JP5793518B2 - Watering nozzle - Google Patents

Description

  The present invention is mainly used for horticulture, agriculture, cleaning, etc. at home, etc., and in a watering nozzle that is connected to the tip of a water supply facility such as a water supply via a hose to perform watering at a low speed and a thick shape. Related to the structure.

  At home, watering nozzles that are attached to the tip of a hose and can be arbitrarily switched between watering and water stopping are widely used for gardening, agriculture, cleaning, and the like. Such a watering nozzle receives water from a water supply facility such as a water supply via a hose and sprays water from a discharge port formed at the tip.

As in Patent Document 1, the conventional watering nozzle includes a substantially cylindrical grip portion extending upward from a base end portion connected to the hose, and a substantially cylindrical nozzle portion extending forward from a substantially upper end of the grip portion. And has a nozzle body formed in a bent shape such as an L shape, a dogleg shape, or a pistol shape as a whole (see FIG. 1).
As shown in FIG. 8, the discharge port formed at the tip of the nozzle portion includes a straight discharge port 5 a composed of one round discharge port, a shower discharge port composed of many small holes, and a vertically long discharge port. There was a fan-shaped discharge port, and the water discharge shape could be switched according to the application.
In some cases, the water-type adjustment core 23 is arranged in the center of the straight discharge port 5a, and the water-type adjustment core 23 approaches the straight discharge port 5a to form a mist-like water discharge shape.

In the conventional watering nozzle, the flow path 10 to the straight discharge port 5a has a small flow resistance, and is formed in a shape that allows water to pass without causing turbulent flow. It was in shape. With such a water discharge shape, it was possible to wash away dirt in the range targeted for car washing and cleaning applications.
However, in horticultural applications such as supplying water to watering cans or pitchers, or watering potted plants or ground-planted plants, the water force is too strong in the high-speed and thin water discharge shape as described above, and water splashes from watering cans and pitchers. Happened, the soil at the base of the plant was washed away, the ground was crushed, and the plant was damaged.

In addition, in sprinkling with shower outlets or sprinkling with a plurality of horizontally long outlets arranged in a ring on the outside of the shower outlet, the watering range is too wide and spills from small watering cans, jugs and pot plants. It was.
Therefore, in the watering nozzle mainly used for horticulture, in order to suppress the water force and secure a large amount of water discharge, it has been required to spray a thick shape at a low speed with a straight discharge port of a limited area. .

Japanese Examined Patent Publication No. 4-77621

  However, the flow rate of the watering nozzle increases when the water passes through a narrow area such as the flow path of the discharge switching valve that switches between the straight discharge port and the shower discharge port. Even if the aperture is formed large, the water discharge shape is disturbed at a high speed because high-speed water hits the water shape adjusting core.

  This invention is made | formed in order to solve the said problem, and makes it a subject to provide the watering nozzle which has the straight discharge port which can perform watering of a thick shape at low speed.

In the present invention, means for solving the above problems are as follows.
The first invention is a watering nozzle having a connection port for introducing water, an internal channel through which water taken from the connection port passes, and a water discharge port formed at the tip of the channel. In the flow path, a dam part that collides part of the water and reduces the flow velocity is provided, and on the upstream side of the dam part, there is a stay part where a part of the water that passes through the flow path stays. It is formed.

  The second invention is characterized in that a diverting member for diverting water to the dam portion side is provided in the flow path upstream of the dam portion.

  According to the first aspect of the present invention, a dam part that collides with a part of water to reduce the flow velocity is provided in the flow path, and a part of the water that passes through the flow path is provided upstream of the dam part. By forming a staying portion where the water stays, thick sprinkling can be performed at a low speed from the discharge port.

  According to the second aspect of the present invention, by providing a diverting member that diverts water to the dam portion side in the flow path upstream of the dam portion, the amount of water colliding with the dam portion is reduced. You can increase the watering speed at a slower speed.

It is a longitudinal cross-sectional view which shows the watering nozzle which concerns on 1st embodiment of this invention. It is a partial expanded longitudinal cross-sectional view which shows the straight discharge outlet vicinity of the watering nozzle. It is a longitudinal cross-sectional view which shows the straight discharge outlet vicinity which concerns on 2nd embodiment of this invention. It is a longitudinal cross-sectional view which shows the straight discharge outlet vicinity which concerns on 3rd embodiment of this invention. It is a longitudinal cross-sectional view which shows the straight discharge outlet vicinity which concerns on 4th embodiment of this invention. It is a longitudinal cross-sectional view which shows the straight discharge outlet vicinity which concerns on 5th embodiment of this invention. It is a longitudinal cross-sectional view which shows the straight discharge outlet vicinity which concerns on 6th embodiment of this invention. It is a longitudinal cross-sectional view which shows the straight discharge outlet vicinity of the conventional watering nozzle.

Hereinafter, the watering nozzle which concerns on 1st embodiment of this invention is demonstrated.
This watering nozzle 1 is an instrument that performs watering by being connected to the tip of a water supply facility such as water supply via a hose in horticulture, agriculture, cleaning, and other uses. It is.

As shown in FIG. 1, the watering nozzle 1 includes a grip portion 3 formed in a substantially cylindrical shape that extends upward from a base end portion that is connected to a hose or the like to form a connection port 2 for introducing water, and the grip portion. The nozzle portion 4 extends forward from the upper end of the nozzle 3 and has discharge ports 5a, 5b, and 5c formed at the tip thereof. The grip portion 3 and the nozzle portion 4 are continuously formed in an L shape, a dogleg shape, or a pistol shape as a whole. It has a nozzle body 6 formed in a bent shape that is bent at a site.
In the present specification, the front and rear in the description of the nozzle part 4 mean the extending direction of the nozzle part 4, the front means the discharge ports 5a, 5b and 5c side of the nozzle part 4, and the rear means the grip part 3 side. To do. Further, in the description of the grip part 3, “up and down” means up and down with respect to the ground in a state where the nozzle part 4 is parallel to the ground and the connection port of the grip part 3 is directed to the ground side. The upper side, that is, the nozzle portion 4 side means the lower side, and the lower side means the ground side, that is, the connection port 2 side.
A water flow path 10 extending from the connection port 2 to the discharge ports 5a, 5b, and 5c is formed inside the nozzle body 6.

  The nozzle body 6 is formed by connecting a hose nipple 8 to a bent water pipe 7 and assembling a plurality of covers covering the outer periphery, but some of them may be integrally formed. A water discharge head 9 is attached to the tip of the nozzle body 6 so as to be movable back and forth around the screw.

The grip portion 3 is formed in a substantially cylindrical shape that extends upward from the base end portion toward the nozzle portion 4, and can be gripped and handled by the user.
At the base end portion of the grip portion 3, an unevenness and an O-ring are provided on the outer peripheral surface for connection with a receiving device (not shown) attached to the hose, and a connection port for introducing water from the water supply facility to the center thereof A hose nipple 8 having an opening 2 is attached below the water pipe 7.
The orientation of the grip portion 3 may be perpendicular to the extending direction of the nozzle portion 4, but as shown in FIG. And may extend in a crossing direction.
The nozzle part 4 is formed in a substantially cylindrical shape extending forward from the upper end of the grip part 3 (on the water spout side of the nozzle part 4).

The watering nozzle 1 has a water stop valve that switches between water flow and water stop and a flow rate adjustment valve that increases or decreases the flow rate of water passing through the flow path in the flow path of the water flow pipe 7.
The water stop valve is provided on the upstream side of the flow rate adjustment valve, and has a water stop valve body 11 disposed in the flow path 10 on the grip portion 3 side of the water flow pipe 7. The water stop valve body 11 is formed in a covered cylindrical shape inscribed in the water flow pipe 7, and a protruding valve body portion 11a is formed on the cover. O-rings 11c and 11c are arranged at two locations on the outer peripheral surface of the water stop valve body 11 so that water does not flow on the outer periphery of the water stop valve body 11, and the O ring 11c passes through the outer peripheral surface above the O ring 11c. The water port 11b is formed. The water supplied from the base end (downward) of the water flow pipe 7 passes through the inside of the water stop valve body 11, flows out from the water flow port 11b, and flows downstream.

  The valve body portion 11 a of the water stop valve body 11 is formed with a larger diameter than the water stop valve seat 7 a provided in the water flow pipe 7 and is interposed between the hose nipple 8 and the water stop valve body 11. 12 urges the water stop valve seat 7a to close the flow path 10 (water stop state). When the valve body portion 11a is separated from the water stop valve seat 7a against this urging force, the flow path 10 is opened and water passes through (water passing state).

In order to operate the water stop valve body 11, a water stop operation lever 13 is attached in front of the grip portion 3. The water stop operating lever 13 is attached to the lower part of the grip part 3 with the lower end as a fixed end, and the upper end is a free end. Therefore, when the user holds the grip part 3 with a hand holding the grip part 3, the lower end becomes the fixed end. It can be rotated in the direction.
The water flow pipe 7 has an opening 7b on the front surface of the grip portion 3 side portion. A valve opening / closing arm 14 having an L-shaped vertical cross section is in contact with the water stop operating lever 13 at one end, is in contact with the water stop valve body 11 at the other end, and is connected to the water flow pipe 7 with an L-shaped bent portion as a fulcrum. When the user grasps the water stop operation lever 13 because it is pivotally supported, the water stop valve body 11 is moved through the valve opening / closing arm 14 against the biasing force of the coil spring 12. It can be separated from 7a and can be in a water-permeable state.
Since the opening 7b of the water flow pipe 7 is always located between the two O-rings 30c, 30c of the water stop valve body 11, water does not leak from the opening 7b to the outside of the water flow pipe 7.

A flow rate adjusting valve capable of adjusting the amount of water spray is provided in the flow path 10 at the bent portion of the water flow pipe 7 on the downstream side of the water stop valve.
The flow rate adjusting valve is disposed in the flow path and rotates to increase or decrease the flow rate of water. The flow rate adjusting valve 15 is interlocked with the flow rate adjusting valve body 15 and protrudes from the rear upper part of the grip portion 3. It comprises a flow rate operation member 16 that is rotated in the left-right direction with the thumb.
The flow rate adjusting valve body is formed in a covered cylindrical shape whose lower end is always open to the flow path 10 of the grip portion 3, and a notch for flow rate adjustment is provided on the peripheral surface.
In this flow rate adjustment valve, the amount of water spray can be adjusted by increasing or decreasing the area where the notch formed in the flow rate adjustment valve body 15 and the flow path 10 of the nozzle portion 4 match.

As shown in FIGS. 1 and 2, the watering nozzle 1 has a straight discharge port 5a, a shower discharge port 5b, and a mist-like discharge port 5c.
The shower discharge port 5 b includes a large number of small holes formed in the screen 17 at the tip of the water discharge head 9.
As shown in FIG. 2, the straight discharge port 5 a is a circular outlet formed at the center of the screen 17 of the water discharge head 9. Therefore, the area of the straight discharge port 5a is limited to a predetermined size or less in relation to the shower discharge port 5b.
The mist-like discharge port 5c is a small hole provided at the tip of the nozzle body 6, and is disposed on the upstream side of the straight discharge port 5a.

In order to perform sprinkling of a thick shape at a low speed from the straight discharge port 5a, a dam portion 18 that protrudes perpendicularly to the flow channel direction toward the center of the flow channel 10 is provided at the edge of the straight discharge port 5a. ing.
As a result, a staying portion 19 in which a part of the water passing through the flow path stays is formed on the upstream side of the weir portion 18.
The stay part 19 and the other part of the flow path 10 are continuous without being partitioned by a special partition or an orifice.

In the first embodiment, the inner diameter A of the flow path 10 of the dam portion 18 is set to 11.6 mm. On the other hand, the inner diameter B of the flow path 10 before the dam portion 18 is set to 13.8 mm. That is, the protruding height of the weir portion 18 toward the center of the flow path is set to 1.1 mm.
The heights of A and B and the dam portion 18 may be set to appropriate values according to the use environment such as tap water pressure and the flow path resistance of other portions of the water spray nozzle 1.
Under the condition that the tap water pressure is 0.2 MPa, the inner diameter A of the flow path 10 of the weir portion 18 is preferably set to 5 to 100 mm.
On the other hand, if A is less than 5 mm, the cross-sectional area of the flow path becomes too small and the flow velocity increases. A is more preferably 8 mm or more, and particularly preferably 10 mm or more.
When A is larger than 100 mm, the disturbed water discharge shape becomes difficult to converge, and it takes a long time from the start of water spraying from the straight discharge port 5a until the water shape is stabilized at a low speed. A is more preferably 50 mm or less, and particularly preferably 15 mm or less.
In the first embodiment, A is set to 11.6 mm.

The inner diameter B of the flow path 10 before the weir part 18 is preferably set to 5 to 100 mm within a range of B> A.
If B is less than 5 mm, the flow path cross-sectional area becomes too small and the flow velocity increases. B is more preferably 8 mm or more, and particularly preferably 10 mm or more.
Further, if B is larger than 100 mm, the apparatus becomes large and difficult to handle. B is more preferably 50 mm or less, and particularly preferably 20 mm or less.
In the first embodiment, B is set to 13.8 mm.

It is preferable that the height 1/2 (BA) of the weir part 18 is set to 0.1 to 10 mm.
If the height of the weir part 18 is less than 0.1 mm, the weir part 18 is too small to dam up the water so that the stay part 19 cannot be filled, and the flow rate cannot be reduced. The weir portion is more preferably 0.5 mm or more, and particularly preferably 1.0 mm or more.
Moreover, if the height of the weir part 18 is larger than 10 mm, the amount of water charged in the staying part becomes too large, resulting in turbulent flow, and it takes time from the start of sprinkling to stabilize at a low speed and a large water discharge shape. End up. The height of the weir portion 18 is more preferably 5 mm or less, and particularly preferably 3 mm or less.
In the first embodiment, the height of the weir portion 18 is set to 1.1 mm.

As shown in FIG. 1, the watering nozzle 1 is provided with a discharge switching valve that switches between watering from the straight outlet 5a, watering from the shower outlet 5b, and watering from the mist-like outlet 5c. .
The flow channel 10 reaches the switching port 20 of the nozzle body 6 and branches downstream of the switching port 20 into an outer flow channel 22 communicating with the shower discharge port 5b and an inner flow channel 21 communicating with the straight discharge port 5a. Yes. The water discharge head 9 moves back and forth about the nozzle body 6 around the screw, and either the inner flow path 21 or the outer flow path 22 is selectively connected to the upstream switching port 20, so that the straight discharge port 5 a Can be switched between water spraying from the shower and water spraying from the shower outlet 5b.
Further, at the position where the water discharge head 9 is most retracted, the tip of the nozzle portion 4 and the inner wall of the water discharge head 9 come into contact with each other to close the inner flow path 21, and water enters the spiral flow path 25 to form a mist-like discharge port. Water is sprayed from 5c in a mist form (see FIG. 2).

In the watering nozzle 1 of the first embodiment, when water spraying from the straight discharge port 5a is started in a state where there is no water in the inner flow path 21, a part of the water passing through the flow path 10 collides with the weir part 18. The flow velocity is reduced, and the turbulent flow is retained in the staying portion 19 and flows along the inner wall of the flow path. Therefore, the water discharge shape is less likely to be disturbed, and the spout has a low speed and a large water spray from the straight discharge port 5a. It can be performed.
When the flow rate of water is relatively high, the water that collides with the weir portion 18 and turbulently collects in the entire retention portion 19 and stays below the flow path 10 even when the flow rate of water is relatively low. The part 19 is filled with water.
After the water has accumulated in the staying part 19, water having a high flow rate passing through the flow path 10 collides with the staying water in the staying part 19 or the viscosity of the staying water works, so that the water flow rate decreases, Thick watering can be performed at low speed from the discharge port 5a.

<Second embodiment>
In the second embodiment, as shown in FIG. 3, instead of providing the mist-like discharge port 5c, a water-type adjustment core 23 formed at the tip of the nozzle body 6 is arranged at the center of the straight discharge port 5a. It has become.
At the distal end of the water shape adjusting core 23, a conical shade portion 23a that is thicker than the proximal end side is formed. The cap portion 23a is formed in front of the straight discharge port 5a.
When the water discharge head 9 is operated and moved backward, the shade portion 23a approaches the straight discharge port 5a, and water hits the shade portion 23a and is diffused in a mist form.

In the second embodiment, since the water shape adjusting core 23 is provided, the inner diameter A of the flow path of the dam portion 18 and the inner diameter B of the flow path before the dam portion 18 are set larger than those of the first embodiment, It is preferable that the cross-sectional area of the channel at the position of the dam portion 18 and the cross-sectional area of the channel before the dam portion 18 are equal to those in the first embodiment.
The channel cross-sectional area C at the position where the weir part 18 is formed is preferably set to 50 to ²⁰⁰ mm ² .
When the flow path cross-sectional area C is less than 50 mm ² , the flow velocity increases. The channel cross-sectional area C is more preferably 75 mm ² or more, and particularly preferably 100 mm ² or more.
On the other hand, if the flow path cross-sectional area C is larger than 200 mm ² , the flow path is too wide, and the flow rate is not sufficiently lowered due to the retention of water in the retention portion 19. The channel cross-sectional area C is more preferably 150 mm ² or less, and particularly preferably 120 mm ² or less.
In the second embodiment, the channel cross-sectional area C is set to 110 mm ² .

The channel cross-sectional area D of the channel 10 before the weir part 18 is preferably set to 50 to 300 mm ² in a range that is larger than the channel cross-sectional area C at the position where the weir part 18 is formed.
If the flow path cross-sectional area D is less than 50 mm ² , the flow velocity increases. The channel cross-sectional area D is more preferably 100 mm ² or more, and particularly preferably 125 mm ² or more.
On the other hand, if the flow path cross-sectional area D is larger than 300 mm ² , the flow path is too wide and the flow rate is not sufficiently lowered due to the water staying in the staying part 19. The channel cross-sectional area D is more preferably 200 mm ² or less, and particularly preferably 175 mm ² or less.
In the second embodiment, the channel cross-sectional area D is set to 150 mm ² .

<Third embodiment>
In the first embodiment, the dam portion 18 is provided in the straight discharge port 5a. However, the dam portion 18 may be provided in the flow path 10 upstream of the straight discharge port 5a.
In the third embodiment, as shown in FIG. 4, a weir portion 18 whose diameter is reduced in a stepped shape is provided in the flow channel 10 upstream of the straight discharge port 5 a.

The channel cross-sectional area E of the channel downstream from the weir part 18 is preferably set to 50 to 300 mm ² .
When the flow path cross-sectional area E is less than 50 mm ² , the flow velocity increases. The channel cross-sectional area E is more preferably 100 mm ² or more, and particularly preferably 125 mm ² or more.
On the other hand, if the flow path cross-sectional area E is larger than 300 mm ² , the flow path is too wide and the flow rate is not sufficiently lowered due to the water staying in the staying part 19. The channel cross-sectional area E is more preferably 200 mm ² or less, and particularly preferably 175 mm ² or less.
In the third embodiment, the flow path cross-sectional area E is set to 150 mm ² .

Also in the watering nozzle 1 of the third embodiment, when watering from the straight discharge port 5a is started, a part of the water passing through the flow path 10 collides with the weir part 18 to be turbulent, and the staying part 19 Therefore, thick sprinkling can be performed at a low speed from the straight discharge port 5a.
In addition, after water has accumulated in the staying part 19, water having a high flow rate passing through the flow path 10 collides with the staying water in the staying part 19 or the viscosity of the staying water works, so that the water flow rate decreases. Thick watering can be performed at a low speed from the straight discharge port 5a.

Further, when the dam portion 18 is provided in the straight discharge port 5a, the area of the straight discharge port 5a is limited because the shower discharge port 5b is provided, and the shape of the dam portion 18 is also limited. By providing the weir portion 18 in the flow path 10 upstream of 5a, the layout restriction of the shape of the weir portion 18 is reduced, and the height of the weir portion 18 can be set high. If the height of the weir part 18 is set high, the amount of water colliding with the weir part 18 and the amount of staying water in the staying part 19 are increased, so that the flow velocity can be further reduced.
However, if the weir portion 18 is made too high and the cross-sectional area of the flow path 10 is made too small, the inner diameter of the flow path 10 becomes small and the flow velocity gradually increases, so it is necessary to set an appropriate value. .
In addition, the weir portion 18 is provided in the flow path 10 upstream from the straight discharge port 5a as in the third embodiment, and the weir portion 18 is also provided at the edge of the straight discharge port 5a as in the first embodiment. Alternatively, see FIG.

<Fourth embodiment>
In the first embodiment, the dam portion 18 that protrudes perpendicular to the flow path direction is provided, but the protrusion angle of the dam portion 18 is not limited to 90 degrees with respect to the flow path direction.
As shown in FIG. 5, the fourth embodiment is characterized in that a dam portion 18 is provided in the flow path 10 upstream from the straight discharge port 5a, and the dam portion 18 is inclined and protrudes upstream. To do.
The angle θ between the channel 10 and the weir portion 18 is preferably 45 degrees or more and 120 degrees or less.
If θ is smaller than 45 degrees, the flow resistance becomes too large, turbulence occurs, and the shape of water discharged from the straight outlet 5a may be disturbed. It is more preferable to set θ to 60 ° or more, and in order to make the apparatus compact, prolong the mold life, improve drainage and prevent the generation of algae, etc. Is preferred.
If θ is greater than 120 degrees, water flows along the weir part 18, so that the staying part 19 is not formed and the flow velocity cannot be reduced. θ is more preferably 100 degrees or less, and in order to effectively reduce the flow rate by filling the staying portion 19 with water, it is particularly preferably 90 degrees or less.

<Fifth embodiment>
As shown in FIG. 6, the fifth embodiment is characterized in that the dam portion 18 is provided on the upstream side of the straight discharge port 5 a and the staying portion 19 is expanded in the radial direction of the flow path 10.
In the fifth embodiment, the flow path 10 serving as the staying part 19 is expanded by causing the peripheral wall of the flow path 10 to bulge radially outward in the immediate vicinity of the upstream side of the weir part 18. Accordingly, the area of the dam portion 18 is also increased.
Thereby, since the quantity of the water which collides with the dam part 18 and the quantity of the staying water of the staying part 19 become large, a flow rate can be reduced further.

<Sixth embodiment>
As shown in FIG. 7, the sixth embodiment is characterized in that a water shape adjusting core 23 is provided and a direction changing member 24 is provided on the water shape adjusting core 23.
In this watering nozzle 1, an annular diverting member 24 is provided in a radial direction perpendicular to the flow path 10 from an intermediate position of the water shape adjusting core 23. The diverting member 24 is disposed in the flow path 10 upstream of the weir portion 18 and the staying portion 19 when water is sprayed from the straight discharge port.

  When water spraying from the straight discharge port 5 a is started, the direction of the water is changed to the dam portion 18 by hitting the deflecting member 24 when passing through the flow path 10. Therefore, the amount of water that collides with the dam portion 18 increases, and the rate of decrease in the flow rate caused by the collision with the dam portion 18 and the rate of decrease in the flow rate caused by the collision with the accumulated water in the staying portion 19 can be further improved.

  The higher the protruding height of the deflecting member 24, the more effective the direction of water is. However, if the height is set too high and the cross-sectional area of the flow path becomes too small, the flow velocity increases. For this reason, the flow direction cross-sectional area F at the formation position of the direction change member 24 is changed so as to be larger than the flow path cross-sectional area at the position where the flow path cross-sectional area is the smallest in the flow path 10 upstream of the direction change member 24. It is preferable to limit the height of the member 24.

It is preferable to set the flow path cross-sectional area F at the formation position of the deflecting member 24 to 50 to 300 mm ² .
If the flow path cross-sectional area F is less than 50 mm ² , the flow velocity increases. The flow path cross-sectional area F is more preferably 100 mm ² or more, and particularly preferably 125 mm ² or more.
On the other hand, if the flow path cross-sectional area F is larger than 300 mm ² , the flow path is too wide, and the flow rate is not sufficiently lowered due to the retention of water in the retention portion 19. The channel cross-sectional area F is more preferably 200 mm ² or less, and particularly preferably 175 mm ² or less.
In the second embodiment, the flow path cross-sectional area F is set to 150 mm ² .

DESCRIPTION OF SYMBOLS 1 Watering nozzle 2 Connection port 3 Grip part 4 Nozzle part 5a Straight discharge port 5b Shower discharge port 5c Mist discharge port 6 Nozzle body 7 Water pipe 7a Water stop valve seat 7b Opening 8 Hose nipple 9 Water discharge head 10 Flow path 11 Stop Water valve body 11a Valve body portion 11b Water passage port 11c O-ring 12 Coil spring 13 Water stop operation lever 14 Valve opening / closing arm 15 Flow rate adjusting valve body 16 Flow rate operation member 17 Screen 18 Weir part 19 Retaining part 20 Switching port 21 Inner flow path 22 Outer channel 23 Water shape adjusting core 23a Shaping part 24 Turning member 25 Spiral channel

Claims (2)

A watering nozzle having a connection port for water introduction, an internal channel through which water taken from the connection port passes, and a water discharge port formed at the tip of the channel,
In the above flow path, a weir part that reduces the flow velocity due to collision of water is provided,
On the upstream side of the weir part, a retention part where part of the water passing through the flow path is retained is formed , and
A watering nozzle characterized in that the staying portion is expanded in a radial direction with respect to a flow path immediately upstream thereof . A watering nozzle having a connection port for water introduction, an internal channel through which water taken from the connection port passes, and a water discharge port formed at the tip of the channel,
In the above flow path, a weir part that reduces the flow velocity due to collision of water is provided,
On the upstream side of the weir part, a retention part where part of the water passing through the flow path is retained is formed, and
In the flow path on the upstream side of the dam part, a direction changing member for turning water to the dam part side is provided ,
In addition, the flow passage cross-sectional area at the formation position of the diverting member is formed larger than the flow cross-sectional area at the position where the flow cross-sectional area is the smallest in the flow path upstream of the diverting member . dispersion water nozzle that.

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