JP6177381B2 - nozzle - Google Patents

Description

  The present invention relates to nozzle technology.

2. Description of the Related Art Conventionally, a nozzle technology including an inflow portion into which water flows in and a throttle portion that squeezes the flow of water flowing in from the inflow portion to increase the flow rate of water is known (see Patent Document 1).
The nozzle is used for the purpose of cleaning the object to be cleaned by discharging streaky air bubbles mixed water onto the object to be cleaned, such as food, animals, human bodies, metal members, resin members, and buildings.

In addition to the inflow portion and the throttling portion, the nozzle includes a dissolving portion configured to dissolve the solid agent with water and flow out the water as a predetermined solution, and discharges water. Some are configured to discharge a predetermined solution.
Here, the solid agent indicates a substance that can be dissolved by contact with water (for example, a solid detergent, a solid coating agent, a solid drug, or a solid carbonic acid agent that can be dissolved by contact with water). .
The predetermined solution indicates a solution in which a solid agent is dissolved and mixed in water.

JP 52-94513 A

However, the nozzle having the dissolving part includes, for example, a structure in which the dissolving part is arranged on the downstream side of the throttle part and water is caused to flow into the dissolving part by being pushed in by the water force. That is, the nozzle is not configured so that a predetermined solution is sucked and flows out of the dissolving portion even when water flows out from the throttle portion to the downstream side, and water is sucked into the dissolving portion. It is not configured to flow in.
In the nozzle configured as described above, water cannot be sufficiently allowed to flow into the dissolving portion by being pushed in by the water flow of water, and water cannot be reliably introduced into the dissolving portion into the dissolving portion ( In some cases, the solid agent cannot be dissolved to obtain a sufficient amount of the predetermined solution. Further, in the nozzle configured as described above, water cannot be sufficiently allowed to flow into the dissolving portion by being pushed in by the water flow, and a predetermined amount of liquid cannot be reliably discharged from the dissolving portion. There is a case.

  The present invention has been made in view of the above situation, and more reliably in comparison with conventional nozzles, water is allowed to flow into the dissolving portion, and the solid agent disposed in the dissolving portion is dissolved by water to thereby reduce the predetermined amount. It is an object of the present invention to provide a nozzle that can cause a predetermined liquid to flow out of a dissolving portion.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, in claim 1, the inflow part into which water flows in, the throttle part which restricts the flow of water flowing in from the inflow part to increase the flow rate of the water, and the water flowing out from the throttle part to the downstream side A nozzle configured to dissolve the solid agent and discharge the water as a predetermined solution, and to discharge the water and discharge the predetermined solution. The dissolving portion is sucked when at least a part of the water flowing out from the throttling portion flows downstream into the dissolving portion, and the water flows out from the throttling portion toward the downstream side, and the predetermined portion The nozzle is configured such that the liquid flows out from the dissolving portion.

  According to a second aspect of the present invention, there is provided a diffusion portion configured to diffuse when water flowing out from the throttle portion to the downstream side comes into contact therewith.

  According to a third aspect of the present invention, it is configured in a cylindrical shape, and is arranged such that the water that has diffused by contacting the diffusion portion contacts the inner surface thereof, and the water that contacts the inner surface is downstream. A cylindrical member configured to flow out from the opening at the side end is provided.

  As effects of the present invention, the following effects can be obtained.

  That is, according to the present invention, water is allowed to flow into the dissolving portion more reliably than in the conventional nozzle, and the solid agent disposed in the dissolving portion is dissolved with water to form a predetermined solution, and the predetermined liquid is supplied. It can be discharged from the dissolving part.

The front view which showed the state which decomposed | disassembled the nozzle which concerns on 1st embodiment of this invention. Similarly the front view of a nozzle. Similarly sectional drawing of a nozzle. The bottom view which similarly showed the aperture member in a nozzle. Similarly a partial enlarged sectional view of the nozzle. Sectional drawing of the nozzle which concerns on 2nd embodiment of this invention. The front view which showed the state which decomposed | disassembled the nozzle which concerns on 3rd embodiment of this invention. Similarly sectional drawing of a nozzle.

  Next, the nozzle 1 according to the first embodiment of the present invention will be described with reference to FIGS. In addition, the arrow A in a figure demonstrates as what shows the direction through which bubble mixed water flows.

The nozzle 1 is configured to mix air into water flowing into the nozzle 1 from the water outlet and discharge the bubble mixed water as bubble mixed water.
As shown in FIGS. 1 to 4, the nozzle 1 includes an inflow portion 11, a throttle portion 12, an air introduction portion 13, a diffusion portion 14, and a dissolution portion 15, and is generally substantially cylindrical. Formed.

  The inflow portion 11 of the nozzle 1 is a portion that is connected to the water outlet and that flows out of the water outlet (for example, a hose) into the nozzle 1.

  The throttle portion 12 of the nozzle 1 is a portion that squeezes the flow of water flowing into the nozzle 1 from the inflow portion 11 to increase the flow rate of water. The throttle portion 12 of the nozzle 1 is disposed downstream of the inflow portion 11. The nozzle 1 is configured such that the flow rate of water flowing out from the throttle unit 12 to the downstream side is increased as compared with the upstream side of the throttle unit 12.

The air introduction unit 13 of the nozzle 1 is connected to the downstream side of the throttle unit 12 by sucking air into the water flowing out from the throttle unit 12 (water flowing in from the water outlet) and mixing the air. This is the part that introduces air into the nozzle 1 so that the water flowing out into the air becomes bubble mixed water.
The air introduction portion 13 of the nozzle 1 is connected to the downstream side portion of the throttle portion 12 in the nozzle 1 from the outside of the nozzle 1 through an air inlet opening 13a in the air introduction portion 13 (hereinafter referred to as “inlet opening 13a”). It is configured to introduce air in the vicinity. An air outlet opening 13 b (hereinafter referred to as “exit opening 13 b”) in the air introduction portion 13 of the nozzle 1 is formed in the vicinity of the downstream portion of the throttle portion 12 in the nozzle 1. Air is introduced into the nozzle 1 through an opening 13 b at the outlet of the air introduction portion 13.

The diffusion unit 14 of the nozzle 1 serves to diffuse the bubble-mixed water while weakening the water force of the bubble-mixed water.
The diffusing unit 14 of the nozzle 1 is disposed on the downstream side of the throttle unit 12 and the air introducing unit 13. The diffusion part 14 of the nozzle 1 is disposed at a position where the bubble-mixed water comes into contact.
The diffusing section 14 of the nozzle 1 is configured such that when the bubble-mixed water abuts the diffusion section 14, the bubble-mixed water is weakened and the bubble-mixed water is diffused.

In the nozzle 1 configured as described above, the bubble-mixed water is weakened by contacting the bubble-mixed water with the diffusion portion 14.
However, in the nozzle 1, the water force immediately after flowing out from the throttle unit 12 to the downstream side (water flowing in from the water outlet) is not weakened. The suction power does not decrease.
For this reason, in the nozzle 1, the air can be reliably mixed in the water introduced into the downstream side from the throttle unit 12 (water whose water power is not weakened) in the air introduction unit 13.
As described above, the nozzle 1 weakens the water force while preventing the amount of bubbles mixed in from decreasing, and discharges the bubble mixed water from the opening 44 at the downstream end of the second cylindrical member 42. Configured.
Therefore, according to the nozzle 1, it can prevent that the washing | cleaning target is damaged, preventing the washing | cleaning effect by bubble mixing water falling.

Further, in the nozzle 1, the bubble-mixed water diffuses when the bubble-mixed water comes into contact with the diffusion portion 14 (see FIG. 5).
And in the nozzle 1, the said bubble mixed water diffuses and the discharge range of bubble mixed water spreads.
For this reason, according to the nozzle 1, compared with the conventional nozzle, the washing | cleaning operation | work of the said washing | cleaning object can be performed easily.

The dissolving portion 15 of the nozzle 1 is configured such that a solid agent 56 is disposed.
The dissolving portion 15 of the nozzle 1 dissolves the solid agent 56 disposed in the dissolving portion 15 by the bubble mixed water (by contacting the bubble mixed water) so that the bubble mixed water flows out as a predetermined solution. Composed.
The dissolving portion 15 of the nozzle 1 dissolves the solid agent 56 disposed in the dissolving portion 15 by a predetermined solution (by contacting the predetermined solution), and the dissolved solid agent 56 component in the predetermined solution It is configured to flow out a predetermined solution at a high concentration.

An opening 15 a (hereinafter referred to as “inlet opening 15 a”) for the bubble-containing water (or a predetermined solution) in the dissolving portion 15 of the nozzle 1 is downstream of the throttle portion 12 and at the outlet of the air introduction portion 13. It arrange | positions in the downstream of 13b.
A predetermined solution outlet opening 15b (hereinafter referred to as “outlet opening 15b”) in the dissolving portion 15 of the nozzle 1 is a midway portion of the air introducing portion 13 (on the downstream side of the inlet opening 13a of the air introducing portion 13, and It is arrange | positioned in the upstream 13b of the opening 13b of the air introduction part 13 exit.

The dissolving portion 15 of the nozzle 1 is sucked by the predetermined liquid in the dissolving portion 15 flowing out from the throttle portion 12 to the downstream side, and flows out from the dissolving portion 15 through the opening 15 b at the outlet of the dissolving portion 15. In addition, at least a part of the bubble mixed water (or a part of the predetermined liquid flowing out from the outlet opening 15b) flows into the dissolving part 15 through the opening 15a at the inlet of the dissolving part 15. Composed.
The nozzle 1 is configured to dissolve the solid agent 56 with bubble-containing water or a predetermined solution flowing into the dissolution unit 15, to flow out from the dissolution unit 15 as a predetermined solution, and to discharge the predetermined solution. .

As described above, the nozzle 1 is sucked when water flows out from the throttle unit 12 to the downstream side, and a predetermined liquid flows out from the dissolving unit 15, and at least a part of the bubble mixed water is in the dissolving unit 15. A melting part 15 configured to flow into
Therefore, according to the nozzle 1, even if water flows out from the throttle part to the downstream side, the predetermined solution is sucked and does not flow out of the dissolving part, and the bubble mixed water is sucked and dissolved in the dissolving part. The solids placed in the dissolving part 15 by the bubble-containing water are more surely introduced into the dissolving part 15 than those that are not configured to flow into the dissolving part 15). The agent 56 can be dissolved to form a predetermined solution, and a predetermined liquid can flow out from the dissolution unit 15.

Here, the solid agent 56 disposed in the dissolving portion 15 of the nozzle 1 is a solid that can be dissolved by contact with bubble-containing water (for example, a solid that can be dissolved by contact with bubble-containing water (water). A detergent, a solid coating agent, a solid medicine, or a solid carbonic acid agent).
The predetermined solution indicates a solution in which the solid agent 56 is dissolved and mixed in the bubble-containing water.

Next, a specific configuration of the nozzle 1 will be described.
The nozzle 1 includes a connection member 20, a throttle member 30, a first cylinder member 40, a second cylinder member 42, a solid agent arrangement member 50, and a solid agent 56, and discharges bubble-containing water. At the same time, a predetermined solution is discharged.

The connection member 20 of the nozzle 1 is formed in a substantially cylindrical shape with its upstream end and downstream end opened.
An upstream side portion of the connection member 20 of the nozzle 1 is configured as an inflow portion 11.
The connecting member 20 of the nozzle 1 is configured such that its upstream side portion can be connected to a water outlet.
The connecting member 20 of the nozzle 1 is configured such that a flange 21 is formed in an upper and lower halfway portion (between an upstream side portion and a downstream side portion). The flange 21 in the connecting member 20 of the nozzle 1 is formed so as to protrude sideways.
The connecting member 20 of the nozzle 1 is configured such that a downstream side portion thereof (a portion on the downstream side of the flange 21) can be inserted into the throttle member 30 through an opening at an upstream end portion of the throttle member 30.

The throttle member 30 of the nozzle 1 is formed in a substantially bottomed cylindrical shape with its upstream end opened and a bottom 31 at the downstream end.
A flange 32 is formed at the upstream end of the throttle member 30 of the nozzle 1. The flange 32 in the throttle member 30 of the nozzle 1 is formed so as to protrude sideways.

  The throttle member 30 of the nozzle 1 has a recess 33. The recess 33 in the throttle member 30 of the nozzle 1 is formed at the center of the upstream surface of the bottom 31. The recess 33 in the throttle member 30 of the nozzle 1 is formed such that the upstream surface of the bottom 31 is recessed in a substantially hemispherical shape.

The throttle member 30 of the nozzle 1 has a plurality of throttle holes 34.
The throttle hole 34 in the throttle member 30 of the nozzle 1 is used to throttle the flow of water flowing into the nozzle 1 to increase the flow rate of water. The throttle portion 12 is configured by a plurality of throttle holes 34 in the throttle member 30 of the nozzle 1.
The aperture hole 34 in the aperture member 30 of the nozzle 1 is formed so as to pass through the bottom 31 from the aperture member 30 to the outside of the aperture member 30. The throttle hole 34 in the throttle member 30 of the nozzle 1 is formed so that the upstream opening 35 opens into the recess 33. The aperture hole 34 of the aperture member 30 of the nozzle 1 is formed with the phase shifted by 60 degrees in the circumferential direction.
The throttling holes 34 of the throttling member 30 of the nozzle 1 are formed so that the three water flows that flow out from the respective downstream openings 36 in the throttling holes 34 flow out in parallel to the axial center direction of the nozzle 1.
The number of the throttle holes 34 in the throttle member 30 of the nozzle 1 is not limited to three.

The throttle member 30 of the nozzle 1 has a notch 37.
The notches 37 in the throttle member 30 of the nozzle 1 are respectively formed so as to be shifted in phase by 180 degrees in the circumferential direction (positions facing each other about the axis of the throttle member 30). The notch 37 in the throttle member 30 of the nozzle 1 is formed such that a part of the outer peripheral surface including the flange 32 is cut out along the axial direction of the throttle member 30 from the upper end to the lower end. .

The first cylinder member 40 of the nozzle 1 is formed in a cylindrical shape with its upstream end and downstream end opened.
The first cylindrical member 40 of the nozzle 1 is gradually reduced in diameter as it goes from the upper and lower halfway portion (between the upstream side portion and the downstream side portion) to the downstream end portion, and the inner diameter of the opening at the upstream end portion is increased. It is formed and configured to be larger than the inner diameter of the opening at the downstream end.
The first cylinder member 40 of the nozzle 1 is configured such that a portion of the throttle member 30 on the downstream side of the flange 32 can be fitted into the upstream side portion thereof.

The first cylinder member 40 of the nozzle 1 has a first through hole 41.
The first through hole 41 of the first cylinder member 40 of the nozzle 1 is disposed at the upstream end of the first cylinder member 40.
The first through hole 41 of the first cylinder member 40 of the nozzle 1 is formed so as to penetrate from the outer surface to the inner surface of the upstream end portion of the first cylinder member 40. The first through-hole 41 of the first cylindrical member 40 of the nozzle 1 is configured to be capable of fitting and inserting one end portion of the outflow pipe 53.

The second cylinder member 42 of the nozzle 1 is formed in a cylindrical shape with its upstream end and downstream end opened.
The second cylinder member 42 of the nozzle 1 is configured such that the upstream side portion thereof can be fitted into the downstream end portion of the first cylinder member 40.
The second cylinder member 42 of the nozzle 1 is configured such that the outer diameters of the portions (the midway portion and the downstream side portion) excluding the upstream side portion are smaller than those of the upstream side portion.
The diameter of the second cylindrical member 42 of the nozzle 1 is reduced from the upstream end toward the downstream side of the inner surface of the boundary portion between the upstream side portion and the midway portion of the second cylindrical member 42. The two cylinder members 42 are configured to have an inclined surface (in a tapered shape) inside the boundary portion between the upstream side portion and the midway portion.

The second cylindrical member 42 of the nozzle 1 has a second through hole 43.
The second through hole 43 of the second cylinder member 42 of the nozzle 1 is disposed in the middle of the second cylinder member 42.
The second through-hole 43 of the second cylinder member 42 of the nozzle 1 is formed so as to penetrate from the outer surface of the middle part of the second cylinder member 42 to the inner surface. The second through-hole 43 of the second cylindrical member 42 of the nozzle 1 is configured so that one end of the inflow pipe 54 can be fitted and inserted.

The solid agent disposing member 50 of the nozzle 1 is configured as the dissolving portion 15.
The solid agent arrangement member 50 of the nozzle 1 is configured such that a solid agent 56 can be arranged inside (solid agent arrangement chamber 55). The solid agent arrangement member 50 of the nozzle 1 dissolves the solid agent 56 arranged in the solid agent arrangement chamber 55 of the solid agent arrangement member 50 with the bubble mixed water, and flows out the bubble mixed water as a predetermined solution. Composed.
The solid agent arrangement member 50 of the nozzle 1 dissolves the solid agent 56 arranged in the solid agent arrangement chamber 55 of the solid agent arrangement member 50 by contact with the predetermined solution (by contacting the predetermined solution) to obtain a predetermined solution. The concentration of the dissolved solid agent 56 in the inside is increased, and a predetermined solution is discharged.
The solid agent arrangement member 50 of the nozzle 1 includes a body 51, a lid 52, an outflow pipe 53, and an inflow pipe 54. The solid agent arrangement member 50 of the nozzle 1 is configured such that a space (solid agent arrangement chamber 55) in which the solid agent 56 can be arranged is formed inside by covering the body 51 with a lid 52.

The body 51 of the solid agent arrangement member 50 of the nozzle 1 includes an outflow through hole 51a and an inflow through hole 51b.
The outflow through hole 51 a of the body 51 of the solid agent arrangement member 50 in the nozzle 1 is formed so as to penetrate from the outer surface to the inner surface of the bottom portion of the body 51. The outflow through hole 51 a of the body 51 of the solid agent arranging member 50 in the nozzle 1 is configured by fitting the other end of the outflow pipe 53.
The inflow through hole 51 b of the body 51 of the solid agent arranging member 50 in the nozzle 1 is formed so as to penetrate from the outer surface of the side portion of the body 51 to the inner surface. The inflow through hole 51 b of the body 51 of the solid agent arranging member 50 in the nozzle 1 is configured by fitting the other end of the inflow pipe 54.

The outflow pipe 53 of the solid agent arrangement member 50 of the nozzle 1 is formed in a tubular shape. The inside of the outflow pipe 53 of the solid agent arrangement member 50 of the nozzle 1 is configured as a flow path through which a predetermined solution flows out of the solid agent arrangement chamber 55.
The solid agent arranging member 50 in the nozzle 1 is configured by fitting the other end portion of the outflow pipe 53 into the outflow through hole 51 a of the body 51 of the solid agent arranging member 50.
One end portion of the outflow pipe 53 of the solid agent arranging member 50 in the nozzle 1 is configured to be fitted into the first through hole 41 of the first cylindrical member 40.

The inflow pipe 54 of the solid agent arrangement member 50 of the nozzle 1 is formed in a tubular shape. The inside of the inflow pipe 54 of the solid agent arrangement member 50 of the nozzle 1 is configured as a flow path through which bubble mixed water (or a predetermined solution) flows into the solid agent arrangement chamber 55.
The solid agent arranging member 50 in the nozzle 1 is configured by fitting the other end of the inflow pipe 54 into the inflow through hole 51 b of the body 51 of the solid agent arranging member 50.
One end portion of the inflow pipe 54 of the solid agent arranging member 50 in the nozzle 1 is configured to be fitted into the second through hole 43 of the second cylindrical member 42.

The nozzle 1 is configured such that a portion of the connecting member 20 on the downstream side of the flange 21 is inserted into the upstream side portion of the throttle member 30 from the upstream end portion of the throttle member 30.
In a state where the connecting member 20 is inserted into the throttle member 30 of the nozzle 1, the inside of the connecting member 20 and the inside of the throttle member 30 communicate with each other.
In the nozzle 1, water flowing from the upstream side of the connecting member 20 flows into the throttle member 30 through the connection member 20 and flows out from the respective downstream openings 36 in the throttle hole 34 of the throttle member 30. Configured to do so.

The nozzle 1 is configured such that a portion of the throttle member 30 on the downstream side of the flange 32 is fitted into the first cylindrical member 40 from the upstream end opening of the first cylindrical member 40. At this time, in the nozzle 1, the first through hole 41 of the first cylinder member 40 is located outside the one notch 37 of the throttle member 30, and the first through hole 41 of the first cylinder member 40 and the air introduction part 13 are located. And the throttle member 30 is inserted and configured in the first cylindrical member 40 so as to communicate with each other in the midway portion of the air introduction portion 13.
The nozzle 1 is configured such that the upstream side portion of the second cylindrical member 42 is inserted into the first cylindrical member 40 from the opening of the downstream end portion of the first cylindrical member 40.

In a state in which the throttle member 30 is inserted into the first cylindrical member 40 of the nozzle 1, the inner peripheral surface of the first cylindrical member 40 and the outer peripheral surface of the portion where the notch 37 of the throttle member 30 is not formed are in contact. A space is formed between the inner peripheral surface of the first cylindrical member 40 and the outer surface of the portion where the notch 37 of the aperture member 30 is formed, although in contact with each other. The air introduction portion 13 is configured by a space formed by the notch 37 in the throttle member 30 of the nozzle 1 and the inner peripheral surface of the first cylindrical member 40.
In the nozzle 1, the opening at the upper end of the notch 37 in the throttle member 30 is configured as an opening 13 a at the inlet of the air introduction unit 13. Further, the opening at the lower end portion of the notch 37 in the throttle member 30 of the nozzle 1 is configured as an air outlet opening 13 b in the air introduction portion 13.
The nozzle 1 is sucked by the outflow of water from each downstream opening 36 in the throttle hole 34 (throttle section 12) of the throttle member 30, and is introduced into the air introduction section 13 (the outlet opening 13a of the air introduction section 13). ), And the introduced air is mixed so that water flowing out from the opening 36 on the downstream side of the throttle hole 34 is used as bubble mixed water.

The nozzle 1 is configured by arranging a solid agent 56 in a solid agent arrangement chamber 55 of the solid agent arrangement member 50.
In the nozzle 1, one end portion of the outflow pipe 53 of the solid agent arrangement member 50 is fitted into the first through hole 41 of the first cylinder member 40, and one end portion of the inflow pipe 54 of the solid agent arrangement member 50 is the second cylinder member. The second through hole 43 of 42 is inserted and configured.
In the state where the outflow pipe 53 of the solid agent arrangement member 50 in the nozzle 1 is fitted, the solid agent arrangement chamber 55 and the first cylinder member of the solid agent arrangement member 50 are interposed via the outflow pipe 53 of the solid agent arrangement member 50. It is comprised so that the inside (air introduction part 13) 40 may communicate.
In a state where the inflow pipe 54 of the solid agent arrangement member 50 in the nozzle 1 is fitted, the solid agent arrangement chamber 55 and the second cylinder member of the solid agent arrangement member 50 are interposed via the inflow pipe 54 of the solid agent arrangement member 50. 42 (a space on the downstream side of the throttle portion 12 or a space on the downstream side of the opening 13 b at the outlet of the air introduction portion 13) is configured to communicate with the inside.
The opening at one end of the outflow pipe 53 of the solid agent arranging member 50 in the nozzle 1 is a midway part of the air introduction part 13 (on the downstream side of the opening 13a at the inlet of the air introduction part 13 and the opening 13b at the outlet of the air introduction part 13). Upstream). In the nozzle 1, an opening at one end of the outflow pipe 53 of the solid agent arranging member 50 is configured as an outlet opening 15 b of the dissolving portion 15.
The opening at one end of the inflow pipe 54 of the solid agent arrangement member 50 in the nozzle 1 is arranged downstream of the throttle unit 12 and downstream of the outlet opening 13 b of the air introduction unit 13. In the nozzle 1, an opening at one end of the inflow pipe 54 of the solid agent arranging member 50 is configured as an opening 15 a at the inlet of the dissolving portion 15.

The solid agent arrangement member 50 of the nozzle 1 is sucked by a predetermined liquid in the solid agent arrangement chamber 55 of the solid agent arrangement member 50 as water flows out from the opening 36 on the downstream side of the throttle hole 34 of the throttle member 30. The solid agent arrangement member 50 flows out of the solid agent arrangement chamber 55 of the solid agent arrangement member 50 through an opening at one end of the outflow pipe 53 of the solid agent arrangement member 50, and at least a part of the bubble mixed water is in the solid agent arrangement member 50. The inflow pipe 54 is configured to flow into the solid agent arrangement chamber 55 of the solid agent arrangement member 50 through an opening at one end of the inflow pipe 54.
The solid agent arrangement member 50 of the nozzle 1 is configured to dissolve the solid agent 56 in the solid agent arrangement chamber 55 of the solid agent arrangement member 50 with the bubble mixed water and to flow out the bubble mixed water as a predetermined solution. The
Then, the nozzle 1 dissolves the solid agent 56 with the bubble mixed water flowing into the solid agent arrangement chamber 55 of the solid agent arrangement member 50 or the predetermined solution, and causes the solid agent arrangement member 50 to flow out as a predetermined solution. The predetermined solution is configured to be discharged from the opening 44 at the downstream end of the second cylindrical member 42.

As described above, the nozzle 1 is sucked when water flows out from the throttle hole 34 (throttle portion) of the throttle member 30 to the downstream side, and a predetermined liquid is at one end of the outflow pipe 53 of the solid agent arranging member 50. The solid agent arrangement member 50 (dissolving part 15) flows out through the opening, and at least a part of the bubble mixed water flows through the opening at one end of the inflow pipe 54 of the solid agent arrangement member 50. (Solution part 15) The solid agent arrangement | positioning member 50 comprised so that it may flow in in is comprised.
Therefore, according to the nozzle 1, the bubble mixed water (at least a part of the bubble mixed water) flows into the solid agent arrangement member 50 (dissolving part 15) more reliably than the conventional nozzle. Thus, the solid agent 56 arranged in the solid agent arrangement chamber 55 of the solid agent arrangement member 50 can be dissolved to form a predetermined solution, and a predetermined liquid can flow out of the solid agent arrangement member 50 (dissolution part 15).

The throttle member 30 of the nozzle 1 has a diffuser 38.
The diffuser 38 in the throttle member 30 of the nozzle 1 serves to weaken the water force of the bubble mixed water and diffuse the bubble mixed water. The diffuser 38 in the throttle member 30 of the nozzle 1 constitutes the diffusion unit 14.
The diffuser 38 in the throttle member 30 of the nozzle 1 is disposed so as to be positioned in the vicinity of the opening 36 on the downstream side of the throttle hole 34. The diffuser 38 in the throttle member 30 of the nozzle 1 is disposed so as to be located on the downstream side of the bottom 31 (the opening 36 on the downstream side of the throttle hole 34). The diffuser 38 in the throttle member 30 of the nozzle 1 is disposed so as to protrude downstream from the central portion (center side of the throttle hole 34) of the bottom portion 31 of the throttle member 30. The diffuser 38 in the throttle member 30 of the nozzle 1 is arranged so that the bubble mixed water comes into contact therewith.
The diffuser 38 in the throttle member 30 of the nozzle 1 is formed in a substantially conical shape. The diffuser 38 in the throttle member 30 of the nozzle 1 is formed in a tapered shape that spreads toward the downstream side.
The diffuser 38 in the throttle member 30 of the nozzle 1 is formed such that its downstream end (outer end) is located outside the throttle hole 34 (inner peripheral surface side of the second cylinder member 42). The diffuser 38 in the throttle member 30 of the nozzle 1 is formed such that the upstream slope is located on the extension line of the axial center of the throttle hole 34. The diffuser 38 in the throttle member 30 of the nozzle 1 is formed so that the upstream slope is located on an extension line in the outflow direction of the bubble mixed water flowing out from the throttle hole 34 of the throttle member 30.

In the nozzle 1 configured as described above, since the throttle member 30 has the diffusing body 38 (diffusion part 14), air bubbles mixed out from the throttle hole 34 (throttle part 12) of the throttle member 30 in the axial direction of the nozzle 1. The water comes into contact with the diffuser 38 of the throttle member 30.
In the nozzle 1, the bubble-mixed water is weakened by the bubble-mixed water coming into contact with the diffuser 38 in the throttle member 30.
However, in the nozzle 1, the water force immediately after flowing out from the throttle hole 34 of the throttle member 30 (water flowing in from the water outlet) is not weakened and flows out from the throttle hole 34 of the throttle member 30 to the downstream side. The suction power of the water to be used does not decrease.
For this reason, in the nozzle 1, the air can be reliably mixed into the water flowing out from the throttle hole 34 of the throttle member 30 (water whose water power is not weakened) in the air introduction portion 13.

As described above, the nozzle 1 can discharge the bubble-containing water while weakening the water force while preventing the amount of bubbles to be mixed from decreasing.
Therefore, according to the nozzle 1, it can prevent that the washing | cleaning target is damaged, preventing the washing | cleaning effect by bubble mixing water falling.

Further, in the nozzle 1, the bubble mixed water diffuses when the bubble mixed water comes into contact with the diffuser 38 in the throttle member 30 (see FIG. 5).
And in the nozzle 1, the said bubble mixed water diffuses and the discharge range of bubble mixed water spreads. At this time, in the nozzle 1, the bubble-mixed water in contact with the diffuser 38 in the throttle member 30 diffuses toward the downstream side, and the discharge range is expanded.
For this reason, according to the nozzle 1, compared with the conventional nozzle (nozzle that discharges bubble-mixed water in a streak shape), the object to be cleaned (the surface is soft and easily deformed, or the streaks are attached due to strong water. It is possible to easily perform a cleaning operation of a cleaning object) that can be sufficiently cleaned even if it cannot be peeled off.

Further, in the nozzle 1, the second cylindrical member 42 is located outside the downstream end of the diffuser 38 of the throttle member 30, and the opening 44 at the downstream end of the second cylindrical member 42 has the diffuser 38 of the throttle member 30. It is comprised so that it may be located in the downstream rather than the downstream end.
The second cylinder member 42 of the nozzle 1 is arranged so that the bubble mixed water diffused by contacting the diffuser 38 of the throttle member 30 contacts the inner peripheral surface (inner surface) of the second cylinder member 42. The second cylinder member 42 of the nozzle 1 is configured such that the bubble mixed water diffused by contacting the diffuser 38 of the throttle member 30 flows out from the opening 44 at the downstream end of the second cylinder member 42. .
In this way, the nozzle 1 is in contact with the inner peripheral surface of the second cylinder member 42 and the downstream end of the second cylinder member 42 when the bubble mixed water diffused by contacting the diffuser 38 of the throttle member 30. It is configured to be discharged from the opening 44 of the part.

For this reason, the nozzle 1 can discharge the bubble-mixed water that has diffused in contact with the diffuser 38 of the throttle member 30 toward the object to be cleaned in a state where the discharge range is widened (see FIG. 5).
Therefore, according to the nozzle 1, it is possible to reliably discharge the bubble-containing water whose strength is weakened and the discharge range is widened while preventing the amount of bubbles to be mixed from decreasing to the object to be cleaned.

The nozzle 1 is configured such that the middle portion of the second cylindrical member 42 is located outside the lower end portion of the diffuser 38 of the throttle member 30. The nozzle 1 is configured such that the second through-hole 43 of the second cylindrical member 42 is located outside the lower end portion of the diffuser 38 of the throttle member 30. In the nozzle 1, the bubble mixed water diffused in contact with the diffuser 38 of the throttle member 30 is solidified via the inflow pipe 54 (second through hole 43 of the second cylinder member 42) of the solid agent arranging member 50. It is configured to flow into the agent arrangement chamber 55 (dissolving part 15).
Therefore, according to the nozzle 1, it is possible to flow the bubble mixed water (at least a part of the bubble mixed water) into the solid agent arranging member 50 (dissolving portion 15) more reliably.

Next, the nozzle 1 which concerns on 2nd embodiment of this invention is demonstrated using FIG.
In addition, description of the nozzle 1 which concerns on 2nd embodiment is abbreviate | omitted suitably about the part of the structure similar to the nozzle 1 which concerns on 1st embodiment, and focuses on a different part from the structure of the nozzle 1 which concerns on 1st embodiment. explain.

  As shown in FIG. 6, the nozzle 1 includes a connection member 20, a throttle member 30, a first cylinder member 40, a second cylinder member 42, a solid agent arrangement member 50, and a solid agent 56. In addition, it is configured to discharge the bubble-containing water and discharge a predetermined solution.

The throttle member 30 of the nozzle 1 has a notch 37.
The notch 37 in the throttle member 30 of the nozzle 1 has a part of its outer peripheral surface (outer peripheral surface below the flange 32) excluding the flange 32 extending from the upper end to the lower end in the axial direction of the throttle member 30. Each is formed to be cut along.
In a state in which the throttle member 30 is inserted into the first cylindrical member 40 of the nozzle 1, the inner peripheral surface of the first cylindrical member 40 and the outer peripheral surface of the portion where the notch 37 of the throttle member 30 is not formed abut. However, a space is formed between the inner peripheral surface of the first cylindrical member 40 and the outer surface of the portion where the notch 37 of the aperture member 30 is formed.
In the nozzle 1, the air introduction portion 13 is configured by a space formed by the notch 37 of the throttle member 30 and the outer surface of the bottom portion 31 of the throttle member 30 and the inner peripheral surface of the first cylindrical member 40. .
In the nozzle 1, an opening at one end of the inflow pipe 54 of the solid agent disposing member 50 is configured as an opening 15 a at the inlet of the dissolving unit 15 and an opening 13 a at the inlet of the air introducing unit 13.

The nozzle 1 is sucked by water flowing out from the respective openings 36 on the downstream side of the throttle hole 34 (throttle portion 12) of the throttle member 30, and the air is one end of the inflow pipe 54 of the solid agent arranging member 50. From the opening (the inlet opening 13a of the air introduction part 13) into the solid agent arranging member 50 and out of the opening at one end part of the outflow pipe 53, and the opening at the lower end part of the notch 37 in the member 30 (air introduction). It is configured to flow out into the opening 13b) at the outlet of the part 13.
In this way, in the nozzle 1, air is introduced through the air introduction part 13 (the opening 13 a at the outlet of the air introduction part 13), and the introduced air is mixed to be downstream of the throttle hole 34. The water flowing out from the opening 36 on the side is configured to be bubble mixed water.

And the solid agent arrangement | positioning member 50 of the nozzle 1 dissolves the solid agent 56 in the solid agent arrangement | positioning chamber 55 of the solid agent arrangement | positioning member 50 with bubble mixing water, and flows out the said bubble mixing water as a predetermined solution. Composed.
Then, the nozzle 1 dissolves the solid agent 56 with the bubble mixed water flowing into the solid agent arrangement chamber 55 of the solid agent arrangement member 50 or the predetermined solution, and causes the solid agent arrangement member 50 to flow out as a predetermined solution. The predetermined solution is configured to be discharged from the opening 44 at the downstream end of the second cylindrical member 42.
Therefore, according to the nozzle 1, the bubble mixed water (at least a part of the bubble mixed water) flows into the solid agent arrangement member 50 (dissolving part 15) more reliably than the conventional nozzle. Thus, the solid agent 56 arranged in the solid agent arrangement chamber 55 of the solid agent arrangement member 50 can be dissolved to form a predetermined solution, and a predetermined liquid can flow out of the solid agent arrangement member 50 (dissolution part 15).

Next, the nozzle 1 which concerns on 3rd embodiment of this invention is demonstrated using FIG. 7 or FIG.
In addition, description of the nozzle 1 which concerns on 3rd embodiment abbreviate | omits suitably the part of the structure similar to the nozzle 1 which concerns on 1st embodiment or 2nd embodiment, and concerns on 1st embodiment or 2nd embodiment. A description will be given centering on portions different from the configuration of the nozzle 1.

  As shown in FIG. 7 or 8, the nozzle 1 includes a connection member 22, a water flow direction changing member 60, a throttle member 30, a rotating body 70, a first cylinder member 40, a second cylinder member 42, The solid agent arranging member 50 and the solid agent 56 are provided, and are configured to discharge a pulsating bubble-containing water and a predetermined solution.

The connection member 22 of the nozzle 1 is formed in a substantially cylindrical shape with its upstream end and downstream end opened.
The upstream side portion of the connection member 22 of the nozzle 1 is configured as the inflow portion 11. The upstream side portion of the connection member 22 of the nozzle 1 is configured to be connectable to the water outlet.

The water flow direction changing member 60 of the nozzle 1 is disposed on the downstream side of the connection member 22.
The water flow direction conversion member 60 of the nozzle 1 converts the water flow direction of the water flowing out from the connection member 22.
The water flow direction converting member 60 of the nozzle 1 is formed in a substantially cylindrical shape with a bottom end 61 having an upstream end and a bottom 61 at the downstream end.

The water flow direction changing member 60 of the nozzle 1 is configured by forming a flange 62 at its upstream end. The flange 62 in the water flow direction changing member 60 of the nozzle 1 is formed so as to protrude sideways.
The water flow direction changing member 60 of the nozzle 1 has a convex portion 65. The convex portion 65 in the water flow direction changing member 60 of the nozzle 1 is formed so as to protrude downstream from the center portion of the bottom portion 61.
The water flow direction changing member 60 of the nozzle 1 is configured such that its downstream side portion (portion downstream from the flange 62) can be inserted into the throttle member 30 from the opening at the upstream end portion of the throttle member 30.

The water flow direction changing member 60 of the nozzle 1 has a through hole 63.
The through-hole 63 in the water flow direction changing member 60 of the nozzle 1 is 180 degrees out of phase in the circumferential direction (at a position facing the center of the axis of the water flow direction changing member 60), and its upper and lower halfway (upstream side) Between the first portion and the downstream portion). The through holes 63 in the water flow direction changing member 60 of the nozzle 1 are respectively formed so as to penetrate (in the radial direction) from the outer peripheral surface of the midway portion of the water flow direction changing member 60 to the inner peripheral surface.

The water flow direction changing member 60 of the nozzle 1 has a notch 64.
The notches 64 in the water flow direction changing member 60 of the nozzle 1 are respectively formed so as to be shifted in phase by 180 degrees in the circumferential direction (at positions facing the axis of the water flow direction changing member 60 as the center). The notch 64 in the water flow direction changing member 60 of the nozzle 1 is formed so that the downstream surface of the bottom portion 61 and the outer peripheral surface of the middle portion are notched. The notch 64 in the water flow direction changing member 60 of the nozzle 1 is formed so as to extend from the bottom 61 to one through hole 63 of the two through holes 63.

The nozzle 1 is configured by arranging the connecting member 22 and the water flow direction changing member 60 so that the upstream side end of the water flow direction changing member 60 abuts on the downstream side end of the connecting member 22. The nozzle 1 is configured by fixing a water flow direction changing member 60 to a connecting member 22. In a state where the connection member 22 of the nozzle 1 and the water flow direction changing member 60 are arranged, the connection member 22 and the water flow direction changing member 60 are in communication with each other.
The nozzle 1 is configured such that water flowing out from the opening at the downstream end of the connection member 22 flows into the water flow direction changing member 60 from the opening at the upstream end of the water flow direction changing member 60.

The nozzle 1 is configured such that a portion on the downstream side of the flange 62 in the water flow direction changing member 60 is inserted into the upstream side portion of the throttle member 30 from the opening at the upstream end portion of the throttle member 30.
In a state where the water flow direction changing member 60 of the nozzle 1 is fitted into the throttle member 30, the inside of the water flow direction changing member 60 and the inside of the throttle member 30 are connected via the through hole 63 and the notch 64 of the water flow direction changing member 60. It becomes a state of communication.

In the nozzle 1, the water flowing in from the opening at the upstream end of the water flow direction changing member 60 flows into the throttle member 30 through the through hole 63 and the notch 64, and enters the throttle hole 34 of the throttle member 30. Each downstream opening 36 is configured to flow out.
In the nozzle 1, the water flowing from the connecting member 22 into the water flow direction changing member 60 flows through the through hole 63 and the notch 64 of the connecting member 22, so that the water flow direction of the water enters the water flow direction changing member 60. From the inflow direction (axial direction of the water flow direction changing member 60) to the circumferential direction and to flow into the throttle member 30.
In other words, the nozzle 1 is configured such that the water flowing out from the water flow direction changing member 60 is converted into a water flow direction and flows into the throttle member 30 as a spiral water flow (clockwise water flow in a plan view).

  The rotating body 70 of the nozzle 1 rotates so as to sequentially close and open the opening 35 upstream of the throttle hole 34 (throttle portion 12) of the throttle member 30 for each of the adjacent throttle holes 34. 34 (squeezing part 12) intermittently blocks the inflow of water.

  The rotating body 70 of the nozzle 1 is configured in such a shape that a disk-like member is provided in the center portion in the axial center direction of the rod-like member so that the respective shaft centers coincide with each other. Both end portions of the rod-shaped portion of the rotating body 70 of the nozzle 1 are each formed in a hemispherical shape.

The rotating body 70 of the nozzle 1 is disposed in the throttle member 30 so that the axis of the rod-shaped portion is inclined. The rotating body 70 of the nozzle 1 is arranged on the outer side of the convex portion 65 of the water flow direction changing member 60 with one end portion 71 (upstream side portion) of the rod-shaped portion facing the outer peripheral side with respect to the other end portion 72 (downstream side portion). At the same time, the other end portion 72 of the rod-shaped portion is disposed in the concave portion 33 of the throttle member 30.
The rotating body 70 of the nozzle 1 is configured to be rotatable so as to change the direction in which the axis of the rod-shaped portion is inclined. In the rotating body 70 of the nozzle 1, the one end 71 of the rod-shaped portion is located along the inner peripheral surface of the throttle member 30 with the other end 72 of the rod-shaped portion positioned in the recess 33 of the throttle member 30. It arrange | positions in the aperture member 30 rotatably so that it may move around the convex part 65 of this.

The rotating body 70 of the nozzle 1 is configured to rotate in the throttle member 30 when the water flow direction is changed by the water flow direction changing member 60 and a spiral water flow is received by the disk-shaped portion of the rotating body 70. The
At this time, in the nozzle 1, when the rotating body 70 rotates and the other end portion 72 of the rod-shaped portion is positioned on the opening 35 on the upstream side of the throttle hole 34 in the throttle member 30, the other end portion of the rod-shaped portion. At 72, the opening 35 on the upstream side of the throttle hole 34 in the throttle member 30 is closed.
In the nozzle 1, when the rotating body 70 further rotates and passes through the opening 35 on the upstream side of the throttle hole 34 of the throttle member 30, the opening 35 on the upstream side of the throttle hole 34 is opened.

When the rotating body 70 rotates, the nozzle 1 closes and opens the opening 35 upstream of the throttle hole 34 in the throttle member 30 at the other end 72 of the rod-shaped portion of the rotating body 70. It is comprised so that it may carry out sequentially.
The nozzle 1 is configured to intermittently block the inflow of water into the throttle hole 34 in the throttle member 30 as the rotating body 70 rotates.
In this way, the nozzle 1 intermittently blocks the flow of water into the throttle hole 34 (throttle portion 12) in the throttle member 30 by the rotation of the rotating body 70, and a plurality of throttles in the throttle member 30. The throttling hole 34 into which water flows in is changed intermittently in the hole 34 so that water that pulsates flows out from the opening 36 on the downstream side of the throttling hole 34.
The nozzle 1 mixes the pulsating water with the air introduced from the air outlet of the air introduction unit 13 and discharges the pulsating water as pulsating bubble mixed water. At the same time, it is configured to discharge a predetermined solution.

In the nozzle 1 configured as described above, when the pulsating bubble mixed water is discharged to the object to be cleaned, the contacted cleaning object for discharging the pulsating bubble mixed water to the object to be cleaned is in the bubble mixed water. In addition to the cleaning effect of the bubble mixed water, the cleaning is also performed by the vibration of the bubble mixed water that pulsates.
In this way, the nozzle 1 can improve the cleaning effect of the bubble mixed water to be discharged from now on.

DESCRIPTION OF SYMBOLS 1 Nozzle 11 Inflow part 12 Restriction part 13 Air introduction part 14 Diffusion part 15 Dissolution part 20 Connection member 30 Restriction member 41 1st cylinder member 42 2nd cylinder member 50 Solid agent arrangement | positioning member 56 Solid agent

Claims (3)

An inflow section into which water flows,
A constriction part for constricting the flow of water flowing in from the inflow part to increase the flow rate of the water;
A dissolving part configured to dissolve the solid agent by water flowing out from the throttle part to the downstream side, and to flow out the water as a predetermined solution;
Comprising a nozzle configured to discharge the water and discharge the predetermined solution,
The dissolving portion is sucked when at least a part of the water flowing out from the restricting portion flows into the dissolving portion and the water flows out from the restricting portion toward the downstream side, so that the predetermined liquid is Configured to flow out of the dissolution zone,
nozzle. Comprising a diffusing portion configured to diffuse when the water flowing out from the throttle portion contacts the downstream side,
The nozzle according to claim 1. It is configured in a cylindrical shape, and is arranged so that the water that has diffused in contact with the diffusing portion contacts the inner surface thereof, and the water that has contacted the inner surface from the opening of the downstream end portion Comprising a tubular member configured to flow out,
The nozzle according to claim 2.

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