KR101933872B1 - Rotary injection device - Google Patents

Abstract

The present invention adjusts the injection angle of the injection nozzle of the rotary nozzle unit and allows the selection of the angle of bending of the injection nozzle, thereby adjusting the rotational speed of the rotary nozzle unit to adjust the intensity of wind through the wing, And the control of the length of the moving part of the windshield, the fluid can be injected in the form of molecules or fine particles farther to the desired position, and the fluid spraying range in the front, rear, left and right directions can be spread more widely, And more particularly to a rotary injection device capable of maximizing the economy.

Description

Rotary injection device

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a rotary injection device, and more particularly, to a rotary injection device capable of injecting a fluid such as agricultural chemicals or agricultural water into a molecule or a particulate form farther The present invention relates to a rotary spraying apparatus capable of increasing the efficiency of fluid spraying through one spraying sprayer by spreading the fluid spraying range in the forward, backward, leftward and rightward directions more widely by controlling the spraying angle, the spraying distance and the rotating speed.

Generally, in the process of cultivating crops such as fruit juice, rice, radish and cabbage, fluids such as agricultural water and pesticides are appropriately used in order to grow crops robustly in order to promote growth of crops and overcome various insect pests. Is generally sprayed through a sprayer, which is disclosed in the prior art.

However, prior art sprayers have a disadvantage in that the spray is sprayed in the front, rear, left, and right directions from the rotation of the fluid spray tube, and this spray gun requires a lot of fuel use when spraying the fluid.

On the other hand, Japanese Patent Application Laid-Open No. 2011-220644 discloses a technique of an agricultural chemical spraying and dispensing apparatus capable of spreading agrochemicals more widely in the longitudinal and lateral directions without using any separate power due to rotation of the nozzle assembly by spray pressure repulsive force , The above-described technique has disadvantages in that it is impossible to adjust the angle of rotation of the rotary blades or the angle of spreading of the blades because the angle of the nozzle can not be controlled and the spraying angle can not be adjusted.

Korean Registered Utility Model No. 20-0474950 Japanese Laid-Open Patent Publication No. 2011-220644 Korean Patent Registration No. 10-1718797 Korean Patent Registration No. 10-1604412

The present invention adjusts the injection angle of the injection nozzle of the rotary nozzle unit and allows the selection of the angle of bending of the injection nozzle, thereby adjusting the rotational speed of the rotary nozzle unit to adjust the intensity of wind through the wing, And the control of the length of the moving part of the windshield, the fluid can be injected in the form of molecules or fine particles farther to the desired position, and the fluid spraying range in the front, rear, left and right directions can be spread more widely, The purpose is to maximize economic efficiency.

The spraying apparatus of the present invention for achieving the above object is provided with a nozzle branching part 12 which rotates together with a central axis tube 11 and a nozzle branching part 12 whose one end is connected to the nozzle branching part 12 in a radial direction perpendicular to the central axis tube 11 A plurality of branch nozzle pipes 13 integrally joined to supply the fluid supplied from the central shaft tube 11 to the nozzle angle member 15, and a plurality of branch nozzle tubes 13 having an inlet side and an outlet side, A nozzle angle member 15 having an inlet side connected to the other end of the nozzle angle member 15 and formed with a bent angle so as to generate a rotational power by a spray pressure repulsive force of the fluid supplied from the branch nozzle channel 13, (10) having a spray nozzle (14) connected to the side of the spray nozzle to disperse the fluid; A rotary blade 20 inserted into the central shaft tube 11 and coupled with the rotary nozzle unit 10 to receive a rotational force to strongly advance and disperse the fluid sprayed from the spray nozzle 14; And a bearing part 30 having one side connected to the fluid supply pipe 40 and the center axial tube 11 of the branch nozzle tube 13 inserted into the other side.

 The plurality of branch nozzle tubes 13 are connected to the nozzle branch 12 so as to be spread radially at the same height and are connected to the spray nozzle 14 at the other end. Is formed to have a bending angle b by the L-shaped nozzle housing 15f

 The nozzle angle member 15 includes an injection angle control pipe 15a having one end coupled to the other end of the branch nozzle pipe 13 and an L-shaped pipe, one end of which is connected to the other end of the injection angle control pipe 15a And a nozzle housing 15f to which the spray nozzle 14 is coupled. The O-ring 15d and the cylindrical bushing 15f are coupled to the spray angle control pipe 15a and the nozzle housing 15f, 15e, and an O-ring 15d.

The bending angle b of the nozzle angle member 15 may be 100 +/- 2.5 deg., 110 +/- 2.5 deg., 120 deg. 2.5 deg., Or 130 deg. 2.5 deg.

 A cylindrical stopper hole 15a 'opened to the nozzle housing 15f is integrally formed on one side of the outer circumferential surface of the injection angle control pipe 15a. Springs 15b and 15b are formed in the stopper hole 15a' A plurality of stopper grooves 15fc are formed in the inside of the flange 15fd formed at one end of the nozzle housing 15f facing the stopper hole 15a ' When the tube 15a and the nozzle housing 15f are inserted into the other end of the branch nozzle tube 13 and are coupled by the snap ring 15g, the stopper 15c is pushed out by the expanding elastic force of the spring 15b One end of the pusher stopper 15c is caught by the stopper groove 15fc formed in the inside of the nozzle housing 15f to maintain the angle and the rotation of the nozzle housing 15f causes the rotation of the nozzle angle member 15 And the injection angle c can be adjusted.

The injection angle c is adjustable within a range of 30 to 60 degrees in a direction opposite to the rotational direction a.

In addition, the rotary vane 20 includes a plurality of vanes 24 having bolt holes 24a at one side thereof; A wing engagement portion (22) formed with a plurality of bolt holes (22c) for engaging the plurality of vanes (24) on a donut shaped plate; And a bolt 22b and a nut 22a that are engaged with the vanes 24 and the bolt holes 24a and 22c formed in the vane coupling portion 22 in a coincident manner.

 The bearing portion 30 is a pipe-shaped bearing body 30a having a circular inner shape, a hexagonal upper portion and a thread on the outer peripheral surface of the lower portion. A spacer 30c inserted into the bearing tube 30a in a circular pipe shape to penetrate and support the central shaft tube 11 of the rotary nozzle unit 10 inward; An upper bearing 30b and a lower bearing 30d which are housed in the bearing tube 30a and respectively located at the upper and lower ends of the spacer 30c; A snap ring 30e located at the lower end of the lower bearing 30d; An oil seal 30f inserted under the inner retaining ring 30e of the bearing tubular body 30a to prevent leakage of fluid between the bearing tubular body 30a and the central shaft tube 11; The inside of the upper end portion is formed with a thread and is screwed with the thread of the outer circumferential surface of the lower portion of the bearing tube body 30a, and a circular flange shape is integrally formed on the outer circumferential surface of the lower portion. A connecting member 30h; And an O-ring 30j on the outer peripheral surface of the lower end of the connecting member 30h.

5 to 7, the rotary spraying apparatus of the present invention includes a cylindrical windshield 50 that surrounds the rotary nozzle unit 10 and the rotary vane 20 so as to spray the fluid in one direction .

6, the windshield 50 includes a plurality of bolt holes 51aa formed in a bottom plate 51a and a plurality of bolt holes 51b formed in a connecting member 30h coupled to a lower end of the bearing portion 30 30ha) and are joined by bolts and nuts (30g, 30i).

The windshield 50 may be formed to have a circular tube-shaped movable part 57 inserted into the cylindrical fixing part 56 as shown in FIG. 7 to adjust its length, 50 are formed in the cylindrical portion of the fixed portion 51 and the movable portion 52 such that a plurality of through holes are formed on the outer circumferential surface of the cylindrical portion in a predetermined size and the movable portion 52 is pivoted about the fixed portion 51, .

 A plurality of ventilation holes 51b are formed in the bottom plate 51a of the fixing portions 51 and 56 to adjust the amount of air to be sucked and a ventilation opening and closing plate 51c for opening and closing the ventilation holes is provided .

As shown in FIG. 6, the ventilation opening / closing plate 51c is coupled to an end of the opening / closing lever 55, which is integrally formed on the lower side of the ventilation opening / closing plate 51c, So as to be opened and closed. The movable portion 52 is pivoted about the fixed portion 51 so that the movable fixed hole 52a of the movable portion 52 is positioned at the open position 51aga or the closed position 51agb of the movable adjustment hole 51ag And is formed so as to open and close by rotating with a butterfly bolt nut 54 or an actuator.

As described above, according to the present invention, it is expected that the spraying range of the pesticide can be widened or concentrated by spray pressure repelling force to increase the efficiency of spraying the pesticide through one rotary spraying apparatus. The purpose of the present invention is to provide a rotary injection device capable of controlling the rotation speed by changing the injection angle, the height of the windshield and the amount of ventilation by changing the injection angle adjusting pipe having various angles, It is.

FIG. 1 is a perspective view of a rotary spray apparatus according to an embodiment of the present invention.
2 is a plan view and a cross-sectional view showing the structure of a rotary injection apparatus according to an embodiment of the present invention.
3 is an exploded perspective view showing the structure of a rotary injection apparatus according to an embodiment of the present invention.
4 is an enlarged exploded view showing the structure of a nozzle angle member according to an embodiment of the present invention.
FIG. 5 is a perspective view of a combined perspective view showing a windshield structure of a rotary injection apparatus according to an embodiment of the present invention.
6 is an exploded perspective view showing a windshield structure of a rotary injection apparatus according to an embodiment of the present invention.
7 is a perspective view showing the operation of adjusting the height of the windshield of the rotary injector according to the embodiment of the present invention.
8 is a perspective view showing a structure of a rotating nozzle unit and a rotating blade unit according to an embodiment of the present invention.
9 is an enlarged exploded view showing another structure of the nozzle angle member of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, preferred embodiments of a rotary injection apparatus according to the present invention will be described in detail with reference to the drawings.

The present invention can be embodied in various forms and is not limited to the embodiments described below.

Hereinafter, for the purpose of clearly illustrating the present invention, a detailed description of parts that are not closely related to the present invention is omitted, and the same or similar components are denoted by the same reference numerals throughout the entire description of the present invention, .

1 to 4, the rotary injection apparatus according to an embodiment of the present invention includes a rotary nozzle unit 10, a rotary blade unit 20, and a bearing unit 30.

 The rotary nozzle unit 10 includes a nozzle branching unit 12 that rotates together with the central axis tube 11 and a nozzle branching unit 12 that has one end integrally coupled with the nozzle branching unit 12 in a radial direction perpendicular to the central axis tube 11. [ A plurality of branch nozzle tubes 13 for feeding the fluid supplied from the central shaft tube 11 to the nozzle angle member 15 and having an inlet side and an outlet side in the form of a tube, A nozzle angle member 15 to which an inlet side is connected and in which a bent angle is formed such that a fluid supplied from the branch nozzle pipe 13 generates a rotational power by a spray pressure repulsive force is connected to an outlet side of the nozzle angle member 15 And a spray nozzle (14) for dispersing the fluid.

 The central axial pipe 11 and the branch nozzle pipe 13 have a shape of an engagement structure of an umbrella and an umbrella when the umbrella is unfolded as shown in Fig. A hexagonal nut-shaped rotary vane coupling portion 11a having a plurality of bolt holes 11b is formed on the outer circumferential surface of the central shaft tube 11 so as to be coupled with the vane coupling portion 22, The branch nozzle portion 12 is integrally formed on the upper side, that is, the upper end of the central axis tube 11. The branch nozzle portion 12 has a tubular shape with a closed end, a circular or polygonal outer peripheral surface, and a plurality of branch nozzle tubes 13 integrally formed radially on the outer peripheral surface.

The rotary vane 20 is inserted outside the central shaft tube 11 and coupled with the rotary nozzle unit 10 to receive a rotational force to strongly advance and disperse the fluid sprayed from the spray nozzle 14. The coupling between the rotary nozzle unit 10 and the rotary vane 20 is formed by a coupling hole 22e formed in the rotary nozzle coupling pin 22d formed on the vane coupling unit 22 and a coupling hole 22d formed in the rotary vane coupling unit 11a The rotary nozzle unit 10 and the rotary blade unit 20 interlock with each other and rotate by being fixed by the coupling bolt 22f in agreement with the bolt hole 11b.

As shown in FIG. 4, a plurality of branch nozzle tubes 13 are connected at one end to the nozzle branch 12 so as to be spread radially at the same height, and the other end is connected to the spray nozzle 14, And a retaining groove 13b is formed at an end portion thereof to engage the snap ring 15g with the snap ring groove 13b after the nozzle angle member 15 is inserted and coupled. The nozzle angle member 15 is formed to have a bending angle b by an L-shaped nozzle housing 15f.

 The nozzle angle member 15 includes an injection angle control pipe 15a having one end coupled to the other end of the branch nozzle pipe 13 and an L-shaped pipe, one end of which is connected to the other end of the injection angle control pipe 15a And a nozzle housing 15f to which the spray nozzle 14 is coupled and the other end of which is coupled to the nozzle housing 15f. An O-ring 15d, a cylindrical bushing 15d, (15e), and an O-ring (15d). A fluid hole 15ea is formed on one side of the outer circumferential surface of the cylindrical bushing 15e and the fluid hole 15ea is coupled so as to coincide with the fluid hole 13a formed in the branch nozzle tube 13, do.

In addition, the bending angle b of the nozzle angle member 15 may be any one of 100 ± 2.5 °, 110 ± 2.5 °, 120 ± 2.5 °, and 130 ± 2.5 °. As described above, since the injection angle adjusting pipe 15a can adjust the direction of spraying according to the bending angle b, there is an advantage that the spray angle adjusting pipe 15a can be selectively used according to crops or disaster prevention objects.

 4, a cylindrical stopper hole 15a 'opened to the nozzle housing 15f is integrally formed on one side of the outer circumferential surface of the injection angle control tube 15a, and the stopper hole 15a' A stopper groove 15fc is inserted in the flange 15fd formed at one end of the nozzle housing 15f facing the stopper hole 15a 'in the order of a spring 15b and a stopper 15c, When the injection angle adjusting pipe 15a and the nozzle housing 15f are inserted into the other end of the branch nozzle pipe 13 and are coupled by the snap ring 15g, The stopper 15c is pushed out and one end of the pushed stopper 15c is caught in the stopper groove 15fc formed in the inside of the nozzle housing 15f to maintain the angle and the rotation of the nozzle housing 15f And the injection angle c of the nozzle angle member 15 can be adjusted. The spray angle adjusting pipe 15a is fitted in the branch nozzle pipe 13 and is fixed by the fixing bolt 15ab. In the hole on the outlet side of the L-shaped nozzle housing 15f, Lt; / RTI >

The injection angle adjusting pipe 15a is fixed to the branch nozzle tube 13 by the fixing bolt 15ab and the nozzle housing 15f coupled by the snap ring 15g is rotatable so that the injection angle c . The injection angle c is adjustable within a range of 30 to 60 degrees in a direction opposite to the rotational direction a. Conventionally, only a fixed angle can be obtained. However, the present invention has an advantage that the rotation speed can be adjusted by adjusting the angle.

As shown in FIG. 3, the rotary vane 20 includes a plurality of vanes 24 having bolt holes 22a at one side thereof; A wing engagement portion (22) formed with a plurality of bolt holes (24a) so that the plurality of vanes (24) can be coupled to a donut shaped plate; And a bolt 22b and a nut 22a which are engaged with the vanes 24 and the bolt holes 22d and 22c formed in the vane engaging portion 22 to be engaged with each other. Although the four blades 24 are formed at the same height in the drawing, two symmetrical blades may be formed at different heights from the other two blades. 8A, the blades 24 may be integrally formed in the branch nozzle tube 13, or the rotary blades 20 may be disposed in front of the rotary nozzle unit 10 as shown in FIG. 8B .

Also, in the present invention, as in 8c, the blade 24 and the blade coupling portion 22 may be integrally formed. Since the above-described structure reduces the number of parts, the manufacturing and assembling steps can be reduced, and the cost can be reduced.

9A, the injection angle control pipe 15a and the cylindrical bushing 15e may be integrally formed. The injection angle control pipe 15a, the cylindrical bushing 15e, And the branch nozzle tube 13 may be formed integrally with the branch nozzle tube 13. Since the above-described structure reduces the number of parts, the manufacturing and assembling steps can be reduced, and the cost can be reduced.

  As shown in FIG. 3, the bearing portion 30 is a pipe-shaped bearing body 30a having a circular shape in the inside, a hexagonal shape in the upper portion of the outer peripheral surface, and a thread in the outer peripheral surface in the lower portion thereof. A spacer 30c inserted into the bearing tube 30a in a circular pipe shape to penetrate and support the central shaft tube 11 of the rotary nozzle unit 10 inward; An upper bearing 30b and a lower bearing 30d which are housed in the bearing tube 30a and respectively located at the upper and lower ends of the spacer 30c; A snap ring 30e located at the lower end of the lower bearing 30d; An oil seal 30f inserted under the inner retaining ring 30e of the bearing tubular body 30a to prevent leakage of fluid between the bearing tubular body 30a and the central shaft tube 11; The inside of the upper end portion is formed with a thread and is screwed with the thread of the outer circumferential surface of the lower portion of the bearing tube body 30a, and a circular flange shape is integrally formed on the outer circumferential surface of the lower portion. A connecting member 30h; And an O-ring 30j on the outer peripheral surface of the lower end of the connecting member 30h.

On the outer circumferential surface of the pipe formed at the lower portion of the connecting member 30h, a thread is formed and threaded connection with the fluid supply pipe 40 is made. An O-ring 30j is inserted in the coupling portion to prevent leakage of the fluid.

5 to 7, the rotary injection apparatus of the present invention further comprises a cylindrical windshield 50 surrounding the rotary nozzle unit 10 and the rotary blade unit 20 so as to direct the fluid in one direction . The windshield of the present invention has the advantage and advantage of being able to control the size of the sprayed particles or to send away the fluid by concentrating or dispersing the direction of the fluid.

The windshield 50 includes a plurality of bolt holes 51a formed in a bottom plate 51a and a plurality of bolt holes 51b formed in a connecting member 30h coupled to a lower end of the bearing portion 30 shown in FIG. (30ha) and joined by bolts and nuts (30g, 30i).

In addition, as shown in FIG. 7, the windshield 50 is formed so as to be able to adjust the length thereof by inserting a circular tube-shaped movable part 57 into the cylindrical fixed part 56. The length adjustment as described above has an effect of controlling the ejection distance of the ejected fluid.

As shown in FIGS. 5 and 6, the windscreen 50 has a plurality of through holes formed in a cylindrical outer circumferential surface at a predetermined size, and the through-holes 50 are respectively formed in the stationary portion 51 and the movable portion 52, The movable part 52 is pivoted to the left and right about the pivot 51 so as to be opened and closed.

 As shown in FIGS. 5 to 6, a plurality of ventilation holes 51b are formed in the bottom plate 51a of the fixing portion 56 so as to adjust the amount of air to be sucked, and a ventilation opening / 51c.

5 to 6, the opening / closing lever 51c is integrally formed with the opening / closing lever 51c and the end of the opening / closing lever 55 is coupled to rotate the opening / However, it may be configured to be opened and closed by being pivoted by the linear movement of the actuator.

The movable portion 52 is pivoted about the fixed portion 51 so that the movable fixed hole 52a of the movable portion 52 is positioned at the open position 51aga or the closed position 51agb of the movable adjustment hole 51ag And is formed so as to open and close by rotating with a butterfly bolt nut 54 or an actuator.

The rotary spraying apparatus of the present invention can be used in a single fluid supply pipe (40) with a handle, or it can be mounted on a car body such as an SS sprayer, a truck, etc. in various ways.

Although the preferred embodiments of the rotary injection apparatus according to the present invention have been described above, the present invention is not limited thereto, but can be variously modified and embodied within the scope of the claims, the description of the invention and the accompanying drawings , Which are also within the scope of the present invention.

10: Rotating nozzle part
11: central shaft tube
11a: Combination of rotary wing portion
11b: Bolt hole
11c: Snap ring engagement groove
12:
13: Branch nozzle pipe
13a: fluid hole
13b: Retaining ring groove
14: Spray nozzle
15: nozzle angle member
15a: injection angle regulating tube
15ab: Fixing bolt
15a ': Stopper hole
15b: spring
15c: Stopper
15d: O ring
15e: Bushing
15ea: fluid hole
15f: nozzle housing
15fc: Stopper Home
15fd: Flange
15g: Snap ring
20:
22:
22a: nut
22b: Bolt
22c, 22d: bolt holes
22d: Rotary nozzle part Binding pin
22e: Coupling hole
22f: coupling bolt
23: wing body
24: wing
24a: Bolt hole
30: bearing part
30a: Bearing tube
30b: Upper bearing
30c: Spacer
30d: Lower bearing
30e: Snap ring
30f: oil seal
30ga: Bolt
30gb: nut
30h: connection member
30ha: Bolt hole
30i: nut
30j: O ring
40: fluid supply pipe
50: Windshield
51:
51a: bottom plate
51aa: Bolt hole
51ab: center hole
51ac: Vents
51ad: opening / closing lever support portion
51ae: opening / closing lever insertion hole
51af: support ring fixing hole
51ag: Operation adjustment hole
51aga: open position
51agb: Closed position
51b: Vents
51c: Ventilation opening / closing plate
51ca: Opening and closing levers
51d: Support ring
51db: Bolt
51da: Bolt hole
52:
52a: movable fixed hole
53: Long hole
54: Knob bolt nut
56:
57:

Claims (20)

A nozzle branching part 12 interlocked with the central axis tube 11 and integrally coupled with the nozzle branching part 12 in a radial direction perpendicular to the central axis tube 11 so as to extend from the central axis tube 11 A plurality of branch nozzle tubes 13 for supplying a fluid to be supplied to the nozzle angle member 15, an inlet side and an outlet side in the form of a tube, an inlet side connected to the other end of the branch nozzle tube 13, A nozzle angle member (15) having a bend angle so as to generate a rotational power by a spray pressure repulsive force, a spray nozzle (15) connected to the outlet side of the nozzle angle member (15) A rotary nozzle unit (10) having a nozzle (14);
A rotary blade 20 inserted into the central shaft tube 11 and coupled with the rotary nozzle unit 10 to receive a rotational force to strongly advance and disperse the fluid sprayed from the spray nozzle 14;
And a bearing part (30) having one side connected to the fluid supply pipe (40) and the other side inserted and coupled with the central shaft tube (11) of the branch nozzle tube (13)
The bearing portion 30 has a pipe shape, a bearing body 30a having a circular inside, an upper portion of a hexagonal shape on the outer peripheral surface, and a thread on an outer peripheral surface of the lower portion;
A spacer 30c inserted into the bearing tube 30a in a circular pipe shape to penetrate and support the central shaft tube 11 of the rotary nozzle unit 10 inward;
An upper bearing 30b and a lower bearing 30d which are housed in the bearing tube 30a and respectively located at the upper and lower ends of the spacer 30c;
A snap ring 30e located at the lower end of the lower bearing 30d;
An oil seal 30f inserted under the inner retaining ring 30e of the bearing tubular body 30a to prevent leakage of fluid between the bearing tubular body 30a and the central shaft tube 11;
The inside of the upper end portion is formed with a thread and is screwed with the thread of the outer circumferential surface of the lower portion of the bearing tube body 30a, and a circular flange shape is integrally formed on the outer circumferential surface of the lower portion. A connecting member 30h;
And an O-ring (30j) on an outer peripheral surface of a lower end of the connecting member (30h). The method according to claim 1,
The plurality of branch nozzle tubes 13 are connected at one end to the nozzle branch 12 to be spread radially at the same height and the other end is connected to the spray nozzle 14, And has a bending angle (b) by an L-shaped nozzle housing (15f). The method according to claim 1,
The nozzle angle member 15 includes an injection angle adjusting pipe 15a having one end coupled to the other end of the branch nozzle pipe 13, an L-shaped pipe having one end coupled to the other end of the injection angle adjusting pipe 15a And the other end thereof is constituted by a nozzle housing 15f to which the spray nozzle 14 is coupled and an O-ring 15d, a cylindrical bushing 15e, , And an O-ring (15d). The method of claim 3,
Wherein the bending angle (b) of the nozzle angle member (15) is 100 +/- 2.5 degrees, 110 +/- 2.5 degrees, 120 +/- 2.5 degrees, and 130 +/- 2.5 degrees. The method of claim 3,
A cylindrical stopper hole 15a 'opened to the nozzle housing 15f side is integrally formed on one side of the outer circumferential surface of the injection angle control pipe 15a and a spring 15b and a stopper 15b are formed in the stopper hole 15a' A plurality of stopper grooves 15fc are formed inside the flange 15fd formed at one end of the nozzle housing 15f facing the stopper hole 15a ' When the nozzle housing 15f and the nozzle housing 15f are inserted into the other end of the branch nozzle tube 13 and are engaged by the snap ring 15g, the stopper 15c is pushed out by the expanding elastic force of the spring 15b, One end of the stopper 15c is engaged with a stopper groove 15fc formed in the inside of the nozzle housing 15f to maintain the angle so that the spray angle of the nozzle angle member 15 (c) is adjustable. The method of claim 5,
Wherein the spray angle (c) is adjustable within a range of 30 to 60 degrees in a direction opposite to the rotational direction (a). The method according to claim 1,
The rotary blade unit 20 includes a plurality of blades 24 having bolt holes 24a at one side thereof;
A wing engagement portion (22) formed with a plurality of bolt holes (22c) for engaging the plurality of vanes (24) on a donut shaped plate;
And a bolt (22b) and a nut (22a) for coupling the vane (24) and the bolt holes (24a, 22c) formed in the vane coupling part (22a). delete The method according to claim 1,
Further comprising a cylindrical windshield (50) surrounding the rotating nozzle unit (10) and the rotating blade unit (20) so as to direct the fluid in one direction. The method of claim 9,
The windshield 50 is coincident with a plurality of bolt holes 51aa formed in the bottom plate 51a and a plurality of bolt holes 30ha formed in a connecting member 30h coupled to the lower end of the bearing portion 30, And nuts (30g, 30i). The method of claim 10,
Wherein the wind shield (50) has a circular tube-shaped movable part (57) inserted into the cylindrical fixing part (56) to adjust its length. The method of claim 10,
A plurality of through holes formed in a cylindrical outer circumferential surface of a predetermined size are formed in the fixed portion 51 and the movable portion 52 respectively and the movable portion 52 is moved in the left and right directions around the fixed portion 51 And is capable of being opened and closed. The method according to any one of claims 11 to 12,
The bottom plate (51a) of the fixing part is provided with a plurality of ventilation holes (51b) for adjusting the amount of air to be sucked and a ventilation opening / closing plate (51c) for opening and closing the ventilation opening Jetting device. 14. The method of claim 13,
The ventilation opening / closing plate 51c is coupled to an end of the opening / closing lever 55 integrally formed at the lower side of the ventilation opening / closing plate 51c and is opened / closed by being pivoted by the opening / closing lever 55 or the linear motion of the actuator . The method of claim 12,
The movable portion 52 is pivoted about the fixed portion 51 so that the movable fixed hole 52a of the movable portion 52 is positioned at the open position 51aga or the closed position 51agb of the movable adjustment hole 51ag And is turned by a butterfly bolt nut (54) or an actuator. The method of claim 7,
And the wing (24) is formed integrally with the branch nozzle pipe (13). The method of claim 7,
Characterized in that the rotary vane (20) is arranged in front of the rotary nozzle (10). The method of claim 7,
Wherein the blade (24) and the blade coupling portion (22) are integrally formed. The method of claim 3,
Wherein the injection angle adjusting pipe (15a) and the cylindrical bushing (15e) are integrally formed. The method of claim 3,
Wherein the injection angle adjusting pipe (15a) and the cylindrical bushing (15e) are formed integrally with the branch nozzle pipe (13).

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