KR101451842B1 - Water jet nozzle - Google Patents

Abstract

According to the present invention, a water jet nozzle includes: a body including an inner flow channel so as to supply and discharge fluid; and a rectifying unit which is formed in the shape of a plate or a pipe extended in the lengthwise direction of the inner flow channel and is installed in the middle of the inner flow channel. According to the present invention, the water jet nozzle discharges the fluid, which enters the inside thereof, with high pressure and, at the same time, maintains the flow of the fluid straight while the fluid supplied passes through the inside thereof. Therefore, the water jet nozzle can increase the straightness and pressure of the fluid discharged; and reduce noise and vibrations by preventing generation of vortex in the inside thereof.

Description

Water jet nozzle}

The present invention relates to a water jet nozzle, and more particularly, to a water jet nozzle capable of improving the straightness and discharge pressure of a discharged fluid by jetting a fluid supplied to the inside at a high pressure, .

A water jet cutting apparatus is a device for jetting high-density fluid through a nozzle to jet a high-density jet flow onto a workpiece to perform a high-precision machining operation. Specifically, the intensifier is a device for increasing the pressure introduced from the hydraulic pump up to 20 times and generating a pressure of about 4,000 to 6,000 kg / cm 2. The water jet cutting device is a device for increasing the pressure The nozzle, which mixes water and abrasives at a speed three times the speed of sound, is moved in the XY-axis, cutting the workpiece while the workpiece is fixed using the pressure. The waterjet cutting device is capable of cutting ultra-precise cutting of almost all kinds of materials, has a very small cutting error and can be cut variously according to the size of the product.

Such water jet cutting apparatuses have been increasing in demand due to the precision of the processing technology, and they are being used in a wide variety of applications such as processing and machining industries, automobile industry, stone and tile industry, aircraft industry, material processing industry, And so on.

At this time, the water jet nozzle has a narrow flow path discharged from the flow path through which the fluid flows, so that the discharge pressure may be higher than the pressure at which the fluid is supplied. When the sectional area of the internal flow path is narrowed, A vortex is generated and the straightness is lowered, thereby causing a problem that the pressure of the discharged fluid is lowered.

Further, when a vortex of the fluid is generated in the internal flow path, the straightness of the discharged fluid is also lowered, resulting in a problem that the accuracy of the machining operation is deteriorated. In addition, when a vortex is generated inside the water jet nozzle, noise and vibration are generated, which not only makes the working environment poor, but also causes a discharge direction of the fluid to fluctuate.

KR 10-0784464 B1

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems, and it is an object of the present invention to improve the straightness and pressure of discharged fluid by discharging the fluid introduced into the interior to a high pressure, Jet nozzle that is configured to be able to reduce noise and vibration by preventing the occurrence of vapors in the interior of the water jet nozzle.

According to an aspect of the present invention, there is provided a water jet nozzle comprising: a body having an internal flow path for supplying and discharging a fluid; And a rectifying unit formed in a plate or a tube shape extending along the longitudinal direction of the internal flow path and mounted to the internal flow path stop.

Wherein the internal flow path includes a supply flow path on a side where a fluid is supplied, an injection flow path on a side from which a fluid is discharged, and a rectification flow path through which the supply flow path and the injection flow path are communicated and the rectification unit is mounted, Wherein the flow path is formed to have a cross sectional area that is narrower than the supply flow path, the rectification flow path has a cross-sectional area larger than that of the supply flow path, the outer surface of the rectification unit is in close contact with the inner wall of the rectification flow path, Direction to be seated at both ends thereof.

The rectifying unit is composed of two or more rectilinear tubes extending in parallel to the flow direction of the fluid flowing in the inner flow path and coupled so that one outer surface is in close contact with the inner wall of the rectifying flow path.

The rectilinear tube is formed in a circular pipe shape, and is radially arranged around a center line of the rectification flow path.

The rectifying unit includes at least one transverse plate and a vertical plate extending in parallel to a flow direction of the fluid flowing in the inner flow path in the longitudinal direction and arranged so as to cross each other in the width direction.

Wherein the rectifying unit includes an outer tube whose outer surface is in close contact with the inner circumferential surface of the rectifying flow passage and an outer tube which is elongated in the flow direction of the fluid flowing through the inner flow passage and both ends in the width direction are located on the inner wall of the outer tube And at least three partition plates arranged radially.

The rectifying unit has a plurality of guide grooves extending along the direction of the fluid flow on the surface contacting the fluid.

The water jet nozzle according to the present invention is capable of improving the straightness and pressure of the discharged fluid by discharging the fluid introduced into the interior of the water jet nozzle at a high pressure and maintaining the straightness of the fluid while passing through the inside, The noise and vibration can be reduced.

1 and 2 are a perspective view and a bottom perspective view of a water jet nozzle according to the present invention.
3 and 4 are a front view and a plan view of a water jet nozzle according to the present invention.
5 and 6 are a cross-sectional perspective view and a cross-sectional view of a water jet nozzle according to the present invention.
7 is a disassembled cross-sectional view of a water jet nozzle according to the present invention.
8 and 9 show another embodiment of the rectifying unit included in the water jet nozzle according to the present invention.

Hereinafter, embodiments of a water jet nozzle according to the present invention will be described in detail with reference to the accompanying drawings.

FIGS. 3 and 4 are a front view and a plan view of a water jet nozzle according to the present invention, and FIGS. 5 and 6 are views showing a water jet nozzle according to the present invention, Fig. 7 is an exploded cross-sectional view of a water jet nozzle according to the present invention. Fig.

The water jet nozzle according to the present invention is an apparatus for cutting or machining a base material by linearly injecting a fluid supplied from the outside (more specifically, water mixed with an abrasive material) at a high pressure, and as shown in Figs. 1 to 4 As a basic component, a body 100 in which an internal flow path 110 is formed in one direction (in this embodiment, a vertical direction). In order to mount the water jet nozzle according to the present invention on other transportation equipment, the body 100 may have threads as shown in this embodiment, or other separate coupling units may be provided.

The inner passage 110 formed in the body 100 has a wide inlet and a narrow outlet so as to receive a large amount of fluid at one time and inject it at a high pressure. When the outlet of the inner passage 110 is formed to be narrower than the inlet A part of the fluid flowing into the internal flow path 110 may generate a vortex on the internal flow path 110 because the whole of the fluid flowing into the internal flow path 110 is not discharged sequentially to the outlet. When the vortex is generated on the inner passage 110, the velocity of the fluid flowing into the inner passage 110 is rapidly reduced and then discharged, so that the pressure of the discharged passage is reduced and the linearity is also lowered do.

5 and 6, the water jet nozzle according to the present invention is further provided with a rectifying unit 200 coupled to an end of the internal flow path 110, . The rectifying unit 200 includes a plurality of rectilinear tubes 210 extending along the longitudinal direction of the inner flow path 110 so that the fluid supplied to the inside of the body 100 does not vortify and is radially inward The flow direction of the fluid to flow in the direction of the flow path of the fluid 110).

In the absence of the rectifying unit 200 in the inner passage 110, a part of the fluid flowing into the inner passage 110 flows in the radial direction of the inner passage 110 or spirally rotates to generate a large vortex. The diameter of the flow path through which the fluid flows is small, so that even if a vortex is generated in the rectifying unit 200, only a small vortex is generated.

As described above, when the water jet nozzle having the rectifier unit 200 is used, the liquid flowing into the body 100 does not generate a large vortex and flows mostly straight along the rectifier unit 200, 100 can be remarkably reduced while the fluid introduced into the fluid chamber 100 is discharged to the outside, thereby increasing the discharge pressure of the fluid and improving the straightness. When the discharge pressure of the fluid increases, cutting and processing efficiency of the mother substrate is improved, and as the straightness of the fluid is improved, more precise processing becomes possible, which is advantageous in that the utilization is greatly expanded.

When the rectifier unit 200 is mounted in the inner passage 110 in a simple fitting manner, the inner passage 110 can be moved in the longitudinal direction by the pressure of the fluid supplied to the inner passage 110, It is preferable that the rectifying unit 200 is configured to be able to fix both longitudinal ends thereof. That is, the internal flow path 110 includes a supply path 112 on the side where the fluid is supplied, a spray path 116 on the side where the fluid is discharged, And a rectification flow path 114 in which the rectification unit 200 is mounted and the injection flow path 116 is formed to have a smaller cross sectional area than the supply flow path 112, The rectifying unit 200 is formed such that its outer surface is in close contact with the inner wall of the rectifying flow passage 114 and both longitudinal ends of the rectifying unit 200 are seated on both longitudinal ends of the rectifying unit 200 .

When both ends of the rectifying unit 200 in the longitudinal direction are coupled to both ends of the rectifying flow path 114 so that the pressure of the fluid supplied to the inside of the body 100 is applied to the rectifying unit 200, The flow path of the fluid passing through the inner flow path 110 can be guided more stably because the inner flow path 200 can be maintained not only in the width direction but also in the longitudinal direction. When the whole body 100 is integrally formed, the rectifier unit 200 can not be drawn into the rectification flow path 114, so that the body 100 is divided into a portion where the supply flow path 112 is formed and a rectification flow path 114 Are separately formed, and the rectifying unit 200 is inserted and then connected.

In order to minimize the flow rate reduction and minimize the generation of vortex while the fluid supplied to the inside of the inner flow path 110 is discharged to the outside, the inner surface of the inner flow path 110 must be smoothly processed. However, since the internal flow path 110 of the body 100 is usually manufactured through drilling and boring, there is a limit to reduce the roughness of the inner circumferential surface of the internal flow path 110. The water jet nozzle according to the present invention contacts most of the rectifier unit 200 while the fluid supplied to the inside of the body 100 is discharged to the outside so that the surface of the rectifier unit 200 is smoothly processed It has the advantage of minimizing the flow rate reduction and vortex occurrence mentioned. That is, since the rectifier unit 200 is manufactured separately from the body 100 and mounted inside the body 100, the surface of the rectifier unit 200 can be smoothly machined, The effect of improving the pressure and the straightness can be obtained.

Meanwhile, the linear tube 210 may be formed in a circular pipe shape as shown in the present embodiment, or may be formed in an elliptic pipe shape or a polygonal pipe shape. If the rectilinear tube 210 is formed in the shape of a polygonal pipe, the probability that a fluid vortex is generated at a corner portion of the rectilinear tube 210 is increased. Therefore, the rectilinear tube 210 is a pipe having no corners, It is preferable to select circular pipe or elliptical pipe as shown in the example.

The rectilinear tube 210 has a structure that is uniformly arranged at each part of the rectification flow path 114 so that the rectilinear tube 210 can maintain a constant linearity regardless of the flow direction of the fluid to the rectification flow path 114. That is, As shown in Fig. Although only three linear tubes 210 are arranged in this embodiment, the number of the linear tubes 210 can be changed to two or four or more.

As described above, if a plurality of linear tubes 210 are provided inside the rectification flow path 114, vortex generation is significantly reduced as compared with the case where the linear tubes 210 are not provided. However, according to various conditions, A slight eddy current may be generated in the inside of the casing 210 as well. Accordingly, in order to further improve the straightness of the fluid flowing inside the straight tube 210, the water jet nozzle according to the present invention is provided with a flow direction of the fluid on the inner side of the straight tube 210, A plurality of guide grooves 212 may be formed extending in the vertical direction (the up and down direction in this embodiment). When a plurality of guide grooves 212 are formed on the inner surface of the linear tube 210, the fluid flowing on the inner surface of the linear tube 210 does not flow spirally and flows in the longitudinal direction of the guide groove 212 As a result, the straightness of the fluid ejected to the outside is further improved.

The injection path 116 located at the outlet end of the internal flow path 110 is formed to have a significantly smaller diameter than the rectification flow path 114. The injection flow path 116 has a portion where the rectification flow path 114 and the injection path 116 are connected The fluid that has flowed through the straight pipe 210 enters the jetting passage 116 and collides against the right angled edge of the jetting passage 116. As a result, Or a vortex may be generated.

Therefore, a portion of the inner flow path 110, to which the rectification flow path 114 and the injection path 116 are connected, may be further provided with an inclined flow path 118 formed to be inclined in a direction in which the diameter becomes narrower downward. When the inclined flow path 118 is provided between the rectification flow path 114 and the injection path 116 as described above, since a right angle step is not formed between the rectification flow path 114 and the injection path 116, There is an advantage that the backflow of fluid or the generation of vortex is prevented during the flow of the fluid past the injection path 116. At this time, the inclination angle of the inclined passage 118 can be variously set according to the difference in diameter between the rectifying passage 114 and the injection passage 116 and the specification of each part, and thus a detailed description thereof will be omitted.

8 and 9 show another embodiment of the rectifying unit 200 included in the water jet nozzle according to the present invention.

5 to 7, the rectifying unit 200 is not limited to a structure in which a plurality of rectilinear tubes 210 are bundled, and the rectifying unit 200 may include a straight line Any structure can be substituted as long as it can be guided in the direction. 8, the rectifying unit 200 includes a plurality of rectifying units 200 extending in a longitudinal direction (vertical direction in this embodiment) parallel to the internal flow paths 110, And may include the horizontal plate 220 and the vertical plate 230 described above.

The transverse plate 220 and the transverse plate 230 are mounted such that both ends of the transverse plate 220 extend in the longitudinal direction of the rectification flow passage 114 and both ends of the transverse plate 220 are in close contact with the inner side surface of the rectification flow passage 114, So that it can be kept fixed. The fluid flowing into the rectification flow passage 114 flows to the injection flow passage 116 side along the transverse plate 220 and the vertical plate 230 so that the fluid can reach the injection flow passage 116 while maintaining the linearity without generating a vortex do.

The number of the transverse plates 220 and the number of the transverse plates 230 is not limited to the diameter of the rectifying flow passage 114, It can be changed to one or more depending on the size. The surfaces of the transverse plate 220 and the vertical plate 230 are directed toward the injection passage 116 so as to further improve the straightness of the fluid flowing along the surfaces of the transverse plate 220 and the transverse plate 230. [ A plurality of guide grooves 212 extending in a straight line may be formed. The shape and function of the guide groove 212 have been described in detail with reference to FIG. 7, and further description of the guide groove 212 will be omitted.

9, the outer surface of the rectifying unit 200 included in the present invention is in close contact with the inner circumferential surface of the rectifying flow path 114, An outer pipe 240 and a plurality of partition plates 250 for dividing the inner portion of the outer pipe 240 into a plurality of regions. The partition plate 250 is extended in the flow direction of the fluid flowing through the inner channel 110 so that both ends of the width direction are positioned at the center of the outer tube 240 and the inner wall of the outer tube 240, .

When the rectifier unit 200 is constituted by the outer tube 240 and the partition plate 250 as described above, since the entire outer surface of the outer tube 240 is in close contact with the inner surface of the rectification flow path 114, There is an advantage that it can be. The fluid introduced into the outer tube 240 is transferred to the injection path 116 through a narrow flow path divided into a plurality of partitioning plates 250. As in the embodiment shown in FIGS. 5 to 7, The effect of maintaining the straightness of the fluid until it is transmitted to the flow path 116 can be obtained.

In this embodiment, three partition plates 250 are mounted in the outer pipe 240, and the inner pipe 240 is divided into three parts with an interval of 120 degrees. However, The number may be increased or decreased by two or four or more depending on various conditions such as the size of the outer tube 240 and the characteristics of the fluid. 9, the inner surface of the outer tube 240 and the surface of the partition plate 250 may be provided with a plurality of guide grooves 240 on the inner surface of the outer tube 240 so as to further improve the straightness of the fluid flowing into the outer tube 240. [ (212) may be formed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention.

100: body 110: inner flow path
112: supply flow path 114: rectification flow path
116: jet passage 118: inclined passage
200: rectification unit 210: straight tube
212: guide groove 220:
230: vertical plate 240: outer tube
250: partition plate

Claims (7)

delete delete delete delete A body (100) having an internal flow path (110) so that fluid can be supplied and discharged;
A rectifying unit 200 formed in a shape of a plate or a tube extending along the longitudinal direction of the internal flow path 110 and installed in the interior of the internal flow path 110; / RTI >
The internal flow path 110 communicates the supply flow path 112 on the fluid supply side and the injection flow path 116 on the fluid discharge side and the supply flow path 112 and the injection flow path 116, And a rectification flow path (114) in which the rectification unit (200) is mounted,
The injection flow path 116 is formed to have a smaller sectional area than the supply flow path 112. The rectification flow path 114 is formed to have a cross sectional area wider than the supply flow path 112, And is connected to an inner wall of the rectifying flow path 114 so that both longitudinal ends of the rectifying flow path 114 are positioned at both longitudinal ends of the rectifying flow path 114,
The rectifying unit 200 includes at least one transverse plate 220 and a transverse plate 230 which are arranged so as to extend in parallel to the direction of flow of the fluid flowing in the internal flow path 110, And the water jet nozzle is configured so that the water jet nozzle can be rotated.
A body (100) having an internal flow path (110) so that fluid can be supplied and discharged;
A rectifying unit 200 formed in a shape of a plate or a tube extending along the longitudinal direction of the internal flow path 110 and installed in the interior of the internal flow path 110; / RTI >
The internal flow path 110 communicates the supply flow path 112 on the fluid supply side and the injection flow path 116 on the fluid discharge side and the supply flow path 112 and the injection flow path 116, And a rectification flow path (114) in which the rectification unit (200) is mounted,
The injection flow path 116 is formed to have a smaller sectional area than the supply flow path 112. The rectification flow path 114 is formed to have a cross sectional area wider than the supply flow path 112, And is connected to an inner wall of the rectifying flow path 114 so that both longitudinal ends of the rectifying flow path 114 are positioned at both longitudinal ends of the rectifying flow path 114,
The rectifying unit 200 includes an outer tube 240 whose outer surface is in close contact with the inner circumferential surface of the rectifying flow path 114 and an outer tube 240 extending in the flow direction of the fluid flowing through the inner path 110, And at least three partition plates (250) radially arranged to be positioned at the center of the outer tube (240) and the inner wall of the outer tube (240).
The method according to claim 5 or 6,
Wherein the rectifying unit (200) has a plurality of guide grooves (212) extending along a flow direction of the fluid on a surface contacting the fluid.

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