the fifth line L5. And the sixth line (L6) is connected to the fluid introduced into the fifth line (L5) can be discharged to the sixth line (L6).

For example, the controller may be a device that transmits a control signal to an electromagnetic valve by a user's manipulation. The user may operate the controller according to the operation of the injection system. As another example, the controller may be software programmed, and the electronic valve may be automatically adjusted according to programmed set values.

In another embodiment, the fluid distribution device 100 may include an A line (A-L), a B line (B-L), a C line (C-L), a first electromagnetic valve 110, and a second electromagnetic valve 120. .

Line A-L may have a first inlet 101 into which a first fluid flows and a first outlet 102 communicating with the first inlet 101 .

Line A-L is a path between the first inlet 101 and the first outlet 102 of the fluid distribution device 100, and may be set as a path through which the first fluid can move. The first line L1 and the third line L3 of the above-described embodiment may form the A line A-L.

The first electromagnetic valve 110 may be disposed on the A line (A-L).

The B line (B-L) may have a second inlet 103 through which fluid discharged from the A-line (A-L) is recovered, and a second outlet 104 connected to the second inlet 103 .

Line B-L is a path between the second inlet 103 and the second outlet 104 of the fluid distribution device 100, and a path through which the first fluid or the second fluid recovered from the nozzle unit 40 moves. can be set to The fifth line L5 and the sixth line L6 of the above-described embodiment may form a B line.

The second electromagnetic valve 120 may be disposed on the B line (B-L).

Line C (C-L) is connected to the first solenoid valve 110 and the second solenoid valve 120, and can supply the second fluid to at least one of the first solenoid valve 110 and the second solenoid valve 120. there is.

Line C-L may be set as a path through which the second fluid is introduced from the compressor 30 and the introduced second fluid moves to the first electromagnetic valve 110 and the second electromagnetic valve 120 . The second line L2, the fourth line L4 and the second fluid supply line LA of the above-described embodiment may form the C line C-L.

The third electromagnetic valve 140 may be disposed on the C line C-L, and the seventh line AL branched from the third electromagnetic valve 140 may be connected to the nozzle unit 40 .

A controller (not shown) may control opening and closing of the first electromagnetic valve 110 and the second electromagnetic valve 120 . The controller may adjust the first electromagnetic valve 110 so that the C line (C-L) communicates with the first outlet 102. The controller may adjust the second electromagnetic valve 120 so that the C line (C-L) communicates with the second outlet 104.

Figure 3 is a cross-sectional view showing a spray nozzle mounted on the nozzle unit of Figure 1;

Referring to FIG. 3 , in the spray nozzle 400, the first fluid and the second fluid are independently introduced, and the first fluid and the second fluid are mixed at the outlet 415 to be injected more finely.

The injection nozzle 400 may be mounted on a pipe connected to the third line (L3) or the fifth line (L5), as shown in the drawing, to eject the fluid introduced from the pipe. However, it is not limited thereto, and the injection nozzle 400 may be manufactured integrally with the pipe.

In one embodiment, the first fluid may be a liquid and the second fluid may be a gas. In the spray nozzle 400, the second fluid forms a vortex so that the sprayed first fluid can be more finely sprayed.

In another embodiment, both the first fluid and the second fluid may be liquid or gaseous. In the spray nozzle 400, the second fluid forms a vortex so that the sprayed first fluid can be more finely sprayed. In another embodiment, the first fluid may be a gas and the second fluid may be a liquid.

The first fluid and the second fluid may be variously set according to the usage of the spray nozzle 400 . For example, if the spray nozzle 400 is used to finely spray water, the first fluid may be set to water, and the second fluid may be set to air. As another example, if the spray nozzle 400 is used to supply drugs to plants such as a greenhouse, the first fluid may be set to drug and the second fluid may be set to air.

The second pressure of the second fluid flowing into the injection nozzle 400 may be set higher than the first pressure of the first fluid. The high-pressure second fluid may finely atomize the first fluid by breaking the first fluid into small pieces. Also, when the second fluid is injected from the injection nozzle 400, the first fluid may flow due to a pressure difference. That is, since the outlet 415 of the injection nozzle 400 is set to a relatively low pressure when the second fluid is injected, the first fluid may move to the outlet 415 due to the pressure difference.

The injection nozzle 400 may include a base body 410, an inserter 420, and a sealing ring 430. In addition, as an alternative embodiment, the spray nozzle 400 may include a filter 440 .

The base body 410 is mounted on a pipe, and an inserter 420, a sealing ring 430, and a filter 440 may be disposed in an internal space. The base body 410 may have a body 411, a nozzle end 412, a supply end 413, a protrusion 414, and an outlet 415.

The base body 410 may have an outlet 415 through which the first fluid and the second fluid are discharged at one end. The base body 410 may have a third line L3 or a fifth line L5 connected to the other end and a seventh line AL connected to one side. The first fluid may be introduced into the third line L3 or the fifth line L5, and the second fluid may be introduced into the seventh line AL.

One end of the body 411 is connected to the pipe, and the nozzle end 412 may extend to the other end. Inside the body 411 may have a main space (411A). The body 411 and the pipe may be assembled in various forms. In one embodiment, the body 411 and the pipe may be connected by screwing.

The supply end 413 is connected to the main space 411A, and the second fluid may flow into the supply end 413 . The main space 411A is partitioned by a flange 423, the first fluid flows into the insert 420 at the rear based on the flange 423, and the second fluid flows at the front based on the flange 423. is introduced, and the second fluid may move to the nozzle end 412 and the outlet 415 along the outside of the insert 420 .

The nozzle end 412 is connected to the body 411, and the head part 421 of the inserter 420 may be disposed therein. The inner surface 412A of the nozzle end 412 is in contact with the surface of the head portion 421 . An outlet 415 may be disposed at an end of the head portion 421 . The inner surface 412A of the nozzle end 412 and the surface of the head portion 421 are in close contact, so that the second fluid cannot pass through, but is directed along a guide groove (not shown) disposed on the surface of the head portion 421. 2 The fluid can move.

The supply end 413 extends to one side of the base body 410 and may be connected to the seventh line AL. One end of the supply end 413 is connected to the seventh line AL, and the other end of the supply end 413 is connected to the main space 411A. The second fluid may be supplied into the base body 410 through the supply end 413 .

The protrusion 414 may be disposed at the end of the nozzle end 412 . The protrusion 414 may be disposed outside the outlet 415 . When cleaning the spray nozzle 400, the user closes the end of the nozzle end 412, and the user's finger places it on the protrusion 414 and then presses it. Then, the second opening 410H of the nozzle end 412 is completely blocked, and the second fluid may flow into the inserter 420 .

The outlet 415 may be disposed at one end of the base body 410, and the first fluid and the second fluid may be discharged. The outlet 415 is disposed inside the nozzle stage 412 and may be located at the end of the nozzle stage 412 . The outlet 415 has a second opening 410H, and the first fluid and the second fluid may be discharged through the second opening 410H.

In one embodiment, outlet 415 may have a predetermined interior space. An end of the inserter 420 is connected to the outlet 415, and the first fluid and the second fluid discharged from the inserter 420 pass through the outlet 415 and can be injected to the outside of the spray nozzle 400. there is.

In one embodiment, the outlet 415 may have a first space 415A and a second space 415B. The first space 415A may be connected to the first opening 420H of the inserter 420, and the second space 415B may be connected to the second opening 410H of the base body 410.

The first space 415A may be larger than the second space 415B. The first space 415A provides a predetermined space to the high-pressure second fluid transformed into a vortex, guides the first fluid to move forward, and pulverizes the first fluid more finely. Since the volume of the second space 415B is smaller than that of the first space 415A, the injected first fluid may be injected more strongly.

In detail, the first width t1 of the first space 415A in the radial direction may be smaller than the second width t2 of the second space 415B. The first opening 420H of the inserter 420 may have a third width t3, and the third width t3 may be smaller than the first width t1 and the second width t2. . The first fluid discharged from the first opening 420H passes through the first space 415A and the second space 415B, and at this time, the first fluid may be more finely pulverized by the second fluid.

Since the outlet 415 provides a space for accommodating the first fluid and the second fluid, the second fluid may be introduced into the insert 420 when the spray nozzle 400 is cleaned. When cleaning the spray nozzle 400, when the user closes the end of the nozzle end 412, the second opening 410H of the nozzle end 412 is completely blocked and moves along a guide groove (not shown). The second fluid may flow into the inserter 420 through the first opening 420H. This will be described in detail below.

In other embodiments, outlet 415 may have one or more spaces. One space or three or more spaces may be provided between the first opening 420H and the second opening 410H.

The inserter 420 is inserted into the base body 410 and may have a guide groove (not shown) disposed on the surface.

The insert 420 provides a path through which the first fluid and the second fluid respectively move. The first fluid may flow into the inserter 420 and the second fluid may move along the outer surface of the inserter 420 . The inserter 420 provides a path for the first fluid to move and guides the second fluid to turn, so that a vortex may be formed in the second fluid.

In the inserter 420 , the head portion 421 , the shaft 422 , and the flange 423 may be disposed in the direction of the first axis AX1 . In addition, a first inner space 421S is disposed inside the head portion 421, a second inner space 422S is disposed inside the shaft 422, and a third inner space is disposed inside the flange 423. 423S is disposed, and the first inner space 421S, the second inner space 422S, and the third inner space 423S may be connected to each other in the direction of the first axis AX1.

The head part 421 is inserted into the nozzle end 412 . The surface of the head part 421 is in close contact with the inner surface 412A of the nozzle end 412, and the movement path of the second fluid can be set by a guide groove (not shown).

A guide groove (not shown) may be disposed on the surface of the head portion 421 . A plurality of guide grooves (not shown) may be provided and spaced apart from each other along the inclined surface of the head part 421 . A plurality of guide grooves (not shown) may be spaced apart from the center of the head portion 421 at equal intervals.

In one embodiment, as shown in the drawing, the inserter 420 may have three guide grooves (not shown) disposed on the surface of the head portion 421 .

In another embodiment, although not shown in the drawings, two or more guide grooves of the inserter may be disposed in the head portion.

In another embodiment, although not shown in the drawings, the inserter may have one guide groove disposed on the surface of the head portion, and one guide groove may have a spiral shape along the head portion.

The shaft 422 is connected to the head portion 421, and the first fluid may pass therein. Although the drawing shows that the shaft 422 has a substantially cylindrical shape, it is not limited thereto and may have various shapes such as a polygonal column.

The diameter of the shaft 422 is smaller than the diameter of the flange 423 and smaller than the diameter of the lower end of the head portion 421 . A space through which the second fluid can flow is formed on the outside of the shaft 422, and the space communicates with a guide groove (not shown) of the head part 421 so that the second fluid flows along the guide groove (not shown). can move

The flange 423 is connected to the shaft 422 and may extend in a radial direction. The flange 423 may extend to the inner surface of the body 411 and partition the main space 411A of the body 411 . Since the flange 423 divides the front and rear of the main space 411A, mixing of the first fluid and the second fluid in the body 411 can be prevented.

4 to 7 are diagrams illustrating a driving mode of the fluid distribution device.

Referring to FIG. 4 , the first mode of the injection system 1 can be described as follows.

The first electromagnetic valve 110 may connect the first line L1 and the third line L3, and the second electromagnetic valve 120 may connect the fifth line L5 and the sixth line L6. .

The first fluid may pass through the filter unit 150 and be introduced into the fluid distribution device 100 by the pump 20 . The first fluid may pass through the third line L3 and move to the nozzle unit 40 by the first electromagnetic valve 110 .

A portion of the first fluid moved to the nozzle unit 40 is discharged by moving to the outlet 415 of the injection nozzle 400, and the rest may be recovered to the fluid distribution device 100 through the fifth line L5. there is. Thereafter, the first fluid may be returned to the reservoir 10 by moving along the sixth line L6.

The first mode is a step in which the first fluid circulates through the reservoir 10, the fluid distribution device 100, and the nozzle unit 40. In a first mode, the first fluid can fill the injection system 1 . Since the first fluid is filled in the nozzle unit 40, the injection system 1 can be prepared for injection in the first mode.

In detail, the first fluid is filled in the path between the reservoir 10 and the fluid distribution device 100, filled inside the fluid distribution device 100, and the fluid distribution device 100 and the nozzle unit 40 are It fills the pathway and may fill the pathway between the fluid distribution device 100 and the reservoir 10.

If the injection proceeds before the first fluid is filled in the injection nozzle 400, the injection of the injection nozzle 400 does not proceed smoothly. If the first fluid is filled in the injection system 1 before being injected, since the entirety of the plurality of injection nozzles 400 of the nozzle unit 40 are injected simultaneously, all the injection nozzles 400 of the nozzle unit 40 are injected. loading time is reduced, and the synchronicity of the entire jetting of the nozzle system 1 is improved. That is, since the present invention fills the injection system 1 before the first fluid is injected in the first mode, preparation for injection is completed and durability of the injection system 1 can be improved.

As an alternative embodiment, the high-pressure second fluid may be supplied to the injection nozzle 400 through the seventh line AL.

Referring to FIG. 5 , the second mode of the injection system 1 can be described as follows.

The first electromagnetic valve 110 may connect the first line L1 and the third line L3, and the second electromagnetic valve 120 may connect the fourth line L4 and the sixth line L6. .

The first fluid may pass through the filter unit 150 and be introduced into the fluid distribution device 100 by the pump 20 . The first fluid may pass through the third line L3 and move to the nozzle unit 40 by the first electromagnetic valve 110 .

All of the first fluid that has moved to the nozzle unit 40 can only move to the nozzle unit 40 . Since the second electromagnetic valve 120 closes the fifth line L5, the entire amount of the first fluid can be injected from the injection nozzle 400.

Since the second electromagnetic valve 120 connects the fourth line L4 and the sixth line L6, the second fluid passes through the fourth line L4 and is discharged through the second outlet 104. Since the discharged second fluid moves to the reservoir 10 again, the high-pressure second fluid may mix the first fluid stored in the reservoir 10 . For example, the high-pressure second fluid may mix the first fluid including the chemical solution to improve the quality of the chemical solution moving to the pump 20 .

At this time, the third electromagnetic valve 140 may branch some of the second fluid to the seventh line AL. The second fluid flows into the supply end 413 of the injection nozzle 400, and the second fluid can atomize the first fluid discharged through the outlet 415.

The second mode is a step in which the first fluid and the second fluid are sprayed from the nozzle unit of the injection system 1 . The first fluid is injected from the injection nozzle 400, and at this time, the second fluid may also enter the injection nozzle 400 to atomize the first fluid.

Referring to FIG. 6 , the third mode of the injection system 1 can be described as follows.

The first electromagnetic valve 110 may connect the second line L2 and the third line L3, and the second electromagnetic valve 120 may connect the fifth line L5 and the sixth line L6. .

Since the first electromagnetic valve 110 closes the first line L1, the first fluid does not flow into the fluid distribution device 100. The second fluid moving along the second line L2 is discharged through the first outlet 102 of the third line L3 and introduced into the nozzle unit 40 .

Referring to FIG. 3, while moving along the third line L3, a portion of the second fluid moves to the insert 420 of the injection nozzle 400, and the rest is recovered along the fifth line L5. . The second fluid passing through the center of the insert 420 of the injection nozzle 400 may be discharged to the outside through the outlet 415 .

The second fluid entering the second inlet 103 along the fifth line L5 moves to the sixth line L6 by the second solenoid valve 120 and is discharged to the second outlet 104. The discharged second fluid may move to the reservoir 10 .

As an alternative embodiment, the high-pressure second fluid may be supplied to the injection nozzle 400 through the seventh line AL.

The third mode is a step of removing the first fluid filled in the internal pipe after the injection of the injection system 1 is finished. In the third mode, the inflow of the first fluid is blocked, and the second fluid may discharge the first fluid remaining in the pipe to the outside while moving along the path along which the first fluid moved. In addition, while the high-pressure second fluid moves along the path along which the first fluid moved, the dregs of the first fluid may be removed. The third mode can increase the cleanliness and stability of the injection system 1 and increase the durability of the pipe.

Referring to FIG. 7 , the fourth mode of the injection system 1 can be described as follows.

The first electromagnetic valve 110 may connect the second line L2 and the third line L3, and the second electromagnetic valve 120 may connect the fourth line L4 and the sixth line L6. .

Since the first electromagnetic valve 110 closes the first line L1, the first fluid does not flow into the fluid distribution device 100. The second fluid moving along the second line L2 is discharged through the first outlet 102 of the third line L3 and introduced into the nozzle unit 40 .

Since the second electromagnetic valve 120 closes the fifth line L5, unlike the third mode, the second fluid can be discharged to the outside only through the injection nozzle 400. Since a large amount of the high-pressure second fluid flows into the spray nozzle 400, foreign substances remaining on the tip of the spray nozzle 400 can be completely removed.

The second fluid that has moved from the fourth line L4 to the sixth line L6 moves back to the reservoir 10, is injected into the first fluid stored in the reservoir 10, and mixes the first fluid again. can make it

As an alternative embodiment, the high-pressure second fluid may be supplied to the injection nozzle 400 through the seventh line AL. The second fluid may move to the surface of the inserter 420 of the spray nozzle 400 to remove foreign substances remaining inside the spray nozzle 400 .

At this time, the third electromagnetic valve 140 may precisely clean the tip of the injection nozzle 400 by increasing the amount of the second fluid moving to the seventh line AL. In addition, by adjusting the flow rate control valve 130, the flow rate of the second fluid moving to the second line (L2) is increased and the flow rate of the second fluid moving to the fourth line (L4) is lowered so that the injection nozzle 400 The inside can be thoroughly cleaned.

8 is a diagram showing an injection system according to another embodiment of the present invention.

Referring to FIG. 8 , the injection system may include the pump 20, the compressor 30, and the fluid distribution device 100 of the above-described embodiment. Comparing the injection system with the aforementioned embodiment, there is a difference in the nozzle unit, and hereinafter, this will be mainly described.

A plurality of nozzle units may be provided. For example, the injection system may include a first nozzle unit 41, a second nozzle unit 42, and a third nozzle unit 43 in order to install injection nozzles in a plurality of spaces. The injection system arranges an on-off valve and a check valve in each nozzle unit, so that each nozzle unit can be injected independently.

A first open/close valve VA1 may be disposed at an inlet of the first nozzle unit 41 and a first check valve VA2 may be disposed at an outlet of the first nozzle unit 41 . A second open/close valve VB1 may be disposed at an inlet of the second nozzle unit 42 , and a second check valve VB2 may be disposed at an outlet of the second nozzle unit 42 . A third open/close valve VC1 may be disposed at an inlet of the third nozzle unit 43 and a third check valve VC2 may be disposed at an outlet of the third nozzle unit 43 .

The user may connect each nozzle unit to the third line L3 by adjusting each open/close valve. In addition, a check valve may be disposed at the outlet of each nozzle unit so that the fluid discharged from each nozzle unit flows into the fifth line L5.

The injection system and the fluid distribution device according to the present invention may set the flow path of the first fluid and the second fluid according to various modes.

As a step for preparing the injection system, the first fluid may be filled in the pipe in the first mode. In addition, when the second mode is driven, the first fluid and the second fluid are sprayed together from the spray nozzle, so that the atomized first fluid can be sprayed to the target area. In addition, when the third mode is driven, the first fluid remaining in the pipe after the end of the injection may be removed, and internal foreign substances may be removed. In addition, in the fourth mode, the high-pressure second fluid flows into the spray nozzle to clean the spray nozzle and increase durability of the spray nozzle.

The injection system and the fluid distribution device according to the present invention have a simple and compact structure and can set various fluid movement paths.

In this way, the present invention has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. . Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

1: injection system
10: reservoir
20: pump
30: Compressor
100: fluid distribution device
110: first electromagnetic valve
120: second electromagnetic valve
130: flow control valve
140: third electromagnetic valve

Claims (9)

a first line into which a first fluid is introduced at one end;
a first electromagnetic valve disposed at the other end of the first line;
a second line into which a second fluid is introduced at one end and the first electromagnetic valve disposed at the other end;
a third line having one end extending from the first electromagnetic valve and into which the first fluid moving along the first line or the second fluid moving along the second line flows as the first electromagnetic valve opens and closes;
a fourth line, one end of which is branched from the second line, through which the second fluid moves;
a second electromagnetic valve disposed at the other end of the fourth line;
a fifth line connected to the second solenoid valve and moving the first fluid or the second fluid having moved the third line; and
One end extends from the second electromagnetic valve, and one of the second fluid moving along the fourth line or the first fluid and the second fluid moving along the fifth line according to the opening and closing of the second electromagnetic valve A sixth line discharged; including, a fluid distribution device. According to claim 1,
a third electromagnetic valve controlling the flow rate of the second fluid flowing into the second line; and
The fluid distribution device further comprising a seventh line through which the second fluid branched from the third electromagnetic valve moves. According to claim 1,
The fluid distribution device further comprising a; flow rate control valve disposed on any one of the second line and the fourth line and adjusting the flow rate of the second fluid flowing from the second line to the fourth line. According to claim 1,
The fluid distribution device further comprising a; controller for controlling opening and closing of the first electromagnetic valve and the second electromagnetic valve. According to claim 4,
The controller
By adjusting the first electromagnetic valve, the first fluid is discharged to the third line by connecting the first line and the third line, or the second line and the third line are connected to discharge the second fluid. fluid dispensing device that discharges fluid into the third line. According to claim 4,
The controller
By controlling the second electromagnetic valve, the fourth line and the sixth line are connected to discharge the second fluid to the sixth line, or the fifth line and the sixth line are connected to discharge the second fluid to the fifth line. A fluid distribution device for discharging the fluid introduced into the line to the sixth line. A line having a first inlet into which a first fluid flows and a first outlet communicating with the first inlet;
a first electromagnetic valve disposed on the A line;
a B line having a second inlet through which the fluid discharged from the A line is recovered, and a second outlet connected to the second inlet;
a second electromagnetic valve disposed on the B line;
a C line connected to the first electromagnetic valve and the second electromagnetic valve and supplying a second fluid different from the first fluid to at least one of the first electromagnetic valve and the second electromagnetic valve; and
A fluid distribution device including a controller controlling opening and closing of the first electromagnetic valve and the second electromagnetic valve. According to claim 7,
The controller
and adjusting the first electromagnetic valve so that the C line communicates with the first outlet. According to claim 8,
The controller
and adjusting the second electromagnetic valve so that the C line communicates with the second outlet.

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