KR102610586B1 - Spraying system - Google Patents

Abstract

The present invention relates to nozzle assemblies. The present invention is a filter including a base body having an outlet through which fluid is discharged at one end, an inserter inserted into the base body, one end of which is inserted into the base body to face the inserter, and a filter net having a curved surface at the other end. Disclosed is a nozzle assembly including a block.

Description

Spraying system {Spraying system}

The present invention relates to injection systems.

In general, in order to automatically spray water or pesticides for the growth and development of crops, a greenhouse is equipped with a plurality of spray nozzles that are connected to a supply pipe that supplies water or pesticides and are fixedly installed by a fixture at regular intervals.

When spraying pesticides in a house-type facility such as a greenhouse, when using a conventional manual sprayer, you carry a heavy container of chemical solution on your back, operate the pump of the spray cylinder with one hand, and use the other hand to operate the pump of the spray cylinder. Hold the nozzle bar and spray pesticide. At this time, the spraying pesticide may cause damage to the user, such as inhalation of the pesticide into the respiratory tract.

The chemical spray device installed in house facilities that has become popular in recent years installs a rail rod near the ceiling, installs a driving movable body on the rail rod that moves back and forth along the rail rod, and moves the driving movable body to create a plurality of spray nozzles. Research is continuing to allow the nozzle bar equipped with this to move back and forth in the longitudinal direction within the house to spray chemicals such as pesticides or nutrients to greenhouse crops.

The purpose is to provide a nozzle assembly that is mounted on a fluid flowing connector and performs filtering without interfering with the flow of fluid. However, these tasks are illustrative and do not limit the scope of the present invention.

One aspect of the present invention includes a base body having an outlet through which fluid is discharged at one end, an inserter inserted into the base body, and a filter network inserted into the base body so that one end faces the inserter and having a curved surface at the other end. It may include a filter block having a.

Additionally, the filter block has a first opening through which the filter network is exposed, and at least a portion of the filter network may protrude from the first opening.

Additionally, the filter block supports the filter network and may include at least one supporter protruding from the first opening.

Additionally, the supporter may have a curvature corresponding to the curved surface of the filter network.

In addition, the filter block has a pair of first low points with the other ends facing each other in a first direction, and a pair of first high points with the other ends facing each other in a second direction different from the first direction, and the first low points and Extended by connecting the first high points, the filter network may protrude between the first low points and the first high points.

In addition, the filter block further includes a first body block having a first opening and a second body block into which the first body block is inserted and disposed to face the inserter, and the filter network is connected to the first body block. It is disposed between the block and the second body block, and may protrude from the first opening.

Additionally, the first body block has a pair of first low points facing each other in a first direction and a pair of first high points facing each other in a second direction different from the first direction, wherein the first low point and the first high point are opposite to each other in a first direction. It extends by connecting one high point, and the second body block has a second low point aligned to correspond to the pair of first low points, and a second high point aligned to correspond to the pair of first high points, It extends by connecting a second low point and the second high point, and when the first body block is assembled to the second body block, the first low point is inserted into the second low point, and the first high point is inserted into the second low point. 2 Can be inserted at the high point.

In addition, the second body block may further include a second opening disposed along the center and a supporter disposed inside the second opening and having a curvature along the filter network at an end.

Additionally, the supporter may protrude from the first opening.

In addition, one of the first body block and the second body block has one of a guide groove and a guide protrusion disposed on an outer surface,

The other one of the first body block and the second body block may be provided with another one of a guide groove and a guide protrusion disposed on an outer surface.

In the nozzle assembly according to the present invention, a filter block having a curved surface similar to the inner diameter shape of the pipe is mounted on the pipe, so that foreign substances can be filtered without interfering with the flow of fluid.

The nozzle assembly according to the present invention can spray the final sprayed fluid into a required particle size by passing it through a filter net having a radius of curvature.

The nozzle assembly according to the present invention can be arranged so that the filter net protrudes on the path of the fluid, so that foreign substances contained in the fluid can be filtered out.

1 is a diagram illustrating a nozzle assembly according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing a portion of the nozzle assembly of Figure 1;
FIG. 3 is a perspective view showing the filter block of FIG. 1.
FIG. 4 is a cross-sectional view showing the first body block of FIG. 3.
FIG. 5 is a perspective view showing the second body block of FIG. 3.
FIG. 6 is a cross-sectional view of the second body block of FIG. 5.
Figure 7 is a perspective view of a portion of the filter block shown in Figure 3 cut away.
FIG. 8 is a diagram illustrating the operation of the nozzle assembly of FIG. 1.
Figure 9 is a perspective view showing a state in which a filter block is mounted on the nozzle assembly of Figure 1.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. The effects and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along 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. When describing with reference to the drawings, identical or corresponding components will be assigned the same reference numerals and redundant description thereof will be omitted. .

In the following embodiments, terms such as first and second are used not in a limiting sense but for the purpose of distinguishing one component from another component.

In the following examples, singular terms include plural terms unless the context clearly dictates otherwise.

In the following embodiments, terms such as include or have mean that the features or components described in the specification exist, and do not exclude in advance the possibility of adding one or more other features or components.

In the following embodiments, when a part of a film, region, component, etc. is said to be on or on another part, not only is it located directly on top of the other part, but also other parts such as a film, region, or component are interposed between them. Also includes cases where it is.

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

1 is a diagram illustrating a nozzle assembly 10 according to an embodiment of the present invention.

Referring to FIG. 1, the first fluid (F1) and the second fluid (F2) are introduced independently into the nozzle assembly 10, and the first fluid (F1) and the second fluid (F2) are mixed to produce a finer fluid. It can be sprayed easily.

The nozzle assembly 10 is mounted on an external pipe (P) as shown in the drawing and can spray the first fluid (F1) flowing from the pipe (P). However, the present invention is not limited to this, and the nozzle assembly 10 may be manufactured integrally with the pipe P.

The pipe (P) may be defined as a passage through which the first fluid (F1) moves. In one embodiment, the pipe P may have a connection port in some sections where the nozzle assembly 10 can be mounted. That is, the connection port connects two pipes, and the nozzle assembly 10 can be mounted on the connection port.

The pipe P forms a connection pipe for the first fluid F1 flowing in one direction and guides the path, and the nozzle assembly 10 may be disposed on the transfer path of the first fluid F1.

Hereinafter, a description will be made based on an embodiment of the nozzle assembly 10 disposed on a T-shaped pipe (P) forming a connection portion in an orthogonal direction. However, the shape of the pipe P is not limited to the example shown in the drawing, and may be selectively connected depending on usage conditions.

In one embodiment, the first fluid F1 may be a liquid and the second fluid F2 may be a gas. The nozzle assembly 10 may have a filter block 300 disposed therein filter out foreign substances inside the first fluid F1 moving through the pipe P and spray the filtered fluid.

In another embodiment, both the first fluid F1 and the second fluid F2 may be liquid or gas. The nozzle assembly 10 can cause the second fluid F2 to form a vortex, thereby spraying the injected first fluid F1 more finely. In another example, the first fluid F1 may be a gas and the second fluid F2 may be a liquid.

The first fluid F1 and the second fluid F2 may be set in various ways depending on the purpose of use of the nozzle assembly 10. For example, if the nozzle assembly 10 is used to finely spray water, the first fluid F1 may be set to water and the second fluid F2 may be set to air. As another example, if the nozzle assembly 10 is used to supply drugs to plants such as greenhouses, the first fluid (F1) may be set to drug, and the second fluid (F2) may be set to air.

The nozzle assembly 10 may include a base body 100, an inserter 200, a sealing ring 210, and a filter block 300.

The base body 100 is mounted on the pipe P, and an inserter 200, a sealing ring 210, and a filter block 300 may be arranged in the internal space.

The base body 100 may have an outlet at one end through which the first fluid F1 and the second fluid F2 are discharged. The base body 100 may be connected to a supply line through which the first fluid (F1) flows at the other end, and to a supply line through which the second fluid (F2) flows at one side. One end of the base body 100 is open so that the first fluid F1 and the second fluid F2 can be discharged through the open outlet.

The inserter 200 is inserted into the base body 100, and the first fluid F1 can pass through it, and the second fluid F2 can pass between the surface and the base body 100.

The inserter 200 provides paths along which the first fluid (F1) and the second fluid (F2) each move. The first fluid F1 flows into the inserter 200, and the second fluid F2 moves along the outer surface of the inserter 200. The inserter 200 provides a path along which the first fluid F1 moves and guides the second fluid F2 to rotate, so that a vortex may be formed in the second fluid F2.

The sealing ring 210 may be disposed inside the base body 100 and at the rear end of the inserter 200. The sealing ring 210 may seal the gap between the inserter 200 and the base body 100.

The nozzle assembly 10 is inserted into the base body 100 so that one end faces the inserter 200, and may include a filter block 300 having a filter net 330 having a curved surface at the other end.

FIG. 2 is an exploded perspective view showing a portion of the nozzle assembly 10 of FIG. 1, and FIG. 3 is a perspective view showing the filter block 300 of FIG. 1.

Referring to Figures 2 and 3, the filter block 300 may be mounted on one side of the pipe (P). The filter block 300 may be inserted into the base body 100 so that one end faces the inserter 200.

The first fluid (F1) moves in one direction along the pipe (P), and the filter block 300 may be disposed between the paths along which the first fluid (F1) moves. The filter block 300 is disposed on the movement path of the first fluid F1 and can filter foreign substances contained in the first fluid F1.

The filter block 300 may have a filter network 330 having a curved surface at the other end. The filter block 300 has a first opening 311 through which the filter net 330 is exposed, and at least a portion of the filter net 330 may protrude from the first opening 311. Additionally, the filter block 300 supports the filter network 330 and may include at least one supporter 323 protruding from the first opening 311.

Referring to FIG. 1, at least a portion of the filter network 330 protrudes from the inner peripheral surface of the pipe P, so that the first fluid F1 may contact the filter network 330 while moving along the pipe P. .

Since the filter net 330 protrudes from the inner peripheral surface of the pipe (P), the filter net 330 allows the first fluid (F1) to pass through the nozzle assembly 10 and at the same time removes foreign substances remaining in the filter net 330. 1 Can be cleaned by fluid (F1). This will be explained in detail below.

In one embodiment, the filter block 300 may include a first body block 310, a second body block 320, and a filter network 330. The filter block 300 may be composed of a plurality of blocks assembled as shown in the drawing.

In another embodiment, the filter block 300 may be manufactured as an integrated block with a filter net 330 on the inside. The filter block 300 includes a first body block 310 having a first opening 311 and a second body block 320 into which the first body block 310 is inserted and disposed to face the inserter 200. It can be further provided.

FIG. 4 is a cross-sectional view showing the first body block 310 of FIG. 3, FIG. 5 is a perspective view showing the second body block 320 of FIG. 3, and FIG. 6 is a cross-sectional view showing the second body block 320 of FIG. 5. ) is a cross-sectional view of

Referring to FIGS. 3 to 6 , the filter block 300 may include a first body block 310, a filter network 330, and a second body block 320 arranged in the direction of the first axis AX1.

The first body block 310 may include a first opening 311 through which the filter network 330 is exposed. The first body block 310 may extend a predetermined length toward the first axis AX1.

The first body block 310 is formed at one end with a first opening 311 penetrating toward the other end 312, and thus may include an internal space open at the other end 312. For example, the first body block 310 may have a first opening 311 on one side with respect to the first axis AX1 and an open other end 312 of the first opening 311 on the other side. The other end 312 may be set to a first diameter d1 so that the second body block 320 is inserted.

As an example, the first body block 310 may be assembled by inserting the filter network 330 and the second body block 320 through the open other end 312.

The first body block 310 may have a curvature whose tip is set to correspond to the shape of the inner diameter of the pipe (P).

The first body block 310 includes a pair of first low points (LP-1) facing each other in a first direction (L) and a pair of first low points (LP-1) facing each other in a second direction (H) different from the first direction (L). It may have the first high point (HP-1).

In one embodiment, the facing first high points (HP-1) are formed at the same height in the first direction (L), and the facing first low points (LP-1) are formed at the same height in the second direction (H). It can be formed to any height.

The height of the first high point (HP-1) may be placed at a higher position than the height of the first low point (LP-1), and the height of the first low point (LP-1) is from the first high point (HP-1) to the bottom. It can be placed at a designated distance away.

The section connecting the first high point (HP-1) and the first low point (LP-1) extends along the edge of the first body block 310 and may have a curved surface. The curved surface extending by connecting the first low point (LP-1) and the first high point (HP-1) is formed with a gentle slope, based on the center lines of the first direction (L) and the second direction (H). It can be formed symmetrically.

Referring to FIG. 1, the outer surface formed by the first high point (HP-1) and the first low point (LP-1) is that of the pipe (P) in contact when the filter block 300 is mounted on the pipe (P). It may be formed to have a curvature similar to the curvature of the inner peripheral surface. The first body block 310 has an outer surface formed by the first high point (HP-1) and the first low point (LP-1) that does not protrude from the inner peripheral surface of the pipe (P), but the filter network 330 has the first high point (HP-1) and the first low point (LP-1). Because it protrudes through the opening 311, the filter net 330 may protrude from the inner peripheral surface of the pipe (P).

In one embodiment, the first body block 310 may have one or more cutoff surfaces according to an upper contour formed by a pair of first high points (HP-1) and first low points (LP-1).

For example, it may have a first cutoff surface 310a extending along the outer edge of the first opening 311 and a second cutoff surface 310b having a different inclination from the first cutoff surface 310a. The first cutoff surface 310a may have a first inclination angle θ1 and the second cutoff surface 310b may have a second inclination angle θ2.

The first cutoff surface 310a may extend from the first opening 311, and the second cutoff surface 310b may extend from the boundary of the first cutoff surface 310a.

The first fluid F1 may flow along the outline formed by the first cut-off surface 310a and the second cut-off surface 310b. The first body block 310 can reduce the area where the first fluid F1 collides by forming a cut-off surface at one end. A portion of the first body block 310 protrudes from the inner diameter of the pipe P, but a cut-off surface can be formed on one side to guide the path through which fluid flows. The first fluid F1 may move smoothly in one direction along the bent surface formed by the first cut-off surface 310a and the second cut-off surface 310b. That is, the first fluid F1 may flow in one direction without being blocked at the end of the first body block 310.

The first body block 310 may have a surface on the inside of an end that contacts the filter net 330. Since the second body block 320 is inserted into the first body block 310, the edge of the first opening 311 may have an inner peripheral surface corresponding to the end shape of the second body block 320.

In one embodiment, the first body block 310 may have a first curvature R1 corresponding to the shape of the second body block 320 on the inside. Additionally, the first curvature R1 of the first body block 310 may be substantially the same as the curved surface formed by the filter network 330. Additionally, the first curvature R1 may be equal to the curvature formed by the tip of the second body block 320.

The second body block 320 may include a second opening 322 and a supporter 323. In detail, the second body block 320 is disposed inside the second opening 322 and a second opening 322 disposed along the center, and a supporter 323 having a curvature along the filter net 330 at the end. It can be further provided. Additionally, the second body block 320 may include a first body portion 321a, a second body portion 321b, and a flange 321c.

The first body portion 321a extends to a preset length and may have an empty space inside facing the inserter 200. The first body portion 321a is connected to the second body portion 321b disposed in the front, and a flange 321c may be formed along the outer peripheral surface of the first body portion 321a. The diameter of the first body portion 321a is smaller than the diameter of the flange 321c and larger than the diameter of the second body portion 321b.

The second body portion 321b extends to a preset length and may have an outer diameter d2 that is smaller than the inner diameter of the first body block 310. The first body block 310 may be formed to be equal to or slightly larger than the outer diameter d2 of the inserted second body portion 321b. Accordingly, the second body portion 321b may be inserted into the first body block 310.

The flange 321c is connected to the first body portion 321a and may extend in the radial direction. The flange 321c partitions the front and rear sides between the second body block 320 and the inserter 200, so that the first fluid F1 and the second fluid F2 are mixed in the base body 100. can be prevented.

The second body block 320 may have a pair of second high points (HP-2) and a pair of second low points (LP-2) disposed at set positions.

In detail, the second body portion 321b has a pair of second low points (LP-2) facing each other in the first direction (L) and a pair of second low points (LP-2) facing each other in a second direction (H) different from the first direction (L). There may be a pair of second highs (HP-2).

For example, the positions of the second low point (LP-2) and the second high point (HP-2) of the second body block 320 are the positions of the first low point (LP-1) and the second high point (HP-2) of the first body block 310. 1 It can be placed to correspond to the high point (HP-1). The second body portion 321b has a second low point (LP-2) aligned to correspond to a pair of first low points (LP-1), and a second low point (LP-2) aligned to correspond to a pair of first high points (HP-1). There may be a second high point (HP-2).

The tip of the second body block 320 may have a curved surface defined by the second high point (HP-2) and the second low point (LP-2). The curved surface extending by connecting the second low point (LP-2) and the second high point (HP-2) is substantially similar to the curved surface extending by connecting the first low point (LP-1) and the second high point (HP-2). can be formed in the same way.

When the first body block 310 is assembled to the second body block 320, the first low point (LP-1) is inserted into the second low point (LP-2), and the first high point (HP-1) is It can be inserted at the second high point (HP-2).

The second opening 322 may be disposed inside the second body block 320. The first fluid F1 may move to the inserter 200 through the second opening 322. The second opening 322 may be disposed inside the first body 321a and the second body 321b to connect the insides of the first body 321a and the second body 321b.

For example, the second opening 322 may have a predetermined level difference in the internal space depending on the diameters of the first body portion 321a and the second body portion 321b. The inner space of the second opening 322 may be partitioned along the boundary between the first body portion 321a and the second body portion 321b.

The supporter 323 may be disposed in the second opening 322. The supporter 323 is disposed on the second body block 320 to maintain the shape of the filter network 330. The supporter 323 may have a curvature corresponding to the curved surface of the filter network 330. The supporter 323 may protrude from the first opening 311. An end of the supporter 323 is exposed from the second body block 320, and a filter net 330 may be disposed on the end.

In one embodiment, a supporter 323 extending perpendicular to the first axis AX1 may be disposed inside the second opening 322.

For example, the supporter 323 may be installed in the shape of one or more partitions inside the second opening 322. The supporter 323 may maintain a predetermined distance within the second opening 322.

The supporter 323 may extend in the same longitudinal direction of the second body portion 321b, but may be provided such that its tip protrudes beyond the second low point LP-2. For example, the highest point of the end of the supporter 323 may be set to be higher than the second low point (LP-2) and lower than or substantially equal to the second high point (HP-2).

The tip of the supporter 323 may be set to a second radius of curvature (R2), and the second curvature (R2) may be set to a radius of curvature corresponding to the curved surface of the filter network 330. The extent to which the filter network 330 protrudes from the first opening 311 can be adjusted depending on the radius of curvature of the supporter 323.

The filter net 330 is seated on the upper part of the supporter 323, and the filter net 330 can be supported by the supporter 323. Since the supporter 323 is provided in the shape of a partition with a curvature at the tip, the filter net 330 mounted on the supporter 323 may have a shape with a convex curvature along the tip of the supporter 323. That is, since the shape of the supporter 323 protrudes convexly, the filter net 330 may protrude convexly.

Since the end of the supporter 323 supports the filter net 330, the filter net 330 can be maintained in a protruding state. Even if the flow rate or hydraulic pressure of the first fluid F1 is strong, the supporter 323 supports the filter net 330, so the filter net 330 can continuously maintain the protruding state.

In one embodiment, the supporter 323 may be disposed inside the second body portion 321b. The supporter 323 may be disposed only in the second opening 322 disposed inside the second body portion 321b.

In one embodiment, at least one supporter 323 may have a cut groove 323a. The cut groove 323a is disposed at a portion where the first body portion 321a and the second body portion 321b are connected, and the through hole 323H between the first body portion 321a and the second body portion 321b. ) can be placed adjacent to. The through hole 323H allows the first fluid F1 flowing into the first body 321a to move to the second body 321b, and the cut groove 323a allows the first fluid F1 to flow through the through hole 323H. The fluid can be guided to be distributed into the gap between the supports 323.

The cutting groove 323a may have an inclined structure on both sides. One side of the cutting groove 323a may have a third inclination angle θ3, and the other side of the cutting groove 323a may have a fourth inclination angle θ4. The inclined structure may have a structure in which the inclined angle becomes smaller toward the top of the second body portion 321b and the other end is open. Accordingly, the fluid may pass through the second body portion 321b and be discharged toward the internal space of the first body portion 321a at a set inclination angle.

The first body block 310 may be inserted into the end of the second body block 320 along the first axis AX1. In one embodiment, the second body block 320 has a step, so that the first body block 310 can be inserted into the second body block 320.

When the filter block 300 is assembled, the supporter 323 may protrude from the first opening 311. The supporter 323 may have a curvature to support the filter net 330 so that the filter net 330 protrudes from the first opening 311.

The filter network 330 may be provided with a structure having a plurality of ventilation holes through which fluid communicates on the front surface. For example, the filter network 330 may be formed in a mesh shape. Additionally, the filter net 330 may be formed of a rigid material such as stainless steel or coated iron.

The filter network 330 is disposed between the first body block 310 and the second body block 320, and may protrude from the first opening 311. The filter net 330 is disposed in contact with the inner surface of the first body block 310 and may be supported by the second body block 320.

In detail, the edge of the filter network 330 may be supported on the inner surface of the first body block 310. The edge of the filter network 330 is supported on the surface connecting the first high point (HP-1) and the first low point (LP-1) of the first body block 310, and the edge of the first body block 310 1 It may have a shape corresponding to the curvature (R1).

Additionally, the edge of the filter network 330 may be supported by the tip of the second body block 320. The edge of the filter network 330 may be supported on a surface connecting the second high point (HP-2) and the second low point (LP-2) of the second body block 320.

The filter network 330 may be provided with a curvature such that at least a portion protrudes from the first opening 311. The filter network 330 may have a radius of curvature such that it protrudes between the first low point (LP-1) and the first high point (HP-1).

The filter block 300 may be placed inside a pipe P through which fluid flows in one direction. At this time, the filter net 330 is disposed in the path through which fluid flows into the nozzle assembly 10, and can filter foreign substances in the fluid flowing into the nozzle assembly 10.

Figure 7 is a perspective view of a portion of the filter block shown in Figure 3 cut away.

Referring to FIG. 7, the filter block 300 may have a guide groove 341 and a guide protrusion 342 to facilitate alignment and assembly.

In the filter block 300, the other of the first body block 310 and the second body block 320 may be provided with the other one of the guide groove 341 and the guide protrusion 342 disposed on the outer surface. The drawings show an embodiment in which guide grooves are disposed on the outer peripheral surfaces of the first body block 310 and the second body block 320, and guide protrusions are disposed at positions where the guide grooves are inserted, but the guide groove is not limited thereto. The positions of the grooves and protrusions may be mutually changed.

The filter block 300 may be assembled along the first axis AX1 into the first body block 310, the filter network 330, and the second body block 320 in that order. At this time, the other of the first body block 310 and the second body block 320 may be provided with the other one of the guide groove 341 and the guide protrusion 342 disposed on the outer surface.

The guide groove 341 may have a shape corresponding to the guide protrusion 342 so that the guide protrusion 342 is inserted. For example, the guide groove 341 may be disposed on the inner peripheral surface of the first body block 310, and the second guide protrusion 342b of the second body block 320 may be inserted.

The guide protrusion 342 protrudes so as to be coupled to the guide groove 341, and the first body block 310 and the second body block 320 can move along the guide groove 341.

As an example, a guide groove 341 may be disposed on the first body block 310 and a guide protrusion 342 may be disposed on the second body block 320. Additionally, a guide protrusion 342 may be further included on the outer surface of the first body block 310.

The guide groove 341 and the guide protrusion 342 may form a path to prevent the second body block 320 from being incorrectly inserted into the first body block 310 .

In another embodiment, a plurality of guide protrusions 342 may be provided on the first body block 310 and the second body block 320. The guide protrusion 342 may be formed to protrude from one surface of the first body block 310 and the second body block 320.

Referring to FIGS. 5 and 7 , a first guide protrusion 342a and a second guide protrusion 342b are formed on the second body block 320, and a third guide protrusion 342c is formed on the first body block 310. ) can be formed.

The first guide protrusion 342a and the third guide protrusion 342c may be inserted into a groove (not shown) formed on the inner peripheral surface of the pipe P. The second guide protrusion 342b is inserted into the guide groove 341.

The first body block 310 can be inserted into the second body block 320 without being separated by the second guide protrusion 342b inserted into the guide groove 341. Likewise, the filter block 300 can be inserted into the pipe (P) without being separated by the first guide protrusion (342a) and the third guide protrusion (342c) inserted into the groove of the pipe (P). That is, the first body block 310 and the second body block 320 are aligned and coupled by the second guide protrusion 342b, and the combined filter block 300 is aligned with the first guide protrusion 342a and the third guide protrusion 342a. It can be aligned and mounted by the guide protrusion 342c.

FIG. 8 is a diagram showing the operation of the nozzle assembly of FIG. 1, and FIG. 9 is a perspective view showing a state in which a filter block is mounted on the nozzle assembly of FIG. 1.

The injection system to which the nozzle assembly 10 is applied stores the first fluid F1 in a reservoir, and the first fluid F1 can automatically move along the supply line and then be injected. Even if the injection system does not have a separate additional supply device such as a pump, when the second fluid F2 is injected from the nozzle assembly 10 by a compressor, the first fluid F1 can move.

The nozzle assembly 10 according to the present invention can remove internal foreign substances contained in the first fluid F1. The filter block 300 is disposed between the inserter 200 and the pipe (P) and can filter out foreign substances remaining in the first fluid (F1). The filter block 300 may remove foreign substances contained in the first fluid F1 before the first fluid F1 flows into the inserter 200.

Referring to Figures 1 and 8, the first body block 310 is arranged to protrude from the side of the pipe P, and the second body block 320 can be arranged so that the other end faces the inserter 200. there is. The inserter 200 is mounted on the outlet of the base body 100 and guides fluid to flow in one direction.

The first fluid (F1) flows along the flow path of the adjacent pipe (P) connected to the base body 100, and the filter block 300 is installed so as to be located on the flow path through which the first fluid (F1) flows, Fluid F1 may flow into the nozzle assembly 10.

The nozzle assembly 10 can spray the first fluid F1 from which foreign substances have been removed, and at the same time, it can effectively remove foreign substances adhering to the filter block 300.

The filter block 300 is disposed at a branched position from the pipe P and can allow the first fluid F1 to flow into the nozzle assembly 10 . At this time, the filter network 330 of the filter block 300 may filter foreign substances in the first fluid F1.

Since the filter net 330 protrudes from the inner peripheral surface of the pipe (P), the filter net 330 allows the first fluid (F1) to pass through the nozzle assembly 10 and at the same time removes foreign substances remaining in the filter net 330. 1 Can be cleaned by fluid (F1).

The filter network 330 is supported by the supporter 323 and may protrude from the opening of the first body block 310 by the supporter 323. Since the filter net 330 protrudes from the inner peripheral surface of the pipe P, the first fluid F1 moving along the pipe P can remove foreign substances deposited on the filter net 330.

The end of the filter block 300 is set to be substantially the same as the inner diameter shape of the pipe P, so that it does not interfere with the flow of fluid flowing in other directions. In detail, one end of the first body block 310 may have a cutoff surface connected to the first opening 311. The cutoff surface extending from the first opening 311 may be formed of, for example, one or more bent surfaces. The first cutoff surface 310a may be bent at an angle so as not to impede the flow of the first fluid F1. The second cutoff surface 310b may be formed to naturally flow along the flow direction of the first fluid F1 by forming a curved surface extending from the first cutoff surface 310a.

The first fluid F1 moving along the pipe P does not receive resistance from the first body block 310, but only receives resistance from the protruding filter net 330. The first fluid F1 flows into the nozzle assembly 10 without resistance, and can effectively clean the protruding filter net 330.

The filter network 330 can be maintained in a protruding state by the supporter 323. Since the filter net 330 is supported on the supporter 323 of the second body block 320, the filter net 330 can be maintained in a protruding state without being deformed even if the hydraulic pressure or flow rate of the first fluid F1 is high. there is.

As such, the present invention has been described with reference to the embodiments shown in the drawings, but these are merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. . Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached claims.

10: Nozzle assembly
100: Base body
200: inserter
300: Filter block
310: first body block
320: second body block
330: filter network

Claims (5)

a storage tank storing the first fluid;
a pipe through which the first fluid moves from the reservoir; and
Includes a nozzle assembly mounted on the pipe,
The nozzle assembly is
base body; and
an inserter inserted into the base body; and
A filter block is inserted into the base body so that one end faces the inserter and has a filter net protruding from the inner peripheral surface of the pipe at the other end,
The filter block is,
The other end has a pair of first low points facing each other in a first direction and a pair of first high points facing each other in a second direction different from the first direction, and connects the first low point and the first high point. So it was extended,
The filter network is
An injection system protruding between the first low point and the first high point. According to claim 1,
The filter block is,
The other end has a predetermined curvature to correspond to the inner diameter shape of the pipe, and is disposed on a flow path through which the first fluid flows. delete According to claim 1,
The filter network is supported on a surface connecting the pair of first high points and the pair of first low points of the filter block. According to claim 1,
The filter block is
An injection system having a curvature corresponding to the curved surface of the filter network and including at least one supporter supporting the filter network.

Images