KR100905629B1 - Vibration-shock injection - Google Patents

Abstract

A vibration-shock injection device is provided to generate vibration and save discharged fluid by controlling pressure of water column and quickly converting the jet and pause of the water and varying pressure applied to a part in which water drop falls. A vibration-shock injection device comprises: a housing(10) which has an inner housing space and in which an inlet connected to a water pipe is formed at one side in order that water flows inside and in which an outlet(12a) discharging the flowed water is formed at the other side; a partition member(20) mounted inside the housing in order to partition the inner housing space of the housing into a first space and a second space; a rotary shaft(30) being mounted inside the partition member and being mounted with a first impeller(31) and a second impeller(32); a direction control member(40) mounted inside the partition member to control direction of the fluid jetting to the second impeller; and an opening and closing valve(50) being fixed to the rotary shaft to be rotatable and controlling the discharge of the fluid.

Description

Vibration Shock Injection Device {VIBRATION-SHOCK INJECTION}

The present invention relates to a vibration shock injection device, and more particularly, by adjusting the operating speed of the opening and closing valve using the first impeller and the second impeller mounted therein, it is possible to adjust the injection interval and the injection pressure of the ejected fluid. The present invention relates to a vibration shock injection device.

In general, the injector is directly connected to a water pipe in a shower booth, a sink, a sink, etc., or connected to a water pipe, and discharged in the form of a single stream or a multiple stream by manipulating a lever integrally attached to the spray unit in such a connection state. Provide a water supply environment that can be easily switched between states.

Briefly, the general structure of the injector includes a main body having an inner space in communication with a passageway through which water is introduced from a water pipe or a hose, and a first position for discharging water and a position covering the inner space in the main body; A discharge plate having a second discharge portion, a ball valve portion disposed in the inner space and two distribution flow passages corresponding to the two discharge portions selectively opened or closed by one ball member, and the ball valve portion A lever for controlling the operation.

Among the two discharge parts, the first discharge part has a single passage, and water is discharged in one branch through any one distribution channel of the ball valve part from the center of the discharge plate.

The second discharge part may be formed of a plurality of holes spaced apart from each other in a shape surrounding the passage of the first discharge part in the discharge plate, and through the other distribution flow path of the ball valve part through the respective holes. The water is discharged into the forks.

The first discharge portion and the second discharge portion are arranged in such a manner as to occupy space with each other in the discharge plate region, and in this state, water is supplied through the distribution passages of the valve portion to supply water. That is, since the valve part is in a state in which the other is opened in the state in which one of the two distribution flow paths is blocked by the ball member by the operation of the lever, the two discharge parts by the switching operation of such a lever. In response to this, water is selectively supplied and discharged.

However, the above-described conventional injector can selectively perform the case where the water is discharged in one branch and the case where the water is discharged in several branches, but it is limited in changing the discharge pressure of the discharged body of water or saving water. There is.

The object of the present invention devised in view of the above point is to control the pressure of the water stream to be ejected and at the same time to quickly switch the spraying and stopping of the water so that the vibration is generated while the pressure applied to the drop portion is changed To provide a vibration shock injection device.

Still another object of the present invention is to provide a vibrating shock injection device capable of saving the discharged fluid.

Vibration shock injection device for achieving the object of the present invention as described above is formed on one side of the inlet is connected to the water pipe and the other side the discharge port is formed; A partition member mounted in the inner accommodating space of the housing and partitioning the inner accommodating space into a first space and a second space and having a connection passage connecting the first space and the second space; A rotating shaft rotatably fixed through the partition member; A first impeller positioned in the first space and having a rotational force generated by the fluid introduced through the inlet and mounted at one end of the rotation shaft; A second impeller positioned in the second space and generating rotational force by the fluid flowing into the second space through the connection passage; A direction control member mounted to the connection channel to adjust a direction of the fluid ejected to the second impeller; And an on / off valve mounted on the other end of the rotary shaft to control the flow of the fluid discharged by opening and closing the discharge port. By adjusting the direction of the fluid ejected to the second impeller by the direction control member, by adjusting the rotational speed of the rotating shaft rotates with the first impeller to control the opening and closing time of the valve.

In addition, preferably, the partition member includes a first inner case accommodating the first impeller therein; And a second inner case coupled to the first inner case, the rotation shaft penetrating therein and receiving the second impeller therein.

Preferably, the first inner case is formed in a cup shape having one side opened, and a partition wall is formed on an outer circumferential surface to partition the first space and the second space, and the connection flow path is disposed between the partition walls. A first connection passage and a second connection passage are provided.

In addition, preferably, the second inner case is formed in a cup shape having one side coupled to the first inner case to partition the first space and the second space, and guided to the outer circumferential surface through the second connection passage. And a third connection passage through which the fluid is introduced.

In addition, preferably, the direction adjusting member is mounted on the inner circumferential surface of the second inner case and is formed to be symmetrical with respect to the third connection flow path inclined guide surface for guiding the direction of the incoming fluid.

Further, preferably, the first impeller is formed larger than the second impeller.

In addition, preferably, the opening and closing valve is a rotary valve plate which is fixed to the rotary shaft to be rotatable with the rotary shaft and formed with at least one through hole; A fixed valve plate covering an opening of the second inner case and having a connection hole contacting the rotary valve plate and temporarily communicating with the through hole to allow fluid to pass therethrough; And a spring mounted to the rotary shaft to apply force to the rotary valve plate to closely contact the fixed valve plate. It includes.

In addition, preferably, two through holes and two connecting holes are formed at intervals of 180 degrees.

In addition, preferably, at least one of the contact surfaces in contact with the rotary valve plate and the fixed valve plate is a micro-channel for flowing out a part of the fluid so that the rotating shaft is rotated even when the through-hole and the connection hole is not in communication Connect the through hole and the connecting hole.

In addition, preferably, the partition member is mounted to the inside of the housing to be movable in the longitudinal direction, the one end is supported by the elastic member, the partition member is temporarily moved along the housing while the inlet and the A discharge passage is further included in which a discharge port is directly connected to the discharge port by connecting the discharge port to the fluid without passing through the partition member.

In addition, preferably, a first catching jaw formed on an outer circumferential surface of the partition member and temporarily contacting a partition wall partitioning the lower housing into a first space and a second space is formed on an inner surface of the housing, and the partition wall A second catching jaw that is in close contact with the other end edge portion of the member is formed on the inner surface of the housing, an O-ring is mounted on the first catching jaw and the second catching jaw, and the first catch on the inner surface of the housing. A first discharge passage and a second discharge passage are formed in the upper end of the locking jaw and the second locking jaw with a predetermined width and depth.

Further, preferably, the housing is composed of a first housing having an inlet formed therein, and a second housing having an outlet formed therein and rotatably fastened to the first housing, and configured to protrude obliquely at the other end of the partition member. An inclined pressing portion is formed, and a pressure protrusion for moving the partition member in the longitudinal direction by pressing the inclined pressing portion on the discharge port side of the second housing.

As described above, the vibration shock injection device according to the present invention controls the rotational speed of the rotating shaft by adjusting the inflow direction of the fluid flowing toward the second impeller, and controls the operation of the opening / closing valve so that the flow rate or pressure of the discharged fluid is discharged. Since the gap is adjusted, vibration shock caused by the fluid is generated.

When the rotational speed of the rotating shaft is fast, a small amount of water is discharged frequently, and when the rotational speed of the rotating shaft is relatively slow, a large amount of water is sprayed sparse with high pressure, so that the skin massage function is improved or the bowl is cleaned. When washing ability is improved.

In addition, it is possible to reduce the amount of fluid discharged than to continuously discharge the fluid while improving the skin massage function or dish washing power is water-saving effect.

Hereinafter, with reference to the accompanying drawings, the vibration shock injection device which is a preferred embodiment of the present invention will be described in detail.

1 is a perspective view showing a vibration impact injector according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing an exploded vibration shock injector, Figures 3 to 4 shows the internal structure of the vibration impact injector 3 is a cross-sectional view showing a state in which the discharge flow path is closed, FIG. 4 is a cross-sectional view showing a state in which the discharge flow path is opened, and FIG. 5 is a cross-sectional view showing a portion "AA" of FIG. FIG. 6 is a cross-sectional view of the "BB" part shown in FIG. 3, and FIG. 7 to FIG. 8 are a cross-sectional view of the "CC" part shown in FIG. 3, and FIG. 7 is a second impeller. Is a cross-sectional view illustrating a state in which a force is applied in a forward direction, and FIG. 8 is a cross-sectional view illustrating a state in which a second impeller is forced in a reverse direction.

As shown, the vibration shock injection apparatus according to the present invention has an inner receiving space and is connected to a water pipe at one side, and an inlet 11a for water is formed therein and a housing in which the outlet 12a for discharging the inlet water is formed. 10, a partition member 20 mounted inside the housing 10 to partition the inner receiving space of the housing 10 into the first space 1 and the second space 2, and the partition wall member ( The rotary member 30 is rotatably mounted in the interior of the 20 and the first and second impellers 31 and 32 are mounted, and the partition member 20 is configured to adjust the direction of the fluid ejected toward the second impeller. The rotation control member 40 is mounted to the inside and the on-off valve 50 is fixed to the rotating shaft 30 to rotate while controlling the discharge of the fluid.

The housing 10 has a structure in which a first housing 11 having an inlet 11a and a second housing 12 having an outlet 12a are screwed together. The O-ring 12b is attached to the screwing portion of the second housing 12 to prevent the fluid from leaking into the gap. A discharge plate 13 having a plurality of through holes 13a is mounted in the discharge hole 12a of the second housing 12 to discharge the diverged body of water.

The partition member 20 is coupled to the first inner case 21 and the first inner case 21 for accommodating the first impeller 31 therein, and the rotation shaft 30 penetrates through the second impeller 32. It consists of a second inner case 25 accommodated in.

The first inner case 21 has a cup shape with one side opening, and a partition 22 is formed at the middle of the outer circumferential surface thereof. A first connection passage 23 and a second connection passage 24 forming a connection passage with the partition 22 therebetween are formed. The first connection passage 23 communicates with the first space 1, and the second connection passage 24 communicates with the second space 2. As illustrated in FIG. 5, the first connection channel 23 is inclinedly penetrated so that the fluid introduced through the inlet port 11a shown in FIG. As illustrated in FIG. 6, the second connection channel 24 is inclinedly penetrated so that the rotating fluid can be discharged counterclockwise. In addition, the number of the first connection passages 23 may be larger than that of the second connection passages 24. In the present invention, the first connection passages 23 may be formed at eight locations and the second connection passages 24 may be formed. It is formed in four places.

The second inner case 25 has a cup shape in which one side thereof is coupled to the opening of the first inner case 21 to partition the first space 1 and the second space 2. The outer circumferential surface is formed with a third connection passage 26 through which the fluid discharged through the second connection passage 24 flows, and a rotation hole 27 into which the rotation shaft 30 is inserted is formed at the central portion of one side.

The first connection channel 23, the second connection channel 24, and the third connection channel 26 are assembled to be arranged in a straight line during front projection so as to smoothly serve as a connection channel for guiding fluid movement. It is desirable to be.

Direction control member 40 is made of a tubular shape in close contact with the inner surface of the second inner case 25, the inclined guide surface 41 for guiding the direction of the incoming fluid is based on the third connection passage 26 It is formed to be symmetrical. In other words, the interval between the inclined guide surface 41 toward the inner side is gradually moved away, and toward the center has a shape in which the width of the penetrated inner diameter gradually increases. In addition, a pinhole 43 is formed at one side of the outer circumferential surface so that the fixing pin 42 may be inserted to fix the direction control member 40 to the second inner case 25. A plurality of pinholes 43 are formed at predetermined intervals to selectively adjust the rotation angle of the direction control member 40. In addition, a pin hole 44 corresponding to the pin hole 43 is formed in the second inner case 25 so that the fixing pin 42 is fitted.

The rotating shaft 30 is inserted into the rotating hole 27 in a state where one end is rotatably fixed to the first inner case 21. The first impeller 31 is fixed to the rotation shaft 30 to be positioned inside the first inner case 21, and the second impeller 32 is fixed to be positioned inside the second inner case 25. It is preferable that the first impeller 31 is formed larger than the second impeller 32 so that the rotational force generated by the fluid flowing therein is larger than the second impeller 32.

The on-off valve 50 has a circular plate shape, is fixed to the rotating shaft so as to be rotatable with the rotating shaft 30, and has a rotary valve plate 51 having at least one through hole 51 a and a second inner case 25. A fixing valve plate 52 having a connecting hole 52a formed to contact the rotary valve plate 51 and mating with the through hole 51a, and fitted to the rotary shaft 30 to cover the rotary valve plate 51. It consists of a spring 53 for pressing the fixed valve plate 52. The through-hole 51a and the connection hole 52a may be formed in a plural number to form a pair with each other at a predetermined interval, but as shown in the drawing, two are preferably formed at intervals of 180 degrees. In addition, the fine flow paths 51b and 52b are formed on the contact surface where the rotary valve plate 51 and the fixed valve plate 52 contact each through hole 51a and the connection hole 52a. The microchannels 51b and 52b may be formed on only one of the contact surfaces on both sides, but as shown in the drawing, the microchannels 51b and 52b may be formed on both sides of the contact surface to be combined with each other to form a larger channel than the structure formed on the one contact surface. The micro flow paths 51b and 52b pass through a small amount of fluid even in a state where the through holes 51a and the connection hole 52b do not communicate with each other so that the through holes 51a and the connection hole 52b communicate with each other, thereby causing the rotation shaft 30 to be in communication with each other. ) Will start the rotation. In addition, since the fluid flows between the contact surfaces by the micro-channels 51b and 52b, the frictional force is reduced. The fixed valve plate 52 is supported by the fixing member 55 in which a plurality of through holes 55a are formed. The fixing member 55 is fixed to the inner side surface of the second inner case 25.

The partition member 20 is mounted in the housing 10 to be movable in the longitudinal direction, and one end of the partition member 20 is supported by the elastic member 3. The elastic member 3 is preferably made of a leaf spring. The gap between the outer circumferential surface of the partition member 20 and the inner surface of the housing 10 serves as a discharge flow path.

On the upper end of the inner side of the second housing 12 of the housing 10, a first catching jaw 13 protruding by a predetermined height from the inner side of the first housing 11 is formed, and the second housing 12 of the second housing 12 is formed. A second catching jaw 14 protruding by a predetermined height and extending along the circumferential surface is formed at the lower end of the inner surface. The first catching jaw 13 temporarily contacts the partition 22 to partition the inside of the housing 10 into a first space 1 and a second space 2. The second catching jaw 14 is temporarily in contact with an end edge of the second inner case 25 constituting the partition member 20. O-rings 13a and 14a are mounted on the first catching jaw 13 and the second catching jaw 14 to prevent leakage of fluid.

The partition wall 22 is in contact with the inner surface of the first housing 11, the end of the second inner case 25 is made of a structure in contact with one side of the second housing 12,

The first discharge passage 13b recessed in a predetermined width and depth at the upper end side of the first catching jaw 13 and the upper end side of the second catching jaw 14 in which the partition 22 and the second housing 12 contact each other. And a second discharge passage 14b are formed.

The other end of the second inner case 25 constituting the partition member 20 is formed with an inclined pressing portion 61 protruding obliquely. The inclined pressure part 61 may be integrally formed at the end of the second inner case 25, or may be formed in a structure in which the inclined pressure member 60 provided with the inclined pressure part 61 is mounted as shown. have. In addition, on the discharge port side of the second housing 12, a pressing protrusion 12c protruding toward the inclined pressing portion 61 by a predetermined height is formed. The pressing protrusion 12c is formed in pairs with the inclined pressing portion 61.

In addition, a guide pin 15 is inserted into one side of the outer circumferential surface of the first housing 11, and the guide pin 15 is fitted into the guide groove 21a formed on the outer circumferential surface of the first inner case 21 to be inserted into the first inner case case. 21 can be moved only in the longitudinal direction without being rotated.

A process of operating the vibration shock injection device according to the preferred embodiment of the present invention configured as described above is as follows.

As shown in FIG. 3, after the second housing 12 is rotated and moved to the locked position, the fluid is introduced into the housing 10 through the inlet 11a when water supply of the fluid starts.

The fluid introduced into the first space 1 through the inlet 11a flows into the first inner case 21 through the first connection passage 23. In this case, the fluid passing through the first connection channel 23 flows in a counterclockwise direction as shown in FIG. 5. Since the first impeller 31 is rotated counterclockwise by the force of the fluid flowing in the counterclockwise direction, the rotation axis is also rotated counterclockwise.

The fluid flowing into the first inner case 21 and rotating the first impeller 31 is discharged into the second space 2 through the second connection passage 24. The fluid discharged to the second connection channel 24 formed to be inclined is discharged while rotating counterclockwise along the inner surface of the housing 10 as shown in FIG. 6.

In the second space 2, the fluid rotated in the counterclockwise direction along the inner surface of the housing 10 passes through the third connection passage 26 as shown in FIG. 7 and then inclines the direction adjusting member 40. It flows in the counterclockwise direction along the guide surface 41. The fluid introduced in the counterclockwise direction rotates the second impeller 32 in the counterclockwise direction. As described above, when a force is applied to the second impeller 32 in a counterclockwise direction, the rotation shaft 30 rotates at a high speed because the same direction as that of the force applied to the first impeller 31.

As shown in FIG. 8, when the direction control member 40 is rotated and fixed by a predetermined angle, the fluid passing through the third connection channel 26 flows into the second housing 25 along the inclined guide surface 41. When the direction is changed to clockwise direction is introduced. The fluid flowing in the clockwise direction exerts a force to rotate the second impeller 32 in a clockwise direction. As described above, when a force is applied to the second impeller 32 in a clockwise direction, the rotation shaft 31 rotates at a slow speed because it is opposite to the direction of the force applied to the first impeller 31.

Although not shown in the same manner, when the direction control member 40 is fixed to the intermediate position, the fluid passing through the third connection passage 26 passes between the inclined guide surfaces 41 on both sides and flows into the second housing 25. Therefore, the rotating shaft 31 is to rotate at an intermediate speed.

As described above, the rotational speed of the rotation shaft 30 may be adjusted by adjusting the fixed position of the direction control member 41 in which the inclined guide surface 41 communicating with the third connection channel 26 is formed.

The fluid introduced into the second inner case 25 is discharged through the through hole 51a formed in the rotary valve plate 51 and the connection hole 52a formed in the fixed valve plate 52.

At this time, when the rotational speed of the rotary shaft 30 is fast, the rotational speed of the rotary valve plate 51 is fast, so that the through hole 51a and the connection hole 52a are frequently communicated for a short time. That is, since the rotational speed of the rotary valve plate 51 is fastened in conjunction with the rotary shaft 30, the moment when the through hole 51a and the connection hole 52a communicate is shortened, but frequently communicated, so that a small amount of fluid is frequently discharged. Will be. Therefore, the water stream is often discharged under a weak pressure.

When the rotational speed of the rotary shaft 30 is slow, the rotational speed of the rotary valve plate 51 is slow, so that the through hole 51a and the connection hole 52a are in sparse communication for a relatively long time. That is, since the rotational speed of the rotary valve plate 51 communicates with the rotary shaft 30 and proceeds slowly, the moment when the through hole 51a and the connection hole 52a communicate is relatively long, and the sparse communication is carried out. It is discharged sparsely. Therefore, the water stream is sparsely discharged under strong pressure.

The fluid passing through the through hole 51a and the connection hole 52a passes through the through hole 55a of the fixing member 55 and passes through the through hole 13a of the discharge plate 13 to the outside.

When the user wants to discharge continuously immediately without adjusting the discharge pressure, discharge amount, or discharge time of the fluid, as shown in FIG. 4, the partition member 20 is moved by rotating the second housing 12 in the unwinding direction. Let's do it.

As described above, when the second housing 12 is rotated, the pressing member 12c moves in the direction in which the partition member 20 is drawn into the housing 10 while pressing the high position of the inclined pressing portion 61. At this time, the elastic member 3 is compressed. When the second housing 12 returns to its original state, the partition member 20 also moves to its original position by the elastic force of the elastic member 3.

When the partition member 20 moves in the direction in which the partition member 20 moves, the partition wall 22, which is in close contact with the O-ring 12a formed on the first catching jaw 13, is separated, and the fluid located in the first space 1 is moved to the first space. It flows into the 2nd space 2 directly through the discharge flow path 13b.

In addition, as the partition member 20 is moved, the end edge of the second inner case 25, which is in close contact with the O-ring 14a formed on the second catching jaw 14, is separated, and immediately flows into the second space 1. After the fluid flows into the discharge plate 13 through the second discharge passage 14b, the fluid is discharged to the outside through the through hole 13a.

As described above, a gap is generated between the O-ring 13a formed in the first catching jaw 13 and the partition wall 22 and between the O-ring 14a formed in the second catching jaw 14 and the second inner case 25. When the gap is generated, a discharge passage for guiding the fluid introduced into the inlet 11a directly to the outlet 12a is formed. When the discharge passage is formed, the fluid moves directly through the discharge passage rather than flowing into the partition member 20 in which the first impeller 31 or the second impeller 32 is formed, which is relatively resistant to the flow of the fluid. Will be done.

As described above, the vibrating shock injection device according to the present invention moves the partition member 20 when the fluid flowing through the inlet 11a is discharged immediately through the outlet 12a so that the O-ring 13a and the partition wall ( 22) through the gap between the O-ring (14a) and the second inner case 25 and flows directly into the second space (2) from the first space (1) to be discharged through the discharge port (12a).

When the flow of the fluid is to be adjusted, the partition member 20 is returned to its original state so that the partition wall 22 and the O-ring 13a are in close contact with each other, and the edges of the two inner cases 25 are closely contacted with the O-ring 14a. When the discharge flow path is blocked, the fluid moves while rotating the first impeller 31 and the second impeller 32. At this time, by adjusting the flow direction of the fluid flowing toward the second impeller 32 by using the direction control member 40, it is possible to adjust the rotation speed of the rotation shaft (30).

When the rotational speed of the rotation shaft 30 is high, the moment of communication between the through hole 51a and the connection hole 52a is shortened, and the frequency of communication within the same time becomes high, so that the water is frequently discharged with weak pressure.

When the rotational speed of the rotation shaft 30 is slow, the moment when the through hole 51a and the connection hole 52a communicate is relatively long, and the frequency of communication within the same time decreases, so that a stream of strong pressure water is sparsely discharged.

That is, by repeatedly operating the opening / closing valve 50 installed on the rotating shaft 30 to generate the rotational force by using the hydraulic pressure of the fluid, water is repeatedly cut and passed to generate water as well as vibration to generate a surface that the fluid contacts. Shocks. When applied to the kitchen sink water, the impact on the dishwasher increases, effectively removing the debris from the dishes, and when applied to the shower, the vibration effect is applied to the body of water that touches the skin, so that the massage effect is increased and instantaneous strong excitement is felt. When applied to waterfalls installed in public baths, strong vibration shocks are generated so that the waterfalls can feel the natural waterfall as if the water is falling.

Since the pressure of the fluid to be discharged and the amount of the fluid to be discharged at a moment can be adjusted, a vibration shock using the fluid is generated, and it can be controlled.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is a perspective view showing a vibration impact injection device which is a preferred embodiment of the present invention,

Figure 2 is an exploded perspective view showing an exploded vibration shock injection device,

3 to 4 are cross-sectional views showing the internal structure of the vibration shock injection device,

3 is a cross-sectional view showing a state in which the discharge passage is closed;

4 is a sectional view showing a state in which the discharge passage is opened;

5 is a cross-sectional view taken along line “A-A” of FIG. 3;

FIG. 6 is a cross-sectional view of a section “B-B” shown in FIG. 3;

7 to 8 are cross-sectional views showing a section "C-C" shown in FIG.

7 is a cross-sectional view showing a state in which the second impeller receives a force in the forward direction,

8 is a cross-sectional view showing a state in which the second impeller receives a force in a reverse direction.

** Description of the symbols for the main parts of the drawings **

10 housing 20 partition wall member

22: bulkhead 30: axis of rotation

31: first impeller 32: second impeller

40: direction control member 50: on-off valve

Claims (12)

A housing having an inlet connected to the water pipe at one side thereof and a discharge hole formed at the other side thereof; A partition member mounted in the inner accommodating space of the housing and partitioning the inner accommodating space into a first space and a second space and having a connection passage connecting the first space and the second space; A rotating shaft rotatably fixed through the partition member; A first impeller positioned in the first space and having a rotational force generated by the fluid introduced through the inlet and mounted at one end of the rotation shaft; A second impeller positioned in the second space and generating rotational force by the fluid flowing into the second space through the connection passage; A direction control member mounted to the connection channel to adjust a direction of the fluid ejected to the second impeller; And An opening / closing valve mounted on the other end of the rotating shaft to control the flow of the discharged fluid by opening and closing the discharge port; Including Vibration, characterized in that by controlling the direction of the fluid ejected to the second impeller by the direction control member, by controlling the rotational speed of the rotating shaft rotated with the first impeller to control the opening and closing time of the opening and closing valve Impact injectors. The method of claim 1, The partition member is A first inner case accommodating the first impeller therein; And A second inner case coupled to the first inner case and penetrating the rotating shaft and accommodating the second impeller therein; Vibration shock injection device comprising a. The method of claim 2, The first inner case is formed in a cup shape having one side opened, and a partition wall partitioning the first space and the second space is formed on an outer circumferential surface thereof, and a first connection channel forming the connection channel with the partition wall therebetween; Vibration shock injection device characterized in that the second connection passage is provided. The method of claim 3, wherein The second inner case has one side coupled to the first inner case and formed in a cup shape for partitioning the first space and the second space, and the fluid guided through the second connection flow path to an outer circumferential surface thereof. Vibration shock injection device characterized in that the connection passage 3 is provided. The method of claim 4, wherein The direction control member is mounted on the inner circumferential surface of the second inner case and the inclined guide surface for guiding the direction of the fluid flowing in the vibration impact injection device, characterized in that formed on the basis of the third symmetric symmetry. The method of claim 1, The first impeller is vibrating shock injection device, characterized in that formed larger than the second impeller. The method of claim 4, wherein The on-off valve is A rotary valve plate fixed to the rotary shaft to be rotatable with the rotary shaft and having at least one through hole formed therein; A fixed valve plate covering an opening of the second inner case and having a connection hole contacting the rotary valve plate and temporarily communicating with the through hole to allow fluid to pass therethrough; And A spring mounted to the rotary shaft to apply a force such that the rotary valve plate is in close contact with the fixed valve plate; Vibration shock injection device comprising a. The method of claim 7, wherein The through-hole and the connecting hole is a vibration shock injection device, characterized in that two are formed at 180 degrees apart. The method of claim 8, At least one of the contact surfaces of the rotary valve plate and the fixed valve plate in contact with the through-hole and the connection hole is a micro-channel for flowing out a part of the fluid so that the rotating shaft is rotated even when the through-hole and the connection hole is not in communication Vibration shock injection device, characterized in that for connecting. The method according to any one of claims 1 to 9, The partition member is mounted to the inside of the housing to be movable in the longitudinal direction, the one end is supported by the elastic member, the partition member is moved along the housing to temporarily connect the inlet and the discharge port fluid And a discharge passage which is discharged directly to the discharge port without passing through the partition member. The method of claim 10, A first catching jaw formed on the outer circumferential surface of the partition member and temporarily contacting the partition wall partitioning the lower housing into the first space and the second space is formed on the inner surface of the housing, and the other end edge of the partition member is formed. And a second catching jaw that is in close contact with the second jammer is formed on the inner surface of the housing, and an O-ring is mounted on the first catching jaw and the second catching jaw, and the first catching jaw and the second catching jaw on the inner surface of the housing. Vibration impact injection device characterized in that the first discharge passage and the second discharge passage recessed in a predetermined width and depth is formed on the upper end of the locking jaw. The method of claim 11, The housing includes a first housing having an inlet formed therein, and a second housing having an outlet formed therein and rotatably fastened to the first housing, and having an inclined pressure part protruding obliquely at the other end of the partition member. Vibration impact injection device characterized in that the discharge port side of the second housing is provided with a pressing projection for moving the partition member in the longitudinal direction by pressing the inclined pressure portion.

Images