JP2015173999A - Mist sprinkler - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mist sprinkler capable of surely switching water stopping and water discharging by an operation at a tip.SOLUTION: In a mist sprinkler comprising: a body part 3 connected to the supply source of a fluid; a mist discharge member 2 detachably connected to the body part 3 and formed with a spray port 21 discharging the fluid; a main channel passing the fluid from the body part 3 to the mist discharge member 2; a seal member 6 being disposed in the main channel and capable of sealing the main channel by being sandwiched between the body part 3 and the mist discharge member 2; and a bypass channel 31c passing the fluid by being branched from the main channel and capable of reducing the pressure of the fluid deforming or displacing the seal member 6 when opening and closing the main channel, natural water stopping caused by the deformation or displacement of the seal member 6 is prevented.

Description

  INDUSTRIAL APPLICABILITY The present invention is used for mist cooling that lowers the ambient temperature with the heat of vaporization of sprayed water, mist spraying on plants, spraying by spraying, and the like, and spraying water in a mist form (hereinafter sometimes referred to as spraying). The present invention relates to a mist watering device that can perform.

Conventionally, a mist nozzle that is connected to a water supply device such as a water supply facility and can spray supplied water has been widely used.
With a mist nozzle that needs to be connected to a water supply facility as in Patent Document 1, spraying cannot be performed in a place where there is no water supply device.
In addition, since the mist nozzle of Patent Document 1 does not have a mechanism for switching between water stopping and water discharging, there is no choice but to switch between water stopping and water discharging by operating an upstream water supply facility or the like.

In addition, sprayers that use compressed gas such as chlorofluorocarbon gas or LPG gas as spray power, or motors such as motor pumps and compressors have been widely used.
However, in a sprayer using Freon gas or LPG gas as the spraying power, these gases are released into the atmosphere at the time of spraying, which may cause environmental destruction and air pollution. Moreover, when electric power was used for the spray power, the sprayer could not be used in a place where there was no power supply facility. In addition, when compressed air is used as the spraying power, it is necessary to incorporate a pneumatic pump, which increases the size of the device.

In the sprayer of patent document 2, the compressed air produced with the air pump for bicycles was used as spray power, and the plastic bottle for drinks was connected to the sprayer, and was used as the supply source of water.
In this sprayer, since compressed air is used as spray power, there is no fear of environmental destruction or air pollution. In addition, since a bicycle air pump or the like is used, no power supply facility is required, and it can be easily used in ordinary homes. Moreover, since the pneumatic pump was not built in, the apparatus could be reduced in size.

  However, the sprayer of Patent Document 2 requires a bicycle air pump or the like in order to compress air. For this reason, the sprayer cannot be used when thinking outside the home, and if it is desired to use it outside, it is necessary to carry an air pump together.

  Moreover, in the sprayer of patent document 2, in order to obtain sufficient spraying power, 3/4 of the volume of the PET bottle was used as an air compression space, so the liquid to be sprayed was injected only about 1/4 of the PET bottle. I could not. Therefore, a large amount of liquid could not be accommodated in the PET bottle, the spray amount was small, and the spray time was short.

Furthermore, in the sprayer of patent document 2, it was possible to stop water by pressing the spray amount adjusting unit against a tube that allows liquid to pass from the plastic bottle to the spray hole.
However, in order to completely stop the water, high dimensional accuracy is required at the cut end of the tube, so there is a possibility that the water cannot be stopped due to an initial failure. Further, even when the tube deteriorates, there is a possibility that the water cannot be stopped. However, since the tube is inserted deeply into the base body, it is difficult to replace the tube.

JP 2011-156468 A Japanese Patent Laid-Open No. 10-165856

In order to prevent the water-stopping structure from deteriorating even if the tube deteriorates, it is conceivable to use a standard O-ring for the seal structure.
FIG. 10A shows a water flow state of the mist sprinkler 101, and has a structure in which an O-ring 106 sandwiched between the mist cap 102 and the nozzle body 103 is sandwiched and sealed in the vertical direction. The mist cap 102 and the nozzle main body 103 are detachably screwed by a male screw portion 133 formed on the outer peripheral surface of the nozzle main body 103 and a female screw portion 124 formed on the inner peripheral surface of the mist cap 102.
FIG. 10B shows a main part when the mist cap 102 and the nozzle main body 103 are separated from each other by rotating the mist cap 102 and the mist spraying state starts. At this time, as shown in FIG. 10B, a gap is generated between the mist cap 102 and the O-ring 106, and water flows out to the swirl flow path 131a and is sprayed.
When the internal pressure of the container (not shown) is high, the pressure in the staying space 128 on the front side of the swirling flow path 131a is increased. In this case, the front staying space 128 on the swirling flow path 131a and the outlet side of the swirling flow path 131a A pressure difference is generated in the acceleration space 122b, and the O-ring 106 is drawn to the mist cap 102 side by the negative pressure as shown in FIG. There is a problem that the water stops naturally.
In addition, when the mist cap 102 is turned to stop the water from the mist sprinkled state, as the mist cap 102 and the O-ring 106 approach each other, the flow path becomes narrower and the flow velocity increases, and the O-ring 106 is pulled. As a result, the water may stop before the assumed position, or the O-ring 106 may be sandwiched between the mist cap 102 and the nozzle main body 103 and be damaged.

  The present invention has been made in order to solve the above problems, and a mist spraying device that can switch between water stop and water discharge by operation of the tip and that can be easily sprayed on the go. The issue is to provide.

In the present invention, means for solving the above problems are as follows.
According to a first aspect of the present invention, there is provided a main body connected to a fluid supply source, a mist discharge member which is detachable from the main body and has a spray port for discharging the fluid, and discharges the fluid from the main body. A main flow path that passes through the member, a seal member that is disposed in the main flow path and can be sealed between the main body portion and the mist discharge member, and a fluid branched from the main flow path And a bypass channel capable of reducing the pressure of the fluid that deforms or displaces the seal member when the main channel is opened and closed.

  The second invention is characterized in that the upstream side of the main channel of the main body is formed so as to be screwable with a commercially available plastic bottle containing carbonated water.

  According to a third aspect of the present invention, there is provided a mist spraying apparatus comprising: a PET bottle container that contains a fluid; and a mist sprinkling device that is formed to be screwable to the PET bottle container and that discharges the fluid in a mist form. A commercially available carbonated water plastic bottle is used for the container.

  According to the first invention, by providing the bypass flow path, when the water pressure or the pressure in the container is high, the fluid passes through the bypass flow path even if the sealing member is attracted to close the main flow path. Thus, the pressure difference between the upstream and downstream of the seal member can be eliminated. Thereby, since the natural water stop which will be drawn in and seal the main flow path can be prevented, spraying can be performed reliably.

  According to the second invention, by using a commercially available carbonated water-containing plastic bottle, mist spraying can be easily performed without any other water supply equipment or spraying power regardless of the place of going out, indoors, in the car, garden, etc. It can be performed.

  According to the third invention, by using a commercially available carbonated water-containing plastic bottle, mist watering can be easily performed without any other water supply equipment or spraying power, regardless of where it is, such as on the go, indoors, in a car, or in a garden. It can be performed.

It is explanatory drawing which shows the mist watering apparatus and tube which concern on embodiment of this invention, (a) is a front view, (b) is a top view. It is a figure which shows the state which attached the container to the mist watering apparatus, (a) is a front view, (b) is a perspective view, (c) is a front view which showed only the container. (A) is the sectional view on the AA line of the principal part of FIG. 1, (b) is the elements on larger scale of (a). It is a figure which shows the mist cap of the mist watering apparatus, (a) is a perspective view, (b) is a top view, (c) is a front view, (d) is a bottom view, (e) is a CC cross section. FIG. It is a figure which shows the nozzle main body of the mist watering apparatus, (a) is a perspective view, (b) is a top view, (c) is a front view, (d) is a side view, (e) is a bottom view, (f) ) Is a sectional view taken along the line DD, (g) is an enlarged view of the E portion, (h) is an enlarged front view of the head portion of the nozzle body, and (i) is an enlarged sectional view of the same. It is the principal part enlarged view at the time of making the depth of the bypass groove which is another form of the mist watering device into a taper shape, (a) is a water stop state, (b) is a mist cap loosened a little from the water stop state. Indicates the state. It is the principal part enlarged view at the time of making the depth of the bypass groove which is another form of the mist sprinkling device into the taper shape, (a) is a state where the mist cap is further loosened, (b) is the most loosened mist cap Indicates the state. It is an enlarged front view of the head part of a nozzle body in other embodiments of the mist watering apparatus. It is a figure which shows the sealing member of the mist watering apparatus, (a) is a top view of an O-ring, (b) is the same sectional view, (c) is a top view of the O-ring of another embodiment, (d) is FIG. It is a figure which shows the principal part of the conventional mist watering apparatus, (a) is sectional drawing which shows a water discharging state, (b) is an expanded sectional view which shows the state which started water discharging, (c) was O-ring drawn It is an expanded sectional view showing a state.

Hereinafter, the mist watering apparatus which concerns on embodiment of this invention is demonstrated.
The mist watering apparatus 1 is comprised by the mist cap 2, the nozzle main body 3, the tube 4, and the container 5, as shown in FIG. 1, FIG.
The container 5 contains a fluid to be sprayed (for example, carbonated water).
As the fluid, water or carbonated water may be used by adding sodium bicarbonate and citric acid to water to make carbonated water. In addition, a fragrance such as aroma may be added to water or carbonated water, or a carbonated product of tablet type in which a fragrance is added to sodium bicarbonate and citric acid may be added to water to produce carbonated water.

The container 5 and the nozzle body 3 are detachably screwed together by a male screw part 51 formed on the outer peripheral surface of the container 5 and a female screw part 34 formed on the inner peripheral surface of the nozzle main body 3.
The nozzle body 3 and the mist cap 2 are detachably screwed by a male screw portion 33 formed on the outer peripheral surface of the nozzle main body 3 and a female screw portion 24 formed on the inner peripheral surface of the mist cap 2.

In the present specification, “upper and lower” in the description of the mist spraying device 1 means up and down with respect to the ground in a state where the container in FIG. The spray port 21 side of the cap 2 is meant, and the bottom means the ground side, that is, the bottom surface side of the container 5.
Further, in this specification, the radial direction is a radial direction of a horizontal plane with the above-described vertical direction as a reference, and the circumferential direction is a circumferential direction with the above-described vertical direction as a reference axis.
In the present specification, the entire article that can realize mist watering, and members constituting a part of the article may also be referred to as a mist watering apparatus.

  As shown in FIG. 4, the mist cap 2 is a substantially dome-shaped member that is attached to the tip (upper end) of the nozzle body 3, and is screwed to the nozzle body 3 on the inner peripheral surface near the lower opening. Female thread portion 24 is formed. Moreover, the outer peripheral surface of the mist cap 2 is formed in an octagonal cross section, and plays the role of anti-slip when holding with a finger and performing the attaching / detaching operation with the nozzle body 3. In addition, as long as it plays the role of anti-slip, the cross-sectional shape may be a polygon other than an octagon, and a cylindrical or conical shape provided with anti-slip ribs or recesses, or a finger rest may be provided. Further, a simple cylindrical shape or a conical shape may be used if anti-slip is not taken into consideration.

As shown in FIG. 4, a fine spray port 21 is formed in the tip surface on the upper side of the mist cap 2, and a funnel-shaped diffusion inclined surface 25 is formed around the spray port 21 on the tip surface. Passed water is easily sprayed by diffusion.
Further, inside the mist cap 2, a cylindrical accommodation tube portion 22 that accommodates a water flow control portion 31 of the nozzle body 3 to be described later is formed from the inner surface of the distal end toward the lower base end side. The accommodation cylinder portion 22 forms an accommodation space extending in the up-down direction. A guide inclined surface 22 a that is inclined inward so as to easily introduce the water flow control unit 31 is formed on the radially inner side of the base end surface 23, which is the lower surface of the accommodating cylinder portion 22.
As shown in FIG. 3, in a state in which a water flow control unit 31 of the nozzle main body 3 to be described later is housed, the side peripheral surface of the water flow control unit 31 is inscribed in the inner peripheral surface of the housing cylinder part 22 with almost no gap, A speed increasing space 22b is formed between the cylindrical portion 22 and the spray port 21 for collecting and increasing the speed of the swirling flow that has passed through the swirling flow path 31a.

In addition, the base end surface 23 forms a first O-ring storage space for storing the O-ring 6 together with a flat portion 32 of the nozzle body 3 described later.
The mist cap 2 further has a lower cylindrical portion connected to the radially outer side of the accommodating cylindrical portion 22 and extending downward, and the lower cylindrical portion has a second inner surface forming a second accommodating space in the radial direction. ing. The second storage space is a space for storing the nozzle body 3, and the second inner surface includes a female screw portion 24. Further, the lower cylindrical portion includes an upper inner surface that forms a stay space 28 described later together with the outer surface of the nozzle body 3 above the female screw portion 24. The lower cylinder part is formed to be connected to the radially outer side from the midway position in the vertical direction of the accommodation cylinder part 22, thereby forming a space between the accommodation cylinder part 22 and the lower cylinder part, and this space is retained. Part of the space 28 is formed.
In the lower cylinder portion, an O-ring storage lower inner surface that forms a space for storing the O-ring 7 together with an O-ring mounting portion 36 of the nozzle body 3 described later is provided below the female screw portion 24.

The material of the mist cap 2 can be a metal, resin, rubber or the like. Among them, a metal or a resin is preferable because hardness is necessary to perform reliable mist spraying from the minute spray port 21. Among them, a resin is preferable in terms of material cost and productivity, and among the resins, a thermoplastic resin is preferable because of easy molding. Among the thermoplastic resins, PP (polypropylene), ABS (acrylonitrile / butadiene / styrene synthetic resin) and PE (polyethylene) that conform to the Food Sanitation Law are preferable. Among them, ABS is preferable in that it has a glossy appearance, and PP is preferable in that the cost can be reduced.
In the first embodiment, an ABS resin having an appearance gloss is used.

As shown in FIGS. 5 and 3, the nozzle body 3 includes, in order from the upper side on the outer peripheral surface, a substantially cylindrical water flow control portion 31, a flat portion 32 that extends radially outward below the water flow control portion, and a flat surface. A male screw portion 33 extending in the vertical direction below the portion 32, an O-ring attachment portion 36 formed below the male screw portion to which the O-ring 7 is attached, and a flat portion extending radially outward from the lower end of the O-ring attachment portion 36 37, an inclined surface 38 positioned below the flat surface portion 37, and a cap portion 39 that extends downward from the inclined surface 38 and attaches the container 5.
Further, in order from the lower side of the inner peripheral surface of the nozzle body 3, a female screw part 34 that is screwed into the container 5, and a tube that extends downward from above the female screw part 34 and is connected to the tube 4. A portion 35 is formed. Furthermore, an internal flow path 35a is formed inside the cylindrical portion 35, and the internal flow path 35a communicates with the communication flow path 35b. The communication flow path 35b is an opening through which carbonated water or the like flows out from the internal flow path 35a to the outer peripheral surface side of the nozzle body 3, and is formed radially outward and upward.
The communication flow path 35b is connected to the internal flow path 35a and extends radially outward. An opening is provided on the outer surface of the cylindrical portion 35 so that carbonated water or the like can flow out, and a plane located above the opening. By cutting out a part of the portion 32, the discharged carbonated water and the like can easily flow into the upper staying space 28.
The nozzle body 3 is screwed with the mist cap 2 at the male screw portion 33 and is screwed with the container 5 at the female screw portion 34.

As shown in FIGS. 5 and 3, the water flow control unit 31 of the nozzle body 3 includes, in order from the upper side, a swirling channel 31a on the tip end side (downstream side) and a lower side (upstream side) of the swirling channel 31a. And an O-ring groove 31b and a bypass groove 31c carved in the O-ring groove 31b.
A head portion that protrudes in the radial direction from the O-ring groove 31b is provided on the distal end side of the water flow control portion 31, and a swirl passage 31a that is a spiral groove recessed in the radial direction is provided on the outer peripheral surface of the head portion. Two are provided at equal intervals on the circumference. When the mist sprinkler 1 is assembled, the outer peripheral surface of the head part other than the swirl flow path 31a is inscribed in the accommodating cylinder part 22 of the mist cap 2 without any gap, and the swirl flow path 31a allows the stagnant space 28 and the bypass groove 31c. A flow path connecting the speed increasing space 22b is formed.

The O-ring groove 31 b is formed in the lower part of the water flow control unit 31. The O-ring groove 31b includes an upper side wall connected to the head part, a lower side wall connected to the flat part 32, and a bottom surface (one of the peripheral surfaces of the water flow control part 31) connected between the upper side wall and the lower side wall. Part), and is an annular groove that is recessed in the radial direction from the plane part 32 and the head part of the water flow control part 31, and the height in the vertical direction is larger than that of the O-ring 6. Therefore, the O-ring 6 can be attached to the O-ring groove 31b so as to be freely movable in the vertical direction.
In a state where the O-ring 6 is attached to the O-ring groove 31 b, the outer diameter of the O-ring 6 is larger than the head portion of the water flow control unit 31 and the inner peripheral surface of the housing cylinder portion 22 of the mist cap 2. Therefore, when the mist cap 2 is operated and the O-ring 6 is sandwiched between the base end face 23 and the flat portion 32, the flow from the stay space 28 to the downstream bypass groove 31c and the swirl passage 31a can be closed. it can.

  In addition, when the O-ring 6 is attached to the O-ring groove 31b in the first embodiment, the O-ring 6 is held in contact with the O-ring groove 31b and the flat portion 32. However, the shapes of the O-ring groove 31b and the O-ring 6 are the same. By changing, the O-ring 6 may be formed so as to be held in contact with only the O-ring groove 31b.

As shown in FIGS. 3 and 7B, in the mist watering device 1, in the basic flow path of carbonated water, carbonated water is taken from the tube 4 and passes through the internal flow path 35 a in the cylindrical portion 35. Then, it flows out of the communication flow path 35b, flows from the stay space 28 formed between the nozzle body 3 and the mist cap 2 and flows into the swirl flow path 31a through the outside of the O-ring 6, and increases the speed of the mist cap 2. It gathers at 22b and the rotational flow velocity is increased, and water is sprayed from the spray port.
Hereinafter, this basic flow path may be referred to as a main flow path.
In addition, a channel through which carbonated water passes through the bypass groove 31c with respect to the main channel may be referred to as a bypass channel (see FIGS. 6B and 7A).

As shown in FIGS. 5 (h) (i), the bypass groove 31c is a groove having a shape in which a part of the peripheral surface of the O-ring groove 31b is further recessed in the radial direction, and the lower end (upstream) of the O-ring groove 31b. The starting end is located at a position slightly above the end) and extends in a vertical direction up to a position straddling the entrance of the swirling channel 31a.
As another example, the start end of the bypass groove 31c may be the position of the lower end of the O-ring groove 31b.
As another example, the end of the bypass groove 31c may extend to the position of the upper end of the O-ring groove 31b without straddling the entrance of the swirl flow path 31a.

The shape of the bypass groove 31c when viewed from the outside in the radial direction of the water flow control unit 31 may be an oval shape, an oval shape, a circular shape, a square shape, a triangular shape, a semicircular shape, or the like. Of these, from the viewpoint of securing the flow rate, an oval shape, an oval shape, or a circular shape is preferable, and an oval shape is particularly preferable in order to prevent deformation of the O-ring 6.
In the first embodiment, as shown in FIG.

Further, the number of bypass grooves 31c can be provided at a plurality of locations of 1 or 2 or more. Among them, it is preferable to provide at one place or a plurality of places at regular intervals in order to obtain a shape that can ensure the strength of the mold used for manufacturing. Considering the smallness of the water flow control unit 31, it is particularly preferable to provide it at 2 to 4 locations. Further, if the number of bypass grooves 31c is excessively increased, sealing failure due to the eccentricity of the O-ring 6 (the amount of deformation increases because there is no support during stress relaxation, and the holding force on the O-ring grooves 31b decreases, so that it is easier to move in the axial direction). 4) or less, and particularly preferably 3 or less.
In the first embodiment, the bypass grooves 31c are formed at two places at equal angles.

The depth dimension of the bypass groove 31c is preferably 0.2 to 1.5 mm in order to allow water to escape through the bypass groove 31c and reduce the pressure difference between the upstream and downstream of the O-ring 6. In order to ensure the strength of the water flow control unit 31 and the mold used for manufacturing the water flow control unit 31, the thickness is particularly preferably 0.4 mm or more.
In the first embodiment, the depth of the bypass groove 31c is 0.5 mm.

  Further, the bypass groove 31c may be tapered. That is, as shown in FIGS. 6 and 7, the depth of the bypass groove 31 c may be formed so as to gradually become deeper from the staying space 28 side (upstream side) toward the swirl flow path 31 a side. As shown in FIG. 8, the width may be gradually increased. As a result, when the mist cap 2 is operated from the water stop state to shift to the water discharge state, the flow passage cross-sectional area gradually increases, so that a fine flow rate adjustment is possible.

  The cap portion 39 of the nozzle body 3 has a cylindrical shape in the first embodiment, but may be provided with a groove perpendicular to the vertical direction so as to serve as a slip stopper when held by a finger, or a protruding finger. A hanging portion may be provided.

The material of the nozzle body 3 can be a material such as metal, resin, or rubber. Among them, metal or resin is preferable because hardness is necessary to reliably form the swirl flow path 31a and allow water to flow. Among them, a resin is preferable in terms of material cost and productivity, and among the resins, a thermoplastic resin is preferable because of easy molding. Among thermoplastic resins, PP, ABS, and PE that comply with the food hygiene law are preferable. Among them, ABS is preferable in terms of having a glossy appearance, and PP is preferable in terms of excellent impact strength and cost reduction.
In the first embodiment, PP having excellent impact strength is used.

As shown in FIG. 3, when the mist watering device 1 is assembled, the O-ring 6 is disposed between the base end surface 23 of the housing cylinder portion 22 of the mist cap 2 and the flat portion 32 of the nozzle body 3. In addition, an O-ring 7 for preventing water leakage is disposed between the inner cylinder portion 27 of the mist cap 2 and the O-ring mounting portion 36 of the nozzle body 3.
As shown in FIG. 6A, when the mist cap 2 is screwed into the nozzle body 3 to the deepest position, the O-ring 6 is sandwiched between the base end surface 23 of the mist cap 2 and the flat portion 32 of the nozzle body 3 and is pivoted. The main flow path is sealed by being crushed in the direction (vertical direction). At this time, the entrance of the bypass groove 31 c is also sealed by the contact between the O-ring 6 and the flat portion 32.
At the same time, the O-ring 7 is sandwiched in the radial direction between the inner cylinder portion 27 of the mist cap and the O-ring mounting portion 36 of the nozzle body 3 to prevent water leakage.

In operation of the mist watering device 1, FIG. 6 (a) has shown the water stop state.
FIG. 6B shows a state in which the mist cap 2 is operated so as to be loosened from FIG. 6A to start spraying, the flow passage cross-sectional area is small, and the flow rate is small. In this state, the pressure difference between the front side of the swirl flow path 31a and the outlet remains large, so the O-ring 6 is attracted to the mist cap 2 by the negative pressure on the downstream side. However, the flow of carbonated water is not hindered, and the carbonated water flows downstream by passing through the bypass groove 31 c and is sprayed from the spray port 21.
FIG. 7A shows a state in which the mist cap 2 is further loosened from FIG. 6B, the flow passage cross-sectional area of the bypass groove 31c is increased, and the flow rate is also increased.
FIG. 7B shows a state in which the mist cap 2 is further operated from FIG. 7A and the flow path cross-sectional area is the largest and the flow rate is the largest. In this state, the pressure difference between the water pressure in the staying space 28 upstream of the swirl flow path 31a and the water pressure in the speed increasing space 22b downstream of the swirl flow path 31a is almost eliminated. Since there is almost no pressure difference, the force that pulls the O-ring 6 downstream is lost. Thereby, carbonated water passes through the main flow path and is sprayed from the spray port 21.
In the state where the mist cap 2 is operated from the state of FIG. 7 (b) and the flow rate is returned to the small state again as shown in FIG. 6 (b), the water pressure in the staying space 28 rises again, resulting in a pressure difference. The ability to attract O-rings will be restored. However, the carbonated water flows downstream by passing through the bypass groove 31 c and is sprayed from the spray port 21.

  As shown in FIGS. 2 and 3, a packing accommodating portion 40 is provided on the female screw portion 34 of the nozzle body 3, and the packing 8 is disposed. By screwing the nozzle body 3 to the container 5, the packing 8 is sandwiched in the vertical direction between the packing housing portion 40 of the nozzle body 3 and the container 5 to prevent water leakage.

In the first embodiment, the mist cap 2 and the nozzle body 3 are attached by screw connection. However, the mist cap 2 and the nozzle body 3 are not limited to screw connection as long as they can be attached and detached and can be moved up and down. Any attachment means such as fixing can be used. Among them, as in the first embodiment, it is preferable to use a screw connection that is excellent in ensuring sealing performance and ease of operation.
In the mist watering device 1 of the first embodiment, the mist cap 2 and the nozzle body 3 can be easily attached and detached. Therefore, the mist cap 2 is removed from the nozzle body 3, and the inner surface of the mist cap 2, the swirl flow path 31a, and the bypass groove 31c etc. can be easily cleaned.

  The seal member is an O-ring 6 in the embodiment, but is a member that can seal the main flow path and the bypass flow path at the time of water stoppage, and provide a bypass flow path in combination with the O-ring groove 31b and the bypass groove 31c. As long as it can be used, rubber packing and other sealing members can be used.

The tube 4 is preferably made of a flexible material such as a rubber hose, and particularly preferably a silicon tube or a vinyl chloride tube, which is a material compatible with the food hygiene law. Among these, a vinyl chloride tube having a particularly low material cost is preferable.
In the first embodiment, a vinyl chloride tube is used.

In the first embodiment, a PET bottle containing carbonated water is used as the container 5. In particular, a commercially available carbonated water-containing plastic bottle is suitable because mist watering can be easily performed at any place.
As another example, the mist sprinkler 1 (cylinder part 35) may be directly connected to a water supply hose through a joint or the like without using a container, or a sprayer using compressed air or other power is used instead of the container 5 You may use for.

About the up-down direction height dimension a at the time of water stop of the mist watering apparatus 1 except the tube 4 in Fig.3 (a), it is preferable to set it as 30-50 mm.
If a is less than 30 mm, the mist cap 2 is difficult to hold and it is difficult to stop water. In order to improve operability, it is particularly preferable that a is 35 mm or more.
On the other hand, if a exceeds 55 mm, the product may be easily damaged when it falls. In order to improve the strength, it is particularly preferable that a is 45 mm or more.
In the first embodiment, a is 36.7 mm.

The vertical dimension b of the mist cap 2 in FIG. 3A is preferably 10 to 45 mm.
If b is less than 10 mm, it becomes difficult for the mist cap 2 to be pinched with a finger, that is, it becomes difficult to perform a water stop operation. In order to improve operability, b is particularly preferably 12 mm or more.
If b is more than 45 mm, the mist sprinkler 1 becomes large and external force concentrates on the mist cap 2 and falls easily when it falls. b is preferably 40 mm or less, more preferably 30 mm or less, and particularly preferably 20 mm or less.
In the first embodiment, b is set to 15.9 mm.

The maximum dimension c in the width direction of the mist cap 2 in FIG. 3A is preferably 10 to 40 mm.
When c is less than 10 mm, it becomes difficult to pinch the mist cap 2 with a finger, that is, it becomes difficult to perform a water stop operation. c is more preferably 10 mm or more, further preferably 12 mm or more, and particularly preferably 16 mm or more.
Further, if c is more than 40 mm, the mist sprinkler 1 becomes large and the external force concentrates on the mist cap 2 when it is dropped, so that it is easy to break. c is more preferably 40 mm or less, further preferably 35 mm or less, and particularly preferably 30 mm or less.
In the first embodiment, c is 18 mm.

The outer diameter dimension (diameter) d of the cap part 39 of the nozzle body 3 in FIG. 3A is preferably 30 to 36 mm.
If d is less than 30 mm, the wall thickness F becomes 0.65 to 0.75 mm to connect to a commercially available carbonated water-containing plastic bottle, and the strength is too low. In order to ensure the strength, it is particularly preferable that d is 30.6 mm or more.
On the other hand, if d is more than 36 mm, the thickness F becomes too thick to connect to a commercially available carbonated water-containing plastic bottle, and sink marks may adversely affect the design surface. d is more preferably 35 mm or less, and particularly preferably 34.8 mm or less.
In the first embodiment, d is 34.5 mm.

The height e of the cap portion 39 of the nozzle body 3 in FIG. 3A is preferably 15 to 18 mm.
If e is less than 15 mm, it will be too small to hold by hand. It is particularly preferable that e is 15.5 mm or more.
If e is more than 18 mm, the thickness becomes too thick, and sink marks may adversely affect the design surface. It is particularly preferable that e is 16.5 mm or less.
In the first embodiment, e is 16 mm.

Mist watering using the mist watering device 1 of the first embodiment is as follows.
In the following description, the state where the mist cap 2 and the nozzle body 3 are screwed in the deepest (water stop state) will be described as the initial position (FIG. 6A).

In the first embodiment, carbonated water is used as a fluid (not shown), and a commercially available carbonated water-containing plastic bottle is used as the container 5. First, the lid of the plastic bottle is removed and attached to the cylinder portion 35 of the mist sprinkler 1.
If the plastic bottle is shaken vigorously in that state, the carbonated water will be stimulated, and the dissolved carbon dioxide gas will fill the gap in the container 5 (pet bottle) and the pressure will rise. Carbonated water is about to spout. The carbonated water passes through the tube 4, passes through the internal flow path 35 a of the nozzle body 3, and flows out from the communication flow path 35 b to the stay space 28 in the mist cap 2.
At this time, since the O-ring 6 is sandwiched between the base end face 23 of the mist cap 2 and the flat portion 32 of the nozzle body 3 and seals the main flow path and the bypass flow path, carbonated water is prevented from flowing downstream. ing.

  Next, when the mist cap 2 is loosened, the mist cap 2 is slightly separated from the nozzle body 3, and carbonated water begins to flow into the swirling flow path 31a from the outside (main flow path) of the O-ring 6 (FIG. 6B). FIG. 7 (a)). At this time, the O-ring 6 is attracted to the downstream due to the pressure difference between the upstream side of the high-pressure O-ring 6 and the downstream side of the low-pressure, but since a gap is generated between the flat portion 32 and the O-ring 6, It flows into the accommodating cylinder portion 22 of the mist cap 2 through the bypass groove 31c formed in the O-ring groove 31b. The water that has passed through the spiral flow path formed by the swirl flow path 31 a gathers in the speed increasing space 22 b and increases the rotational flow velocity, and is diffused and sprayed from the spray port 21.

  When the mist cap is further loosened and the mist cap 2 is largely separated from the nozzle body 3, carbonated water flows downstream from the outside (main flow path) of the O-ring 6 and is sprayed (FIG. 7 (b)). Also at this time, carbonated water can pass through the bypass channel, and the main channel has a sufficient flow rate, and the pressure difference between the upstream side and the downstream side of the O-ring 6 is greatly reduced. The ring 6 is not attracted downstream. Therefore, a large amount of water can be diffused and sprayed by flowing the water from the main channel into the swirl channel 31a.

  In the first embodiment, by providing the bypass groove 31c, the O-ring 6 is attracted to the staying space 28 on the near side of the swirl passage 31a and the speed increasing space 22b on the outlet side of the swirl passage 31a. The large pressure difference is not generated, and the O-ring 6 is not pulled into the mist cap 2 side due to the pressure difference. Therefore, the flow path is not blocked and the water is not stopped naturally.

  Moreover, by using a commercially available PET bottle containing carbonated water as a container of the mist watering device 1, mist watering can be easily performed at any place.

<Other embodiments>
The bypass channel of the first embodiment is formed by a bypass groove 31c carved in the O-ring groove 31b, and uses a normal O-ring as shown in FIGS. 9 (a) and 9 (b). c) As in (d), a notch serving as a bypass channel may be provided inside the seal member (packing).
Further, the bypass flow path may be formed by providing a gap between the O-ring 6 and the O-ring groove 31b by making the inner diameter of the O-ring 6 larger than the outer diameter of the O-ring groove 31b.
However, in these modified examples, when the mist cap 2 is tightened to the water stop side, a seal failure occurs due to the wrinkles of the O ring 6 or the O ring 6 easily moves due to a water flow when water flows. Therefore, it is most preferable to provide the bypass groove 31c in the nozzle body 3 as in the first embodiment.

In the first embodiment, a PET bottle is used as the container 5, but a general container other than a PET bottle such as a metal bottle such as aluminum or a container dedicated to the mist sprinkler 1 may be used.
Moreover, you may connect not to the container 5 but to water supply equipment or another water supply apparatus as a fluid supply source.

In the first embodiment, a commercially available carbonated water-containing plastic bottle is used as the spraying power, but other examples include those using tap water pressure, those using compressed air, and those operated by external power. Can be used.
For example, when using a carbonated water plastic bottle, the internal pressure may increase up to 0.6 MPa.
In addition, tap water pressure at a faucet in a general home may be 0.74 MPa at the maximum.
Moreover, the compressed air using an air pump may increase the internal pressure to 1.0 MPa.
In the mist sprinkler of the present invention, even when switching from the water stop state to the water discharge state under such a high water pressure, the seal member (O-ring 6) is drawn into the downstream mist cap 2 side to block the main flow path. Even so, the pressure upstream of the seal member is reduced when water passes through the bypass channel. Thereby, the natural water stop by the drawing-in of a sealing member can be prevented, and spraying can be performed reliably.

  Furthermore, in the mist watering device 1 of the first embodiment, water passes through the spiral swirl passage 31a, and the rotational flow velocity is increased in the speed increasing space 22b and is diffused and sprayed from the spray port 21, but as another example A mechanism for generating a swirling flow on a plane, a mechanism for causing a linear flow having a high flow velocity to collide with a wall surface, or other mist generating mechanism may be used.

  Moreover, in the mist watering apparatus 1 of 1st embodiment, although the spraying opening 21 was opened upwards with respect to the PET bottle container, you may open toward other directions, such as a side, and a plurality of spraying A mouth may be provided to enable spraying in multiple directions.

  The present application also describes other inventions not included in the invention according to the independent claims. Each form, member, configuration and the like described in the claims and embodiments of the present application are recognized as inventions based on the functions and effects of each.

  Each form, member, configuration, etc. shown in the above embodiment may be individually described in the present application including the invention according to the claims of the present application, even if it does not include all of the form, member, or configuration of these embodiments. It can be applied to all inventions.

  The structure demonstrated above is used for all mist watering apparatuses.

DESCRIPTION OF SYMBOLS 1 Mist sprinkler 2 Mist cap 3 Nozzle main body 4 Tube 5 Container 6 O-ring 7 O-ring 8 Packing 21 Spraying port 22 Accommodating cylindrical part 22a Guide inclined surface 22b Speed increasing space 23 Base end surface 24 Female screw part 25 Diffusion inclined surface 26 Below Side end surface 27 Inner cylinder part 28 Retention space 31 Water flow control part 31a Swirling flow path 31b O-ring groove 31c Bypass groove 32 Plane part 33 Male thread part 34 Female thread part 35 Tube part 35a Internal flow path 35b Communication channel 36 O-ring attachment Part 37 flat part 38 inclined surface 39 cap part 40 packing accommodating part 51 male screw part 61 notch shape

Claims (3)

A body connected to a fluid source;
A mist discharge member that is detachable from the main body and has a spray port for discharging fluid;
A main flow path for allowing fluid to pass from the main body to the mist discharge member;
A seal member that is disposed in the main channel and can be sealed between the main unit and the mist discharge member;
A mist sprinkler characterized by comprising a bypass channel that branches off from the main channel and allows fluid to pass therethrough and that can reduce the pressure of the fluid that deforms or displaces the seal member when the main channel is opened and closed. .   2. The mist sprinkler according to claim 1, wherein the upstream side of the main channel of the main body is formed so as to be screwable with a commercially available plastic bottle containing carbonated water. A plastic bottle container containing the fluid;
In the mist watering device provided with a mist generating mechanism that is formed to be screwable to the PET bottle container and discharges the fluid in the form of a mist.
A mist sprinkler characterized in that a commercially available carbonated water plastic bottle is used for the plastic bottle container.

Images