JP3174379U - Water softener ejector - Google Patents

Abstract

To provide an ejector having a structure that can be easily adjusted to an optimum salt water absorption performance suitable for the type of a water softener.
An ejector main body, a conical first nozzle, and a second nozzle are provided. The ejector body has a threaded portion at both ends, and a suction inlet 7 with a valve, which is a salt water suction channel that joins the tap water channel from the side surface, is provided at the center of the central tap water channel. A 2nd nozzle injects the tap water injected from the 1st nozzle, and the salt solution which flows in from a suction inlet with a valve.
[Selection] Figure 5

Description

The present invention relates to an ejector (flow water pump) of a water softener.

First, in order to explain the function of the ejector of the water softener, the outline of the water softener with an ejector will be described with reference to FIG.
The water softener container 50 is filled with an ion exchange resin and sealed with a water softener cap 50-1. The water softener cap 50-1 includes a water pipe 51, a water on / off valve 52. The tap water switching valve 53 is connected in order. The tap water injection cap 54 is hermetically connected. Tap water is injected into the container 50 in the flow of arrows P and Q. Calcium and magnesium, which are hard water components dissolved in tap water, are removed with an ion exchange resin, and soft water is collected from the soft water drainage base 59 and the soft water drain pipe 60. When a certain amount of water is softened, the ion exchange resin deteriorates and the water softening ability decreases, so it needs to be regenerated and activated. The ion exchange resin is regenerated and activated with sodium ions by the passage of saline. In order to suck the salt water 62 into the ion exchange resin in the water softener container 50, the water softener cap 50-1 is arranged in the order of the bypass flow path, that is, tap water switching valve 53, serpentine pipe 55, ejector 1, and elbow pipe 56 in this order. Are sealed and connected. When the tap water switching valve 53 is switched and tap water is flowed in the directions of arrow P, arrow E, arrow F, and arrow G, the saline water 62 is formed in the ion exchange resin by the action of the ejector 1 due to the flow of tap water. Suction and injection are performed, and the ion exchange resin is regenerated and activated by the saline 62.
The conventional ejector 1 having such a function is difficult to adjust because the saline suction performance is fixed depending on the capacity of the water softener.

Problems that the device tries to solve

The amount of soft water required varies depending on the facility that uses soft water, such as homes, beauty salons, and hotel kitchens. Therefore, there are types of water softeners with different capacities. The inflow resistance of tap water varies depending on the capacity. In the water softener having a large inflow resistance, there is a problem that the tap water loses the internal water pressure, the tap water flows backward from the saline solution intake port of the ejector 1, and the saline solution 62 cannot be sucked. Moreover, unless the ejector 1 has a performance suitable for the water softener, there is a problem that the suction efficiency of the saline solution 62 is poor, a large amount of tap water is used, and water is not saved. Therefore, an ejector having a structure that can easily adjust an ejector having a performance suitable for the model is desired.

Means for the Invention to Solve

When tap water flows between the nozzle diameter d1 (FIG. 2) of the injection nozzle 2 inside the ejector 1 and the diameter d2 (FIG. 2) of the injection water receiver, an injection flow S is generated, The water pressure decreases and a saline suction flow T is generated. The strength of the saline suction flow T is determined by the water pressure of tap water, the flow resistance in the container of the water softener, the jet nozzle diameter d1, and the jet receiver diameter d2.
Therefore, the present invention has a structure in which the nozzle 12 (FIG. 5) having the injection nozzle diameter d1 and the injection water receiver 11 (FIG. 5) (FIG. 9) having the inner diameter d2 can be easily replaced and adjusted. The point is solved.

Effect of device

1: It can be easily adjusted to an ejector with good suction efficiency that matches the inflow resistance of the water softener.
2: Tap water can be used efficiently and tap water can be saved.
3: Even a type of water softener with a large inflow resistance can provide an ejector with a strong suction force.
4: As a material, if a commercially available pipette tip (FIG. 7) is used, it is inexpensive.

In the water softener of FIG. 1, the conventional ejector 1 is replaced with an ejector 9 which is an embodiment of the present invention (FIG. 5) and hermetically fixed with a tightening nut 4. At that time, the inner diameter d2 of the jet water receiver 11 and the inner diameter d1 of the nozzle 12 are appropriately selected so as to fit the container of the water softener, and are exchanged and inserted into the ejector body 9. With the flow of tap water, the saline 62 is efficiently injected into the ion exchange resin and regenerated and activated.

The structure of the conventional ejector 1 will be briefly described with reference to FIGS.
A suction base 7 with a valve is screwed into the ejector body 1. (Figure 3)
7-1 opens and closes a valve with a handle. Inside the ejector body 1, the snake pipes 5 and 6 are fixed by fastening nuts 4 via packings 3 at both ends of the ejector body 1 into which the injection nozzle 2 (FIG. 4) is screwed.
The flow of tap water becomes an injection flow S by the injection nozzle 2. Around the tip of the injection nozzle 2, a negative pressure is generated, and a saline suction flow T is generated.
In this way, the saline water is sucked and injected into the water softener container 50 by the tap water flow S, and the ion exchange resin is regenerated and activated.

Next, an embodiment of the ejector structure of the present invention will be described with reference to FIGS. 5, 6, 7, 8, and 9. FIG.
FIG. 5 shows a cross-sectional view thereof. A nozzle receiver 10 is press-fitted and fixed to 9 of the ejector body A of the present invention. Further, a suction cap 7 with a valve is screwed. Inside the ejector body A of the present invention, a nozzle 12 and a spray water receiver 11 are inserted. The serpentine tubes 5 and 6 are hermetically fixed to both ends with a tightening nut 4 via a packing 3. Tap water flows through the nozzle 12 and jet water S is generated. A negative pressure is generated around the tip of the nozzle 12, and a saline suction flow T is generated.
FIG. 6 is a sectional view in which the nozzle receiver 10 is press-fitted and fixed to the ejector body A-9.
FIG. 7A is a front view of a commercially available pipette tip, and B is a side view thereof.
Cut according to the size at X0-Y0, and cut the nozzle diameter d1 at the tip to an appropriate diameter. Generally, it is cut by X1-X2 and X3-X4 so as to be 1 mm to 3 mm.
Since it is mass-produced and diverted, it is inexpensive. You can purchase it for about one yen.
FIG. 8 shows a side view thereof. d1 is cut to an appropriate nozzle diameter. It is adjusted from 1 mm to 3 mm.
FIG. 9 shows a side view of the jet water receiver 11. The nozzle 12 is cut and press-fitted as 12F. d2 is adjusted from 3 mm to 6 mm.
However, the pipette tip (FIG. 7) is made of plastic and is suitable for softening tap water, but is not suitable for softening hot water, and metal is used.
Next, another embodiment of the present invention will be described.
First, returning to FIG. 2, the flow will be described. The conventional ejector 1 has a jet nozzle diameter d1 of 3 mm and a jet water receiving hole diameter d2 of 4 mm. If the amount of water jetted from d1 is large, the saline suction flow T is not generated when the flow resistance in the container is large, and there is a problem that the tap water flows backward from the valve-equipped suction cap 7. If there is a gap between the spray nozzle 2 and the spray water receiving hole d2, it is convenient for salt inhalation when the flow resistance is small, but conversely, if the flow resistance is large, it causes a reverse flow.
An embodiment of the ejector 9 that does not flow backward will be described with reference to FIGS.
FIG. 10 shows a cross-sectional view of another embodiment of the ejector of the present invention. A suction base 7 with a valve is screwed into the ejector body B13 of the present invention. An injection piece receiver 14 is press-fitted and fixed inside. An O-ring 15 for preventing backflow is inserted. In addition, an ejection piece 16 is inserted. The serpentine tubes 5 and 6 are hermetically fixed to both ends with a tightening nut 4 via a packing 3. Tap water flows through the nozzle portion 16-1 of the jet piece 16, and jet water S is generated. A negative pressure is generated around the tip of the ejection piece nozzle portion 16-1, and a saline suction flow T is generated in the saline suction port 16-3.
Compared with the conventional ejector of FIG. 2, the ejector body 13 of the present invention of FIG. 10 prevents back flow of tap water by an O-ring 15 and a saline solution inlet 16-3 of 16-3.
FIG. 11 shows a cross-sectional view in which the ejection piece receiver 14 is press-fitted and fixed inside the ejector body B13. Reference numeral 15 denotes an O-ring.
12A is a sectional view of the ejection piece 16, and B is a side view thereof. 16-1 is an injection nozzle part, 16-2 is an expansion negative pressure part, and 16-3 is a saline solution inlet.
The injection nozzle part d1 is set to 1 mm to 2 mm, the expansion negative pressure part d2 is set to 2 mm to 4 mm, and the salt suction port d3 is set to about 2 mm to 3 mm.
FIG. 13 is a sectional view of the ejection piece receiver 14, and B is a side view thereof. 15 is an O-ring. FIG. 14A is a cross-sectional view of another embodiment of the injection piece. B shows a side view thereof.
In order to increase the saline solution suction efficiency, the spray nozzle unit 17-1 is doubled.
FIG. 15A shows a cross-sectional view of another embodiment of the ejection piece. B shows a side view thereof.
In order to increase the saline solution suction efficiency, the spray nozzle portion 18-1 is further tripled.

The external appearance sketch of the conventional water softener. A is a sectional view of a conventional ejector. B is a side view thereof. FIG. 3 is a cross-sectional view in which a valve-equipped suction cap 7 is screwed into the ejector body 1 of FIG. 2. A is sectional drawing of the conventional injection nozzle 2. FIG. B is a side view thereof. Sectional drawing of the ejector of one Example of this invention. Sectional drawing of the ejector main-body part 9 of FIG. A is a front view of a commercially available pipette tip. B is a side view thereof. Sectional drawing when cutting | disconnection adjustment of this invention and the injection nozzle 12 is carried out. A is a cross-sectional view of the injection nozzle receiver 11. B is its side view. Sectional drawing of the ejector of one Example of this invention. Sectional drawing of the ejector main-body parts A and 13 of FIG. FIG. 11 is a cross-sectional view of the ejection piece 16 of FIG. 10. B is its side view. A is a cross-sectional view of the ejection piece receiver 14. B. The side view. FIG. B is a side view thereof. FIG. B is a side view thereof.

DESCRIPTION OF SYMBOLS 1 Conventional ejector main body 2 Conventional injection nozzle 3 Rubber packing 4 Clamping nut 5 Serpentine tube 6 Serpentine tube 7 Suction cap with valve 9 Present invention ejector main body A 10 Nozzle receiver 11 Spray water receiver 12 Nozzle 13 Present invention ejector main body B 14 Injection frame receiver 15 O-ring 16 Injection piece 17 Two-part injection piece 18 Three-part injection piece 50 Water softener container 51 Tap water conduit 52 Tap water opening / closing valve 53 Tap water switching valve 54 Tap water injection cap 55 Serpentine pipe 56 Elbow pipe 57 Inspection cock 58 Inspection pipe 59 Soft water drain cap 60 Soft water drain pipe 61 Saline tank 62 Saline 63 Saline tube

Claims (1)

    In an ejector (flowing water pump) used for a water softener, a jet that can be exchanged for an ejector body 9 having a salt intake port 7 with an open / close valve screwed, screw portions 9-1 at both ends, and a nozzle receiver 10 fixed inside. Ejector having water receiver 11 and replaceable nozzle 12

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