JPH11239442A - Water sprinkling plug for dilution of chemical - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily carry out preparatory operations for the spraying of a chemical, simply obtain a required amount of a water-diluted chemical, provide a water sprinkling plug in a simple structure at a low cost and remarkably simplify a change in dilution ratio. SOLUTION: This water sprinkling plug for the dilution of a chemical is equipped with a flow passage constricting part 12 capable of making tap water as a jet water stream flow down, an opened flow passage 11 communicating and connecting to a stock solution bottle 10 for the chemical and plural water flow passages 16 respectively having an opening and closing valve 17 in a plug body 1. The stock solution is sucked up from the stock solution bottle 10 with the jet water stream and mixed with the jet water stream to provide a water- diluted chemical. The tap water flowed down from one or plural water flow passages 16 is simultaneously mixed with the water-diluted chemical to change the magnitude of the dilution ratio.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a watering faucet for diluting horticultural chemicals, one end of which is connected to a water tap or the like and used by being connected to a water supply hose.

[0002]

2. Description of the Related Art Spraying a chemical is indispensable for preventing or eliminating pests during plant cultivation. In general, commercially available chemicals are diluted, if necessary, in the order of 500 times, 1000 times, or 2000 times, and the diluted chemicals are atomized and sprayed on cultivated plants. In addition, liquid fertilizers, nutrients, and the like are diluted and sprayed with these chemicals in the same order. In the present invention, the above-mentioned chemicals, liquid fertilizers, nutrients and the like are hereinafter collectively referred to as chemicals.

When diluting these chemicals and spraying,
Usually, the cap of the bottle containing the chemical solution is used as a measuring box. Then, the chemical solution poured into the cap is mixed and diluted with a predetermined amount of water. Next, the dilution water of the chemical solution is transferred to the tank of the sprayer. At this time, an operation of washing the cap with dilution water is also required. As another means, there is a working mode in which a predetermined amount of water is poured into a tank of a sprayer, and a chemical solution poured into a cap is mixed and diluted therewith. However, this work mode is not advantageous because it is necessary to clean the chemical solution remaining in the cap. Therefore, the former work mode is generally adopted.

[0004]

However, such a spraying method of dilution with a chemical solution has a problem in that it involves the following inconveniences. In order to prevent mixing of different types of chemicals, it is necessary to clean the tank of the nebulizer each time. Since the nebulizer itself is heavy and the tank is supplied with the dilution water of the chemical solution, it is very hard work to hold the nebulizer and hang it on the shoulder. In addition to the expensive nebulizer, a special dilution container is required for diluting the drug solution. Preparation of work such as measurement and dilution of a chemical solution, and cleaning of a tank before dilution takes time and effort. It is very difficult to obtain as much dilution water of the drug solution as necessary for spraying, because the drug solution is mixed with a fixed amount of dilution water. Since the diluent will be overkill,
Chemical liquid waste increases.

[0005] The present invention has been developed in view of the drawbacks of this conventional dilution means. Therefore, an object of the present invention is to provide a simple and easy preparation for spraying a chemical solution. Moreover,
The required amount of chemical dilution water can be easily obtained and can be provided at a low cost with a simple structure. At the same time, it is to satisfy that the change of the dilution ratio can be performed much simpler.

[0006]

Means for Solving the Problems A normally open flow-rate increasing flow passage through which tap water can flow as a jet water flow to a stopper body connected to a water tap or the like via a hose, and a bottle containing a chemical solution. A connected open flow path and a plurality of water flow paths each having an on-off valve are provided.

According to this means, a basic dilution water can be easily obtained by sucking up the chemical from the bottle with the jet water flow and mixing the chemical solution with the jet water flow. Then, by mixing the basic dilution water with tap water flowing down from one or more of the plurality of water passages, the dilution ratio of the drug solution can be easily changed to be large or small.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A plug body is provided with a water supply hose at one end and a sprinkler with a sprinkler nozzle at the other end thereof. In the plug body, a plurality of water passages are independently provided. One of the plurality of water passages is formed as an open passage through which tap water always flows. A flow velocity increasing flow path is formed in the open flow path. The flow velocity increasing flow path is provided with means for mounting a bottle containing a chemical solution. A chemical solution discharge port of the chemical solution suction channel is opened in the flow velocity increasing channel. The chemical in the bottle is sucked through the chemical suction passage and guided to the chemical discharge port. Then, the chemical liquid is sucked from the chemical liquid suction flow path by the jet water flow flowing down in the flow velocity increasing flow path, and mixed with the jet water flow. Further, the remaining water passages other than the open passage are provided with on-off valves, respectively.
All the flow paths including the open flow path are joined at the tip thereof, and are formed so as to flow down to the watering nozzle. And it is comprised so that the dilution rate of a chemical | medical solution may be changed by the combination of one or more of the said water flow path, and the said flow velocity increase flow path.

[0009]

A hose connected to a water tap or the like is connected to one end of the water tap, and a water sprinkler is connected to the other end. Then, open the faucet and pour tap water through this hose,
It is used so that water is sprinkled from a sprinkler.

According to the above-mentioned means, since the sprinkler is provided with the flow velocity increasing flow path, the flow velocity increasing flow path increases the flow velocity of the tap water and lowers the pressure. As a result, the drug solution in the bottle is pushed by the atmospheric pressure and is sucked into the drug solution suction channel. The sucked chemical solution is discharged from the chemical solution discharge port of this flow path, and is stirred by the tap water and diluted. Finally, the dilution water of this chemical solution is spouted vigorously from the watering nozzle.

At this time, using only the open flow path,
When all the other water passages are closed, a diluent having the highest concentration can be obtained.

As described above, the water tap according to the present invention is provided with a plurality of openable and closable water flow paths in addition to the open flow path. Therefore, if one or more of the water flow passages are appropriately opened and the tap water is allowed to flow down, the diluent and the tap water in the open flow passage, which is always in a water flow state, are connected to the sprinkler tap. In the mixing section, the desired mixing ratio is well mixed. As a result, the dilution ratio increases as desired.

Therefore, as shown in FIG. 2, it is possible to adopt a configuration in which all the water passages are set to have the same diameter as the open passage. That is, assuming that the dilution rate of the open flow path is 500 times, opening one water flow path increases the dilution rate to 1000 times. In addition, if the number of water passages is two, the ratio is 1500 times.
The dilution rate is sequentially increased by a factor of 00 (claim 4).

Further, as shown in FIG. 3, a configuration is adopted in which the flow rate of each of the flow passages is set to a flow path diameter that is twice as large as the flow rate of the minimum flow path diameter, for example, from one to several times. Can be adopted. That is, if the dilution rate of the open flow path is set to 500 times as described above, the dilution rate is increased to 1000 times by opening the smallest water flow path. Also, if the diameter is a medium flow path diameter, it is 1500 times, and if the flow path diameter is the maximum, it is 200 times.
The dilution factor is increased sequentially to 0 times (claim 5).

As shown in FIG. 4, for the purpose of efficiently sucking the chemical solution in the chemical solution bottle, even if the flow path diameter of each of the water flow paths is set to be the same as the flow path narrowing portion of the open flow path. good. This is because by making the flow path resistances of all the flow paths the same, an ideal chemical solution suction and dilution action can be expected (claim 6).

As described above, the water spigot for diluting a chemical according to the present invention can sprinkle the chemical diluting water onto a cultivated plant by running water such as tap water simply by attaching a chemical bottle to the water spigot. . Therefore, an expensive nebulizer or a container dedicated to diluting a chemical solution is not required. Further, a desired dilution ratio can be easily and easily obtained by a simple structure for simply opening and closing the water flow passage and a simple operation. As a result, it became possible to easily spray the necessary amount of the chemical dilution water with ease and without any trouble.

If the chemical bottle is removed and water is sprinkled, the tap water flowing down the open flow path causes the chemical remaining in the chemical suction flow path to flow down together. Therefore, there is no possibility that the chemicals in different chemical bottles are mixed when the different chemicals are sprayed.

Further, by removing the chemical bottle and closing the chemical suction passage, only tap water can be sprinkled. For this reason, it is possible to arbitrarily switch between spraying the diluted liquid of the chemical solution and spraying only the tap water.

The means for increasing the flow velocity in the open flow path includes:
As shown in FIG. 1, means (claim 2) having a narrow flow path (flow path narrowing portion) in which the flow path diameter is partially narrowed is employed, or as shown in FIG. Means in which a narrowed flow path (flow path narrowed portion) as described above and a tapered frusto-conical member which is substantially concentric with the flow path axis and which is tapered are provided in the flow path (claim 3). Is adopted. In addition, the chemical solution discharge opening is formed on the bottom of the narrowest portion of the flow path, in the tap water flow, or on the truncated surface of the tapered frustoconical member so that the chemical solution is efficiently sucked out of the bottle. (Claim 2 and claim 3).

The reason why the flow path constricted portion is configured so that the flow path diameter is partially constricted is that the structure is simple and the production is simple. Further, the frusto-conical member is employed because the tap water is more likely to be jetted, and the chemical solution can be efficiently and accurately sucked out.

The open flow path is formed of a large-diameter flow path dedicated to flowing down tap water and a small-diameter flow path dedicated to sucking a chemical solution, because the suction of the chemical solution can be performed more efficiently.

The plug body is formed of a straight pipe, and the connection between the water supply hose and the sprinkler is screwed to screws formed at the front and rear ends of the straight pipe. The reason for this is that the plug body can be manufactured much more simply and inexpensively, and in particular, if a synthetic resin is used as a material, the manufacture is much simpler and cheaper.

Further, the stenotic flow path portion including the bottle mounting means is formed separately from the plug main body. It is possible to adopt a configuration in which it is fixed so as to be connected to a dedicated small-diameter flow path for suction. By constructing a part with a complicated structure as a separate body among the parts constituting the plug body,
This is because the manufacture is much easier and cheaper than when the whole is configured as one integrated unit from the beginning.

[0024]

Embodiments of the present invention will be described below with reference to the drawings. (First Embodiment) FIG. 1 shows a first embodiment of a water faucet for diluting a chemical according to the present invention. In the figure, reference numeral 1 denotes a plug body provided with a water supply channel A, and a male thread portion a is formed on the rear end side. Also,
The rear end side of the male screw portion a is formed with a slightly smaller diameter. An annular ridge b for connecting a water supply hose is formed in the small diameter portion.

Then, the water supply hose 2 is inserted into the raised portion b of the small diameter portion.
Are externally fitted. The separation prevention of the water supply hose 2 is provided by the following structure. That is, the female thread sleeve 3 having the reduced diameter portion c formed by reducing the diameter of the rear end portion is fitted to the water supply hose 2 in advance. The female screw sleeve 3 is screwed to the male screw portion a, and the water supply hose 2 is sandwiched between the reduced diameter portion c of the female screw sleeve 3 and the raised portion b. Also, this water supply hose 2
Is connected to a water tap (not shown).

Reference numeral 4 denotes, for example, a cock type on-off valve. A valve box 5 is formed slightly downstream of the male screw portion a of the plug body 1, and a rotary valve element 6 having a flow path d in the valve box 5.
Is built-in. Then, the rotary valve element 6 is passed through the valve cover 7.
An operation lever 8 is provided to open and close the water supply passage A and adjust the amount of water.

Reference numeral 9 denotes a female screw cylindrical portion serving as a mounting means for the bottle 10 containing the chemical solution. The female screw tube portion 9 is provided on the downstream side of the on-off valve 4 with respect to the stopper
For screwing the male screw opening 10a. The mounting means 9 is provided with a so-called breathing slit flow path e which connects the internal space of the chemical liquid bottle 10 to the outside.

Reference numeral 11 denotes an open flow path formed in connection with the water supply flow path A. An axis parallel to the axis of the plug body 1 is provided on the downstream side of the rotary valve body 6 of the plug body 1. The open flow path 11 has a flow path narrowing portion 12 formed on the inner wall thereof, as shown in FIG. 1, for narrowing the width of the flow of tap water. Therefore, when the tap water flows down the flow path constriction portion 12, the flow velocity becomes large (jet water flow).

The flow path narrowing portion 12 is obtained by forming a constriction on the inner surface of the pipe in the middle of the open flow path 11. This constriction first causes the pipe inner surface in the middle of the open flow path 11 to sequentially swell in the flowing direction of the tap water. Then, after that, it is formed so as to return to the flow path diameter G of the open flow path 11 again.

The flow path narrowing portion 12 is provided in the chemical liquid bottle 1.
0 is formed above the mounting means 9. Also,
A chemical solution discharge port 13 is opened in front of the maximum bulging portion 12a, that is, on the side closer to the lower side of the tap water flow. Then, the chemical solution discharge port 13 and the inside of the chemical solution bottle 10 are communicatively connected.

As a specific structure, first, a chemical solution suction passage 14 is formed through the pipe wall of the plug body 1. And
A flexible tube 15 is connected to the chemical solution suction channel 14. The flexible tube 15 has an opening located at the bottom in the chemical solution bottle 10 as shown. As described above, the chemical solution discharge port 13 and the chemical solution bottle 1 are formed by the chemical solution suction passage 14 and the flexible tube 15.
The inside of 0 is connected to each other.

Therefore, the tap water flows down at a high speed in the flow path narrowing portion 12, so that the pressure drops. as a result,
The chemical in the chemical bottle 10 is sucked into the chemical suction passage 14 through the tube 15. Then, a small amount of the chemical solution sucked into the chemical solution suction channel 14 is sucked through the chemical solution discharge port 13, and is finally stirred and diluted with tap water.

A plurality of water passages 16 (three in the illustrated example) are provided in the plug body 1 separately from the open channel 11 at predetermined intervals around the axis of the plug body 1. Is formed. A cock type on-off valve 17 is provided in the middle of each flow path. Each of these on-off valves 17
The valve box 18 is formed in the middle of each water passage 16, and a rotary valve body 19 having a passage f is built in the valve box 18. Further, an operation lever 21 is connected to the rotary valve body 19 through the valve cover 20 so that each water passage can be opened and closed independently.

Each of the water passages 11 has a diameter g,
The open channel 11 is formed to have the same size as the channel diameter G. That is, the flow rates of the open flow channel 11 and each of the plurality of water flow channels 16 are substantially the same.

Therefore, for example, in the case where the chemical is designed to be diluted 500 times in the open flow path 11, the following diluting action can be obtained according to the structure shown in FIG. That is, when one of the water passages 16 is opened to allow the tap water to flow down, the chemical is diluted 1000 times. Similarly, two water passages 1
When releasing 6, the drug solution is diluted 1500 times.
Then, when all the water passages 16 are opened, the chemical is diluted 2000 times.

A mixing channel 2 is provided at the tip of the plug body 1.
2 are formed, and the four flow paths, that is, the open flow path 11 and the respective water flow paths 16 are merged. Thus, the dilution water flowing down from the open flow path 11 can be mixed with the tap water flowing down the water flow path 16. By this mixing, the desired 500 to 2000
Allows for 2-fold dilution.

From the side of the plug body 1, a water tool 25 attached in this order to the water pipe 23 and the watering nozzle 24 is detachably connected to the tip of the plug body 1. Then, the diluent flowing down from the stopper main body 1 is jetted at a high speed. Plug body 1
The sprinkling tool 25 is attached to the end of the water pipe 23 by a screw connection via a coupling 23A.

Next, the operation of the first embodiment will be described. A water supply hose 2 is connected to the rear end of the stopper main body 1 and a chemical solution bottle 1 is connected.
This chemical solution bottle 10 is mounted on the bottle mounting means 9 such that the flexible tube 15 is inserted into the inside of the bottle. Furthermore,
In order to obtain a desired dilution ratio, the necessary number of the plurality of water passages 16 is selected, and necessary operations such as opening the on-off valve body 19 of the on-off valve 17 corresponding thereto are performed. Next, when the on-off valve 4 is opened, the tap water flows down the open flow path 11, the flow speed increases in the flow path narrowing portion 12, the pressure decreases, and the tap water flows down to the mixing flow path 22. .

When the tap water flows down the flow path narrowing portion 12 at a high speed, the pressure in the flow area of the flow path narrowing portion 12 becomes low. As a result, the drug solution in the bottle 10 is sucked into the drug solution suction channel 14 through the flexible tube 15. Then, a small amount of the chemical solution is discharged through the chemical solution discharge port 13, and the small amount of the chemical solution is stirred and diluted with tap water. The diluted water of the chemical is guided from the mixing channel 22 to the water guide tube 23, and finally is spouted vigorously from the water spray nozzle 24 at the tip.

When the water passage 16 is also open, tap water flows from the water supply passage A into the water passage 16 as well. As a result, the tap water is mixed with the dilution water flowing down from the open channel 11 in the mixing channel 22. By this mixing, the dilution ratio of the dilution water is further increased. In this manner, four levels of dilution ratios, 500 times, 1000 times, and 15 times, according to the number of open water passages 16.
00 and 2000 times are easily obtained.

The change in the dilution rate is determined by the stopper body 1
This is achieved by a very light and simple operation of simply opening and closing the on-off valve 17 provided on the peripheral wall to open and close the water passage 16. Therefore, it is possible to easily sprinkle the required amount of the chemical dilution water onto the cultivated plant without any trouble.

When the chemical bottle 10 is removed and water is sprayed, the chemical remaining in the chemical suction passage 14 is flushed out with tap water and removed. Therefore, when spraying different chemicals, a chemical bottle 10 containing different chemicals is used.
The possibility that these different chemicals are inadvertently mixed is eliminated even if they are replaced.

In the first embodiment, the open channel 1
1. Basically, the water passage 16 is employed in a simple structure having the same inner diameter. For this reason, the manufacture and processing of the plug body 1 is extremely easy and simple, and has an advantage in manufacturing that can be provided at low cost.

(Second Embodiment) FIG. 3 shows a second embodiment of a water faucet for diluting a chemical according to the present invention. In the first embodiment, each of the water passages 16 is designed so that the same amount of water as the open passage 11 can be obtained. To change the dilution ratio, the on-off valve 17 of each water passage 16 is operated to adjust the total water flow. In other words, a structure is adopted in which some on-off valves 17 are opened and closed to change them depending on the dilution ratio. For this reason, although it is a simple operation, a literal one-touch operation that is originally oriented cannot be expected. This second embodiment is:
This is an improvement of the first embodiment, which enables the dilution ratio to be changed with just one touch.

More specifically, each of the water passages 16 is set so that the required flow rate can be obtained by one of the water passages in accordance with the dilution ratio. That is, the open channel 11
Is set to the same size as in the first embodiment so that a dilution ratio of 500 times can be obtained. However, the other three water passages 16 are 500 times larger in the first, and 1 in the second.
000 times, and the third one 1500 times
The dimensions (G <g ₁ <g ₂
<G ₃ ).

Therefore, in order to obtain a dilution ratio of, for example, 1000 times, only the first opening / closing valve 19a is opened, and only the first first water passage 16 is opened. The other second water passage 16 and the third water passage 16 remain closed. As a result, the tap water flowing down from the first water passage 16 is mixed with the 500-fold dilution water flowing down from the open flow passage 11 in the mixing passage 22 so that the dilution rate becomes the expected 1000 Doubled.

Similarly, to increase the power by 1500 times, the second
The desired dilution rate can be achieved by one-touch operation by opening only the opening / closing valve 19b, or by opening only the third opening / closing valve 19c to increase the magnification by 2000 times.

As described above, in the second embodiment, the magnitude change of the dilution ratio is achieved by a so-called one-touch operation in which only the water passage that can exhibit the preset dilution ratio is opened. it can.

When the structure according to the second embodiment is adopted, the dilution ratio can be changed only by opening and closing a predetermined opening / closing valve of the water passage. Therefore, the desired dilution rate can be obtained without taking any consideration into the combination of the water flow passages, which is particularly advantageous for the elderly in handling operation.

In the figure, the flow path f of the on-off valve body 19 is shown for convenience of expression.
Each water passage 16 has the same diameter as the passage f formed in 9.

(Third Embodiment) FIG. 4 shows a third embodiment of a sprinkler for diluting a chemical according to the present invention. In the first embodiment, each of the water flow passages 16 is designed so as to obtain almost the same water flow as the open flow passage 11. However, in this embodiment, each of the water passages 16 and the open passage 1
1 are configured to have substantially the same flow rate. Specifically, the flow path diameters g to g of each water flow path 16
₃ is configured to have the same flow path diameter as the flow path diameter G ₁ of the flow path narrowing portion 12 of the open flow path 11. Thereby, the flow path resistance of the open flow path 11 and each flow path 16 is configured to be the same. By adopting such means, the suction of the chemical solution in the open flow path can be made more reliable, and the desired dilution water can be obtained.

In the figure, the flow path f of the on-off valve 19 is shown for the sake of convenience of expression, but each water flow path 16 has the same flow path diameter as the flow path f formed in the on-off valve 19. Is formed.

(Fourth Embodiment) FIG. 5 shows a fourth embodiment of a water tap for diluting a chemical according to the present invention. In FIG. 1 showing the first embodiment, the flow velocity increasing flow path formed in the open flow path 11 is obtained by narrowing the flow path wall to form a constriction. However, in the fourth embodiment, instead of this constriction, a truncated conical flow path restricting member is provided in the open flow path 11.

Specifically, a flow path narrowing portion 12 similar to FIG. 1 is formed in the open flow path 11. A tapered frusto-conical member 26 is provided concentrically with the open flow channel 11 on the side of the flow channel narrowing portion 12 where the tap water flows downward. The truncated conical member 26 is provided above the mounting means (female screw cylinder) 9 for the chemical liquid bottle 10.

As shown, the truncated conical member 26 has the chemical solution suction passage 14 formed therein. Then, the chemical solution discharge port 13 is opened at a truncated surface portion of the truncated conical member 26, that is, a portion facing the channel narrowing portion 12 side. The chemical solution discharge port 13 is connected to the inside of the chemical solution bottle 10 through the chemical solution suction passage 14 and a flexible tube 15 connected to an end of the chemical solution suction passage 14.

The rear end of the truncated conical member 26 is
That is, the upstream side under the tap water flow is formed in a spindle shape.
By this spindle shape, the turbulent flow of tap water is suppressed, and a smooth flow is obtained.

In the fourth embodiment, the tap water acts so as to flow down the flow passage narrowing portion 12 at a high speed. Along with this high-speed flow, the pressure at the tip of the truncated conical member 26 becomes low pressure, and the chemical in the chemical bottle 10 is sucked into the chemical suction passage 14 through the flexible tube 15. It is. Subsequently, a small amount is discharged through the chemical solution discharge port 13. Then, this trace amount of the chemical solution is stirred and diluted in tap water. Finally, the diluting liquid is jetted from the watering nozzle 24.

As described above, when the frusto-conical member 26 is employed, the jet water flow of tap water can be accurately produced by the cooperative action with the channel narrowing portion 12. Accordingly, the pressure at the tip of the truncated conical member 26 is accurately reduced. As a result, the liquid medicine in the liquid medicine bottle 10 is efficiently sucked out.

(Fifth Embodiment) FIGS. 6 and 7 show a fifth embodiment of a water faucet for diluting a chemical according to the present invention. In each of the first to fourth embodiments, a structure in which the open flow path 11 is provided with a flow path constriction portion 12 is employed for sucking a chemical solution. Instead of this, in the fifth embodiment, a separate suction channel is formed in the open channel 11. According to this means, it is advantageous in that efficient suction and dilution of the drug solution can be successfully achieved as intended.

The specific configuration is as follows.
Are formed from two large and small flow paths 11a and 11b, as shown in FIGS. These two channels 1
The upper portions 1a and 11b are formed in the large-diameter flow channel 11a, and the lower portions are formed in the small-diameter flow channel 11b. In the lower small-diameter flow passage 11b, a flow passage narrowing portion 12 for narrowing the width of the flow of tap water is formed as in FIGS. Therefore, when the tap water flows down the flow path constriction portion 12, the flow velocity becomes large (jet water flow). The flow path constriction portion 12 is configured by providing a constriction on the pipe inner surface in the middle of the small-diameter flow path 11b. This constriction is obtained by sequentially expanding the inner surface of the pipe in the middle of the small-diameter flow passage 11b in the flow-down direction of the tap water, and then returning to the predetermined flow passage diameter again.

The flow path narrowing portion 12 is formed above the mounting means 9 for the chemical liquid bottle 10 as in FIGS. 1 to 4. And the largest bulging part 1
A chemical solution discharge port 13 is opened before 2a, that is, on the side closer to the lower side of the tap water flow. Also, this chemical solution discharge port 1
3 and the inside of the chemical liquid bottle 10 are connected to each other through a chemical liquid suction passage 14 and a flexible tube 15. The chemical solution suction passage 14 is formed so as to penetrate the tube wall of the plug body 1. Further, the flexible tube 15 connected thereto is provided such that its opening is located at the bottom in the chemical solution bottle 10.

Therefore, the tap water flows down at a high speed in the flow path narrowing portion 12, so that the pressure decreases. Thereby, the chemical solution in the chemical solution bottle 10 is sucked into the chemical solution suction channel 14 through the tube 15. Subsequently,
A small amount of this chemical solution is sucked through the chemical solution discharge port 13. Then, this small amount of chemical solution flows down on tap water.

The chemical solution having passed through the small-diameter flow path 11b is stirred and diluted in the mixing flow path 22 into tap water flowing down the large-diameter flow path 11a. In this way, dilution is performed at a predetermined dilution rate, for example, 500 times.

The flow path diameter g of each water flow path 16 is as follows:
A passage diameter G ₂ of the flow path 11a of the large diameter is formed in summing the channel diameter of the channel diameter G ₃ of the small diameter flow channel. Therefore, the same flow path resistance as that of the open flow path 11 is provided.

As described above, the dedicated flow path for sucking the chemical solution,
That is, by providing the small-diameter flow path 11b, the chemical solution can be sucked more efficiently.

(Sixth Embodiment) FIGS. 8 to 12 show a sixth embodiment of a water faucet for diluting a chemical according to the present invention. In the sixth embodiment, in particular, a sprinkler having a simple structure, easy to manufacture, and inexpensively provided has been obtained as a result. Basically, it is configured to have the following three requirements. First, the plug body 1 is formed in a straight tube 1A over its entire length. Next, the water supply hose 2 and the sprinkler 25, which are formed by the straight tubular body 1A and are connected to the front and rear ends of the plug body 1, are connected to each other by a screw-connected connector 28 (described later). thing. Finally, the channel constriction 12 is
It includes the female screw cylinder 9 for attaching the undiluted solution bottle 10 and is configured separately from the plug body 1. And it shall be comprised so that it may be retrofitted to the plug main body 1. Hereinafter, the specific structure will be described.

As shown in FIGS. 8 to 9 and FIG. 11, the plug body 1 is basically formed to have the same diameter without constriction or overhang over its entire length. That is, it is formed in a straight tube 1A. Male screws 27 are provided on the outer peripheral surfaces of the front and rear ends.
Is provided.

The straight tubular plug body 1 has a fifth
As in the embodiment (see FIGS. 6 and 7),
Are an upper large-diameter flow path 11a and a lower small-diameter flow path 11
b. The flow path diameter G of the large-diameter flow path 11a
And _2, the ratio of the flow path diameter of the channel diameter G ₃ of the small diameter flow channel 11b is 4: 1 to 3: is set at 2 range. And
In the lower small-diameter flow passage 11b, a flow passage narrowing portion 12 that narrows the width of the flow of tap water is formed as in FIGS. 1 to 4, 6, and 7.

Therefore, when the tap water flows down in the flow path narrowing portion 12, the flow velocity becomes large (a jet water flow). The flow path narrowing portion 12 is formed by the small-diameter flow path 11.
The inner surface of the tube in the middle of b is provided with a constriction. This constriction firstly moves the inner surface of the pipe in the middle of the small-diameter flow path 11b,
The tap water is sequentially swollen in the flowing direction. Thereafter again, obtained by forming so as to return to a predetermined channel diameter G ₃ of the small diameter flow channel 11b.

The channel narrowing portion 12 is formed above the mounting means 9 of the chemical bottle 10 as in FIGS. 1 to 4, 6 and 7. A chemical solution discharge port 13 is opened before the maximum bulging portion 12a, that is, on the side closer to the lower side of the tap water flow. The chemical solution discharge port 13 and the inside of the chemical solution bottle 10 are connected to each other via a chemical solution suction passage 14 and a flexible tube 15 connected thereto. The chemical solution suction passage 14 is formed to penetrate the tube wall of the plug body 1. Also,
The flexible tube 15 has the opening thereof
It is provided to be located at the bottom within 0.

The straight pipe 1A forming the plug main body 1 is provided with three water passages 16 having the same diameter as in the fifth embodiment. Each water passage 16 is provided with a similar on-off valve 17. The diameter g of each of the water flow passages 16 is the sum of the flow passage diameter G of the large-diameter passage 11a and the small-diameter passage 11b of the open passage 11.
(G ₂ + G ₃ ). That is, the ratio between the diameter of each water passage 16 and the diameter of the open passage 11 is designed to be 1: 1.

Further, connection caps 28 as connection tools are screwed into the external threads 27 provided on the outer peripheral surfaces of the front and rear ends of the straight pipe 1A. Then, via these connection caps 28, the water supply hose 2 and
A connection hose 29 connected to the sprinkler 25 is connected.

Each of these connection caps 28 has a large diameter on the side connected to the straight tubular body 1A. And, on the inner surface of this large diameter, a female screw 30
Is provided. The female screw 30 is screwed to the male screw 27 formed at the end of the straight tubular body 1A. In addition, these two connection caps 28 integrally have a small-diameter connection cylinder 31 on the other end side. And
The small-diameter connection cylinder 31 has an annular raised portion (rib) b for connecting a hose on the outer peripheral surface.

Therefore, the ends of the water supply hose 2 and the connection hose 29 are fitted into the connection tube 31.
Although not shown, a tightening ring is fitted on the outside of the connecting portion as necessary to prevent the hose from being detached.

As described above, there are adopted three configurations of the straight tube 1A, the male screw 27 formed at both ends thereof, and the connection cap 28 connected to the male screw 27 by the female screw 30. As a result, the plug body 1 can be manufactured much more easily and at a lower cost. In particular, by employing a synthetic resin material, the production thereof is further simplified and the cost is reduced.

A mixing channel 22 is formed inside the connection cap 28 on the side to which the connection hose 29 is connected. The mixing channel 22 includes the open channel 11,
It has a volume sufficient to mix the water flowing down the three water passages 16. Further, an enlarged flow path 32 is also formed inside the connection cap 28 to which the water supply hose 2 is connected. The enlarged flow path 32 also has a volume sufficient for flowing water through the open flow path 11 and the three water flow paths 16.

The small-diameter flow path 11 of the open flow path 11
As shown in FIG. 11, the flow path constricted portion 12 formed in the b and the female screw tube portion 9 provided integrally with the flow path constricted portion are separate from the linear tube 1A. Is configured.

The specific structure is as follows. First,
In the flow-down direction, the flow path is defined as a region extending from the flow path narrowed portion 12 of the small-diameter flow path 11b to a part reaching the maximum diameter part before and after the flow path narrowed part. Further, the upper side is defined as a range from the lowermost end of the large-diameter flow path 11a of the open flow path 11 or a region along an imaginary horizontal line passing below and below the lower end. Then, this portion including the female screw tube portion 9 is formed separately (piece P) from the linear tubular body 1A. In addition, a straight tube 1A
In this case, a concave portion is formed in which a piece P integrally formed including the flow path constricted portion 12 and the female screw cylindrical portion 9 is fitted.
The straight pipe 1A and the piece P are configured such that the piece P is fitted into the concave portion 33 and integrally joined by an appropriate means. As the joining means, for example, an adhesive can be used when the article is a synthetic resin molded article, and a means such as welding can be used when the article is a metal.

As described above, by adopting a method of separately configuring a portion having a complicated structure among the respective portions constituting the plug main body, a case where the whole is configured as one integrated body from the beginning. It is much easier and cheaper to manufacture.

In the sixth embodiment, the straight tube 1A does not include the on-off valve 4 for the entire flow channel shown in the other embodiments. This is because it is intended that the manufacture of the plug body 1 is easy and can be performed at low cost. As shown in FIG. 12 as a modification, the on-off valve 4 is formed separately from the straight pipe 1A as required.

As a specific connection structure, the water supply hose 2
The male screw 27 on the side to which is connected is used. Also,
The water supply hose 2 of the water pipe 4A provided with the on-off valve 4
A male screw 4B is formed on the outer periphery of the side end. The female screw 30 of the connection cap 28 on the water supply hose 2 side is screw-fitted to the male screw 4B. As described above, by providing the on-off valve 4 for the entire flow path as a separate body, there is an advantage that the manufacture of the plug body is further facilitated.

As described above, the sixth embodiment employs a technique in which a part having a complicated structure among the parts constituting the plug main body is formed separately. With this configuration, the manufacture is much easier and at lower cost than when the whole is configured as a single unit from the beginning. In particular, by using a synthetic resin material, this purpose is more remarkably exhibited.

In the configuration shown in FIG. 8, the sprinkler 25 is connected to the straight pipe 1A via the connection hose 29. However, as shown in FIG. 13, similarly to FIG. 1, a configuration in which a direct screw connection is used can also be adopted. Specifically, the connection cap 27 is tapered sequentially toward the sprinkler 25, and the mixing channel 22 is formed here. Then, as shown in FIG.
The base end of the water guide pipe 23 of the sprinkler 25 is screw-connected by 3A. With this configuration, the stopper body 1 and the sprinkler 2
5 can be handled as an integral object, so that work efficiency can be further improved.

Therefore, since the tap water flows down at a high speed in the flow path narrowing portion 12, the pressure decreases. As a result, the chemical in the chemical bottle 10 is sucked into the chemical suction passage 14 through the tube 15. Then, a small amount of the chemical solution is sucked through the chemical solution discharge port 13, and the small amount of the chemical solution flows down on tap water.

The chemical solution having passed through the small-diameter flow path 11b is stirred and diluted in the mixing flow path 22 into tap water flowing down the large-diameter flow path 11a. Thereby, the dilution is performed at a predetermined dilution rate, for example, 500 times.

Each of the water flow passages 16 is provided with the open passage 1.
This large-diameter flow path 11 has the same flow path resistance as
a and the small-diameter flow path 11b are formed to have a combined flow path diameter.

Further, by providing a dedicated channel for sucking the chemical solution, that is, a small-diameter channel 11b, the suction of the chemical solution can be performed more efficiently.

In each embodiment, the opening / closing valve 4 is attached to the stopper body 1.
The on-off valve 4 is provided as needed. Therefore, it is not an essential requirement to achieve the intended purpose of the present invention. When the on-off valve 4 is provided, tap water can be discharged and closed with a sprinkler at hand. Therefore, it is needless to say that the handling operation is simpler and more convenient.

Further, the synthetic resin material is not limited to the sixth embodiment, but can be used for a water tap having the structure of each of the other first to fifth embodiments. By adopting the synthetic resin material, the production is easier and the production cost can be reduced.

Further, the configurations of the embodiments can be diverted or combined with each other without departing from the intended purpose of the present invention.

In the drawings following FIG. 2, the portions related to the same configuration as the first embodiment are given only the reference numerals, and the detailed description is omitted.

[0092]

As will be understood from the above description, the sprinkling cock for diluting a chemical according to the present invention has the following effects. With a simple operation of mounting a bottle containing a chemical solution on the bottle mounting means and opening and closing the open / close valve, the chemical solution with a desired dilution ratio can be sprayed. Therefore, an expensive nebulizer or a container dedicated for diluting a chemical solution is not required, and no cumbersome preparation work is required. In addition, the change of the dilution ratio can be achieved by a very light and simple operation of opening and closing the on-off valve of the water flow passage. Therefore, it is possible to easily sprinkle the required amount of the chemical dilution water onto the cultivated plant without any trouble.

Then, if the chemical bottle is removed and water is sprayed, the chemical can be washed away without any excess. For this reason, when spraying another chemical solution after replacing the bottle with another bottle, there is no possibility that the previous chemical solution and a different type of chemical solution to be sprayed next are inadvertently mixed. Therefore, its practical value is extremely large.

In addition, the water tap according to the present invention can be switched by arbitrarily switching between dilution watering of a chemical solution and watering of only tap water. Therefore, a more convenient sprinkler can be provided.

Further, as shown in the first embodiment, the open flow passage and the water flow passage basically have the same flow passage diameter, and if a simple structure is adopted, the sprinkling faucet is It is very easy to manufacture and process, is simple, and can be provided at low cost.

Further, as in the second embodiment, the flow path diameters of a plurality of water flow paths other than the open flow path are different in size, and the dimensions are such that the flow rate becomes an integral multiple of the flow rate of the flow velocity increasing flow path. The set configuration can be adopted. According to this configuration, the magnitude change of the dilution ratio can be achieved very simply by a so-called one-touch operation in which only a specific water flow path that opens a preset dilution ratio is operated. At the same time, the desired dilution ratio can be obtained without paying any attention to the combination of the water passages. Therefore, the handling operation is very convenient especially for the elderly.

As in the third embodiment, all of the water flow paths are set to have the same flow path diameter as the flow path diameter of the narrow path portion of the open flow path, and the flow path resistance of all the flow paths is the same. If you do
More ideal suction of the drug solution can be expected.

Further, the following two means can be adopted as means for increasing the flow velocity in the open channel. First, a means (FIG. 1) for forming a narrow flow path (flow path narrowing section) in which the flow path diameter is partially narrowed, this narrow flow path (flow path narrowing section),
Means (FIG. 5) provided in the open channel and combined with the frusto-conical member can be employed.

Further, as in the fifth embodiment, the open channel is
If it is formed of a large-diameter flow path dedicated to flowing down tap water and a small-diameter flow path dedicated to sucking a chemical, suction of the chemical can be performed more efficiently. Therefore, a more ideal chemical solution dilution rate can be expected.

The means having the flow path constricted portion is adopted because the structure is simple and the manufacture is simple. Also,
The means provided with the truncated conical member is employed because the tap water can be more accurately made into a jet stream, and the chemical solution can be efficiently and more accurately drawn.

As in the sixth embodiment, the stopper main body is formed of a straight pipe, and the connection between the water supply hose and the watering device is also made.
The following effects are obtained when the connection is performed via a connection tool that is screw-connected to the front and rear ends of the straight tubular body. In other words, the plug body can be manufactured much more easily and at a lower cost. In particular, if a synthetic resin is used as a material, the manufacture is more simple and inexpensive. In addition, there is an advantage that the structure can be further simplified and the production can be performed at a low cost, in consideration of the above configuration and the configuration having the flow path constricted portion.

Further, the constricted flow path portion of the open flow path including the bottle mounting means is formed separately from the plug body, and the constricted flow path portion is attached to the mounting recess formed in the plug main body. Has the following effects when it is fixed in such a manner that it is connected to a dedicated small-diameter flow path for sucking the chemical solution. That is, its manufacture is extremely easy and can be performed at low cost. Compared to the case where the whole is manufactured as a single unit from the beginning, manufacturing of the parts with a complicated structure among the parts of the plug body as separate parts has simplified and simplified the manufacturing. It is.

[Brief description of the drawings]

FIG. 1 is a partially cutaway longitudinal sectional view showing a first embodiment of a water tap for diluting a chemical according to the present invention, with a chemical bottle attached.

FIG. 2 is a partially cut-away enlarged cross-sectional view of the first embodiment of the water tap for diluting a chemical solution according to the present invention, taken along line AA in FIG. 1;

FIG. 3 is a partially cutaway enlarged sectional view of a portion corresponding to a sectional view taken along the line AA in FIG. 1, showing a second embodiment of the water faucet for diluting a chemical solution according to the present invention.

FIG. 4 is a partially cut-away enlarged sectional view showing a third embodiment of the sprinkler for diluting a chemical according to the present invention, which corresponds to a sectional view taken along line AA in FIG. 1;

FIG. 5 is a partially cut-away enlarged longitudinal sectional view showing a fourth embodiment of a water tap for diluting a chemical according to the present invention, in which a main part with a chemical bottle is mounted.

FIG. 6 is a partially cut-away enlarged vertical sectional view showing a fifth embodiment of a water tap for diluting a chemical according to the present invention, with a chemical bottle mounted.

FIG. 7 is a partially cutaway enlarged cross-sectional view of a portion corresponding to a cross-sectional view taken along the line AA in FIG. 1, showing a fifth embodiment of the water faucet for diluting a chemical solution according to the present invention.

FIG. 8 is a partially cut-away enlarged longitudinal sectional view of a main part of a sprinkler for diluting a chemical according to a sixth embodiment of the present invention with a chemical bottle mounted.

FIG. 9 is an enlarged longitudinal sectional view of a main part of the water tap with the liquid bottle shown in FIG. 8 mounted, showing a sixth embodiment of the water tap for diluting a drug solution according to the present invention.

FIG. 10 is a partially cutaway enlarged sectional view showing a sixth embodiment of a water tap for diluting a chemical solution according to the present invention, taken along line AA in FIG. 8;

FIG. 11 is an enlarged exploded perspective view of a main part of a sixth embodiment of a water faucet for diluting a chemical solution according to the present invention.

FIG. 12 is a partially cutaway longitudinal sectional view showing a sixth embodiment of the water tap for diluting a chemical solution according to the present invention, which is provided with an on-off valve.

FIG. 13 is a partially cutaway longitudinal sectional view showing a sixth embodiment of a water tap for diluting a chemical solution according to the present invention, and showing another attachment means of a water sprinkler.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Plug main body, 2 ... Water supply hose, 9 ... Mounting means, 10 ... Chemical liquid bottle, 11 ... Open flow path, 11a ... Large diameter flow path, 11
b: small-diameter flow path, 12: flow path constriction, 13: chemical liquid discharge port, 14: chemical liquid suction flow path, 15: flexible tube,
16 ... water passage, 17 ... on-off valve, 22 ... mixing passage, 25
... water sprinkler, 26 ... frusto-conical member, 27 ... male screw, 28
... connection cap, 30 ... female screw, A: water supply flow path, f: flow path of the on-off valve body, G: flow path diameter of the open flow path, G ₁ ... flow path diameter of the flow path constricted portion, G ₂ ... flow of a large diameter passage diameter of road, channel diameter of G ₃ ... small-diameter flow path, the flow path diameter of g ₁ to g ₃ ... passing water flow path, P ... pieces.

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[Procedure amendment]

[Submission date] October 31, 1998

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claim 2

[Correction method] Change

[Correction contents]

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] Claim 3

[Correction method] Change

[Correction contents]

[Procedure amendment 3]

[Document name to be amended] Statement

[Correction target item name] Claim 4

[Correction method] Change

[Correction contents]

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] Claim 5

[Correction method] Change

[Correction contents]

[Procedure amendment 5]

[Document name to be amended] Statement

[Correction target item name] Claim 6

[Correction method] Change

[Correction contents]

[Procedure amendment 6]

[Document name to be amended] Statement

[Correction target item name] Claim 7

[Correction method] Change

[Correction contents]

[Procedure amendment 7]

[Document name to be amended] Statement

[Correction target item name] Claim 8

[Correction method] Change

[Correction contents]

[Procedure amendment 8]

[Document name to be amended] Statement

[Correction target item name] Claim 9

[Correction method] Change

[Correction contents]

Claims (9)

[Claims] 1. A water supply hose connection at one end,
At the other end, a plurality of water passages are independently arranged in a stopper body provided with a connection part for a watering tool having a watering nozzle at a tip, and one of the water passages is always provided with a tap. An open flow path through which water flows, a flow rate increasing flow path is formed, and the flow rate increasing flow path is provided with a mounting means for a bottle containing a chemical solution. The chemical solution discharge port of the chemical solution suction passage through which the chemical solution is sucked is opened, and the jet solution of the tap water flowing down in the flow velocity increasing flow passage sucks the chemical solution from the chemical solution suction flow passage and mixes it with the tap water. Further, the open and closed valves are respectively provided in the remaining water flow paths other than the open flow path, so that all the flow paths including the open flow path are joined at the tip thereof and flow down to the sprinkling nozzle. Formed in front of one or more of the flow channels Watering stopper for chemical dilution, characterized in that it is configured to change the dilution ratio of the chemical liquid by a combination of flow rate increases channel. 2. The flow rate increasing flow path is formed by partially narrowing the flow path diameter, and the liquid discharge opening of the liquid suction path is opened to the lower part of the narrowest flow path to improve the tap water flow downward. The water faucet for diluting a drug solution according to claim 1, wherein 3. The flow velocity increasing flow path is formed by providing a tapered frusto-conical member in the flow path substantially concentric with the flow path axis. 2. A sprinkling tap for chemical solution dilution according to claim 1, wherein a chemical solution discharge port of a chemical solution suction channel is opened in a truncated surface portion of the member. 4. The water spray for diluting a chemical according to claim 1, wherein the plurality of water flow paths other than the open flow path are dimensioned to have a flow path diameter that can obtain the same flow rate as the flow rate increase flow path. plug. 5. A plurality of water flow passages other than the open flow passages have different diameters from each other and are dimensioned such that the flow rate is an integral multiple of the flow rate of the flow velocity increasing flow path. The water tap for diluting a drug solution according to claim 1. 6. The chemical solution according to claim 1, wherein each of the plurality of water flow paths other than the open flow path has the same flow path diameter as the flow path diameter of the flow velocity increasing flow path of the open flow path. A faucet for dilution. 7. The open flow path includes a large-diameter flow path dedicated to flowing down tap water and a small-diameter flow path dedicated to sucking a chemical solution, and the flow-rate increasing flow path is formed in the small-diameter flow path. The water tap for diluting a chemical according to any one of claims 1, 2, 4, and 5. 8. The plug body provided with a water flow passage and an open flow passage is formed of a straight pipe, and the connection between the water supply hose and the sprinkler is made of the straight pipe. The watering for dilution of a chemical solution according to any one of claims 1, 2, 4, 5, and 7, which is performed via a connector screwed to screws formed at both front and rear ends of the liquid crystal. plug. 9. The open flow path has a narrow flow path portion including a bottle mounting means, which is formed separately from the stopper body, and has a narrow flow path dedicated to sucking the drug solution. 9. The sprinkling tap for chemical liquid dilution according to claim 1, wherein the flow path portion is fixed to a mounting recess formed in the plug main body in a continuous manner.