JP2005002693A - Water saving instrument - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a water saving instrument which is easily installable in a pipe such as a water service pipe, runs water in a suitable saved amount depending on the circumstance of a installation location, ensures a water saving state at a stable flow rate corresponding to variation in water pressure, maintains a considerable stream and a suitable flow velocity even in the water saving state, and is good in usability. <P>SOLUTION: The water saving instrument is arranged in the pipe such as the water service pipe in order to save water, and has at least an engaging section 12 which is engaged with an insertion end of the water pipe inserted into a water pipe joint, and a flow rate adjusting section 20 which is arranged in the insertion end of the water pipe by the engagement of the engaging section 12. The flow rate adjusting section 20 forms a flow rate adjusting channel 22 in which a flow rate adjusting ring 23 is fitted loosely. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a water-saving device, and more specifically, it is disposed in a water tap connection portion, a water tap connection portion of a mixer tap, and other pipes such as a water pipe, and a flow rate higher than necessary is from a terminal such as a curan. The present invention relates to a water-saving device for saving water so as not to be discharged.
[0002]
[Prior art]
Conventionally, in a water supply terminal such as a faucet, when the terminal is opened, the amount of water discharged is adjusted according to the opening degree.
However, the amount of water used in a home kitchen or bathroom, etc., is generally not sufficient to open more than half of the faucet, and in most cases it is sufficient to be less than half open. Also, in high-rise buildings such as hotels, hospitals, office buildings, etc., depending on the installation situation of the receiving tank and elevated tank, for example, even when the faucet is used at the same 90 degree opening, each floor and each room The current situation is that the water discharge is different. Only the maximum water pressure and the minimum water pressure are determined at the stage of water supply design, and there is no problem if the minimum water pressure is strictly observed at the construction stage. It has been discharged. Therefore, in the past, there were only means to call for water saving or to forcibly stop using water even if droughts were reached many times.
Of course, conventionally, a water-saving device has been provided which is attached to a part of a flow path such as a water pipe so that water can be saved from the usual level so that the flow rate does not become excessive even if the faucet is opened too much.
[0003]
[Problems to be solved by the invention]
However, most of the water-saving devices that have been provided in the past are simply a hole for water-saving, so even if the discharge flow rate can be suppressed simply, the way the water comes out is sparse. In addition, most of the devices cannot adjust the appropriate discharge flow rate according to the place of use. For example, the flow rate adjustment is very rough, and the adjustment according to the situation such as the water pressure cannot be performed well. For this reason, there was a problem that the feeling of use after installation of the water-saving device was not good.
[0004]
Therefore, the present invention solves the above-mentioned conventional problems, can be easily installed in pipes such as water pipes, can flow out an appropriate water-saving flow rate according to the situation of the place of use, and changes to water pressure. Water saving equipment can be maintained at a stable flow rate even when water is generated, and the water flow can be maintained at an appropriate flow rate in the water-saving mode. Is an issue.
[0005]
[Means for Solving the Problems]
The water-saving device of the present invention that solves the above-mentioned problems is a water-saving device that is disposed in a pipe line of a water pipe or the like and saves water so that an excessive flow rate is not discharged from a terminal such as a currant. A locking portion for locking with respect to the insertion end portion of the water pipe inserted into the other water pipe end portion of the pair of water pipes constituting the portion, and the insertion end of the water pipe by the locking by the locking portion A flow rate adjusting unit disposed in the unit, wherein the flow rate adjusting unit forms a flow rate adjusting flow path and a flow rate adjusting ring is loosely fitted in the flow rate adjusting flow path. One feature.
Further, the water-saving device of the present invention is a water-saving device that is arranged in a pipe line of a water pipe or the like and saves water so that an excessive flow rate is not discharged from a terminal such as a currant, and constitutes a water pipe connection portion. Of the pair of water pipes, a locking part for locking with respect to the insertion end part of the water pipe inserted into the other water pipe end part, and the locking by the locking part are arranged in the insertion end part of the water pipe. And a flow rate adjusting portion that forms a flow rate adjusting flow path and loosely fits the flow rate adjusting ring in the flow rate adjusting flow path, and the flow rate adjusting ring is configured to flow by water pressure. The second feature is that the flow passage cross-sectional area is changed and adjusted by being moved in the adjustment flow passage.
In the water-saving device according to the present invention, in addition to the first or second feature, a receiving seat for receiving the flow rate adjusting ring moved by the water pressure is formed in the flow rate adjusting unit. A third feature is that the water flow passing through the outside of the flow rate adjusting ring is closed by contacting the seat, and only the water flow passing through the ring hole of the flow rate adjusting ring is discharged.
Further, the water-saving device according to the present invention has a flow control ring in a direction perpendicular to the water flow direction by inserting a flow control ring into the flow control unit in addition to any of the first to third features. A fourth feature is that an axial column for stabilizing the shaft is formed.
Further, the water-saving device of the present invention, in addition to any one of the first to fourth features, a rectifying path that rectifies and collects the flow of running water that has come out of the flow rate adjusting unit continuously downstream of the flow rate adjusting unit. The fifth feature is that the above is formed.
In addition to the first to fifth features, the water-saving device of the present invention has a sixth feature that the flow rate adjusting ring is loosely fitted to the flow rate adjusting portion in a freely replaceable manner.
Further, in the water-saving device of the present invention, in addition to any one of the first to sixth features, the flow rate adjusting unit is composed of a flow rate adjusting body as one independent unit, and is attached in a replaceable manner. This is the seventh feature.
Moreover, the water-saving device of the present invention is characterized in that, in addition to any of the first to seventh features, a magnet material that emits a strong magnetic force is applied to at least a part of the inner surface of the flow channel in contact with running water. It is a feature.
[0006]
According to the water-saving device according to the first feature, the water-saving device is attached by the engaging portion using the connection end portion of the water pipe inserted at the water pipe connection portion. A water-saving device can be easily attached by attaching to the connection end of the water pipe with a locking portion. Further, when attaching a terminal such as a curan, it is convenient to attach a water-saving device to the insertion end of the water pipe of the terminal.
In the flow rate adjusting unit, the flow rate can be adjusted by the dimensional relationship between the flow rate adjusting flow path and the flow rate adjusting ring loosely fitted therein. In other words, by preparing several combinations of a flow rate adjustment flow path adjustment ring and a flow rate adjustment ring that occupies a part of the cross sectional area and reduces the flow path cross sectional area in advance, A water-saving device having a channel cross-sectional area that can save water appropriately according to the situation can be attached. In short, it is possible to easily adjust the flow rate by preparing a plurality of flow rate adjusting rings having different ring hole diameters.
[0007]
According to the water-saving device according to the second feature, the same effects as those of the water-saving device according to the first feature are exhibited.
In addition, since the flow rate adjustment ring loosely fitted in the flow channel of the flow rate adjustment unit is configured to change and adjust the flow channel cross-sectional area by moving with water pressure, A stable water-saving flow rate can be discharged against the water pressure that changes depending on the situation.
[0008]
According to the third feature, in addition to the function and effect of the first or second feature, when the flow rate adjustment ring is moved by water pressure and abuts against the seat of the flow path adjustment unit, The water flow that flows out of the outside is blocked and the flow rate is reduced. That is, when the water pressure increases to a certain level, the amount of water is further reduced and the water-saving flow rate becomes stable.
Furthermore, since the flow that has been reduced and reduced is collected and discharged by the ring hole only by flowing out from the ring hole of the flow rate adjusting ring, the water flow in the water-saving state is maintained and an appropriate flow rate is maintained. It is possible to carry out in the state that was made to. Therefore, it is possible to maintain a good feeling of use without sparsely flowing out water.
[0009]
According to the fourth feature, in addition to the operational effects of the first to third features, a flow rate adjusting unit is formed with a shaft column, and a flow rate adjusting ring is inserted into the shaft column, whereby the flow rate is adjusted. Since the attitude of the adjustment ring is stabilized in a direction perpendicular to the water flow direction, the flow rate of water saved and discharged is also stabilized.
[0010]
According to the fifth feature, in addition to the function and effect of any one of the first to fourth features, a rectification path is continuously formed downstream of the flow rate adjusting unit so that the Since the flow of the running water is rectified, the water saved and reduced can be discharged from the terminal in a state that is easy to use.
[0011]
According to the sixth feature, in addition to the operational effects of any of the first to fifth features, by making the flow rate adjustment ring interchangeable, the place where the water-saving device is used, the water-saving condition, and other conditions Depending on the situation, it is possible to replace the flow rate adjustment ring that is optimal for the condition and situation, so that more appropriate water saving can be performed. Also, since the flow rate adjusting ring is usually a rubber ring, it is convenient for replacing a deteriorated flow rate adjusting ring.
[0012]
According to the seventh feature, in addition to the function and effect of any one of the first to sixth features, the flow rate adjusting ring can be attached interchangeably as a flow rate regulating body comprising one independent unit. This makes it possible to easily attach and replace the optimum flow rate adjusting body according to the place where the water-saving device is used, the water-saving condition, other conditions, and the situation.
[0013]
According to the eighth feature, in addition to the function and effect of any one of the first to seventh features, a magnet material that emits a strong magnetic force to at least a part of the inner surface of the flow path configured in the water-saving device. By applying, the water quality improvement effect by magnetic force can be added to a water-saving device, and the convenient device which can exhibit two effects together with one device can be provided.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be further described with reference to the following drawings.
1 to 6 relate to a water-saving device according to the first embodiment of the present invention, FIG. 1 is a longitudinal sectional view of the water-saving device, FIG. 2 is a longitudinal sectional view of the main body of the water-saving device, and FIG. Fig. 4 is a plan view of the flow rate adjusting unit, Fig. 5 is a longitudinal sectional view showing a state in which the water-saving device is attached to a water pipe connection unit such as a water supply, and Fig. 6 shows where the water-saving device is mounted. It is a perspective view which illustrates. FIG. 7 is a longitudinal sectional view of a water-saving device according to the second embodiment of the present invention.
[0015]
First, a first embodiment will be described with reference to FIGS. The first embodiment is a water-saving device in which the flow rate adjusting unit 20 can be attached interchangeably.
That is, the water-saving device includes the device main body 10 and the flow rate adjusting unit 20. In this embodiment, the flow rate adjusting unit 20 constitutes a flow rate adjusting body as one independent unit.
[0016]
The instrument body 10 has a cylindrical portion 11 formed with an outer flange 12 as a locking portion at one end.
The cylindrical portion 11 is formed with the outer flange 12 and has one end as an inlet 13. The inflow port 13 is formed with its opening slightly inclined downward, so that the inflow noise is reduced and the water flow smoothly flows into the flow rate adjusting unit 20.
A fitting recess 14 is formed at a downstream position of the inflow port 13 for detachably attaching a flow rate adjusting unit 20 as the flow rate adjusting body. Further, a rectifying path 15 is formed downstream of the stepped portion 14a of the fitting recess 14. The length of the rectification path 15 is set to a length necessary for adjusting the water flow flowing out from the flow rate adjustment unit 20 to stable rectification.
The instrument body 10 is made of metal or plastics, but can be made of charcoal, ceramics, or other non-metallic materials.
[0017]
The flow rate adjusting part 20 is attached as a flow rate adjusting body by being detachably fitted to the fitting recess 14 of the tubular part 11 of the instrument body 10, that is, exchangeable.
The flow rate adjusting unit 20 has a short cylinder part 21, and a flow rate adjusting flow path 22 is configured as an inner hole of the short cylinder part 21. A flow rate adjusting ring 23 is loosely fitted in the flow channel adjusting flow channel 22.
Drop-off prevention grids 24 are formed on both end surfaces of the short tube portion 21 of the flow rate adjusting portion 20 so that the flow rate adjusting ring 23 does not drop from the short tube portion 21.
The flow rate adjusting portion 20 is formed with a shaft column 25 into which the flow rate adjusting ring 23 is inserted in the center of the inner hole of the short cylinder portion 21. The axial column 25 has an inner hole of the short cylinder portion 21, that is, a posture of the flow rate adjusting ring 23 that is loosely fitted in the flow rate adjusting flow path 22 in the water flow direction (the central axis direction of the inner hole of the short cylinder portion 21) It is provided for stabilization in a direction perpendicular to the direction (horizontal direction in FIGS. 1 and 3). The direction perpendicular to the water flow direction does not mean strictly a direction perpendicular to the water flow direction but, in a broad sense, means a direction that does not deviate significantly from the direction perpendicular to the water flow direction.
The short cylinder portion 21, the fall prevention lattice 24, and the shaft column 25 of the flow rate adjusting unit 20 are made of metal or plastic, but can be made of ceramics or other non-metallic materials.
[0018]
The flow rate adjusting ring 23 has a ring shape, and a gap S and a ring formed between the short cylinder portion 21 outside the ring 23 as shown in FIG. 3 while being loosely fitted in the flow rate adjusting flow path 22. Water flows out through the hole H.
The flow rate adjusting ring 23 uses a solid ring, but a hollow ring can also be used. A rubber material is used as the material, but other plastics may be used.
The first flow rate adjustment for the purpose of saving water can be performed by the dimensional relationship between the flow rate adjustment flow path 22 and the flow rate adjustment ring 23 fitted loosely there. In other words, by adjusting the cross-sectional area of the flow rate adjusting ring 23, the size of the gap S and the ring hole H can be changed and adjusted, thereby adjusting the outflow amount.
Therefore, actually, a plurality of types of flow rate adjusting rings 23 having different types of cross-sectional areas are provided in advance, and a plurality of types of flow rate adjusting units 20 are prepared by loosely fitting the plurality of types of flow rate adjusting rings 23. When installing a water-saving device, an appropriate flow rate adjustment unit 20 is selected from a plurality of types according to the location conditions, other conditions, and circumstances of installing the water-saving device, and the selected flow rate adjustment unit 20 is provided. By attaching a water-saving device, appropriate water-saving can be performed according to the location.
The flow rate adjusting ring 23 loosely fitted in the flow rate adjusting flow path 22 can also be manufactured to have a size so as to be in close contact with the inner wall of the short cylindrical portion 21. In this case, most of the water flowing through the flow rate adjusting unit 20 passes through the ring hole H of the flow rate adjusting ring 23, but various dimensions of the ring hole H are prepared in advance, and the water according to the situation can be selected. That's fine.
[0019]
The flow path adjusting portion 20 is provided with a seat 26 that receives the loosely fitted flow rate adjusting ring 23 on the inner surface of the inner hole of the short cylinder portion 21. The seat 26 is a seat that receives the flow rate adjusting ring 23 at the moving end when the flow rate adjusting ring 23 is moved downstream in the flow rate adjusting flow path 22 by water pressure. When the flow rate adjusting ring 23 comes into contact with the receiving seat 26, the water flow that has flowed out through the gap S outside the flow rate adjusting ring 23 is blocked from flowing out. As a result, the water flow is blocked by the ring hole of the flow rate adjusting ring 23. Only those passing through H will flow out, and the overall flow rate will be reduced. Of course, even before the flow rate adjustment ring 23 completely contacts the seat 26, the flow rate adjustment ring 23 flows out through the gap S outside the flow rate adjustment ring 23 as it approaches the seat 26 side by being pushed by water pressure. The resistance to the flowing water increases, and the flow rate flowing out through the gap S is reduced.
That is, in the water-saving device of the present invention, the second flow rate adjustment for the purpose of saving water is performed by setting the gap S outside the flow rate adjustment ring 23 by the flow rate adjustment ring 23 and the receiving seat 26 that are moved according to the applied water pressure. This can be done by reducing or blocking the flow of water flowing through. In this second flow rate adjustment, when the water pressure increases according to the change in water pressure, the flow cross-sectional area or flow resistance is increased to restrict the flow rate, and the water-saving flow rate according to the water pressure is automatically discharged stably. is there.
[0020]
Although the seat 26 is formed on the outlet side of the flow rate adjusting flow path 22, it functions normally even if the flow rate adjusting portion 20 is fitted into the fitting recess 14 of the instrument body 10 from any direction. As described above, the receiving seats 26 may be provided symmetrically on the inlet side and the outlet side of the flow rate adjusting flow path 22.
The seat 26 can be replaced with a fall prevention grid 24. In this case, the flow rate adjusting ring 23 is pushed by the water pressure and comes into contact with the fall prevention grid 24, so that the flow rate is greatly reduced as compared with the case where the flow rate adjustment ring 23 is not in contact. Of course, since the literal receiving seat 26 is not provided, the water flow passing outside the flow rate adjusting ring 23 is not completely blocked, but the effect of the flow rate adjustment is exhibited.
In addition, the flow rate adjusting flow path 22 is formed to become narrower as it goes downstream, and the gap S outside the flow rate adjusting ring 23 becomes narrower as the flow rate adjusting ring 23 moves downstream due to water pressure. May be.
[0021]
Although the short cylinder portion 21 of the flow rate adjusting portion 20 is not shown in the drawing in order to allow the flow rate adjusting ring 23 to be inserted into the short cylinder portion 21 or to be exchanged in and out of the short flow rate adjusting ring 23, It is good to comprise so that it can isolate | separate into one, or it is good to make the one end side of the cylindrical part 21 into a cover shape or a cap shape. Or it can be set as the structure which can remove the drop-off prevention grid 24 formed in one end side.
By configuring the short cylinder portion 21 so that the flow rate adjusting ring 23 can be attached and taken out, the flow rate adjusting ring 23 itself can be exchanged with the flow rate adjusting portion 20. In this case, by replacing only the flow rate adjusting ring 23, it is possible to provide a water-saving device capable of adjusting a preferable flow rate, and it is possible to replace the deteriorated flow rate adjusting ring 23.
[0022]
An example of the mounting arrangement of the water-saving device in the pipe in a water pipe or the like will be described with reference to FIGS.
The water-saving device is disposed in the insertion end 1a of the water pipe 1 inserted into the water pipe end 2a of the other water pipe 2 of the pair of water pipes 1 and 2 constituting the water pipe connection portion A. The inserted water pipe 1 has a smaller diameter than the other water pipe 2 and is usually positioned downstream of the flow path with respect to the water pipe 2.
The instrument main body 10 is locked to the end face of the insertion end 1 a of the water pipe 1 by the outer flange 12, and the cylindrical part 11 of the instrument main body 10 is placed in the insertion end 1 a of the water pipe 1. . 3 is a cap nut and 4 is a packing.
Of course, in addition to the outer flange 12, other means can be added to the locking of the instrument body 10 to the water pipe 1.
The manner in which the tubular part 11 is arranged in the insertion end 1a and the outer flange 12 is locked to the end surface of the insertion end 1a is very simple as a method of attaching the instrument main body 10 to the water saving instrument, Easy way.
[0023]
The water pipe connecting portion A to which the water-saving device is attached includes, for example, a faucet pipe in addition to the water pipe connecting portion A between the water pipe 2 on the main body side of the two-valve mixer tap and the water pipe 1 on the faucet side in a water tap as shown in FIG. The connection part of this, the connection part of a shower hose, the connection part of a shower head, the water pipe connection part in the middle of the pipe line of a water pipe, the connection part of the water pipe of the water supply terminal which attached curan etc. correspond.
Since the water pipe connecting portion A to which the water-saving device is attached is usually attached downstream of the stop cock, there is an advantage that the installation work can be performed without closing the main tap of the water supply.
[0024]
With reference to FIG. 7, a water-saving device according to a second embodiment of the present invention will be described. In the second embodiment, unlike the case of the first embodiment, the flow rate adjusting unit 20 is not a replaceable unit.
In other words, the flow rate adjusting unit 20 of the water-saving device is formed integrally with other water-saving device parts. The configuration or function of the flow rate adjusting unit 20 itself is the same as that of the first embodiment. The same members, portions, and elements are denoted by the same numbers, and description thereof is omitted.
However, the short cylinder portion 21 is not an independent cylinder as in the first embodiment, but is formed integrally with a portion corresponding to the instrument main body 10 in the first embodiment.
[0025]
An outer flange 12 to be locked to the end face of the insertion end 1a of the water pipe 1 in FIG. 5 is formed in a portion corresponding to the instrument main body 10 in the first embodiment, and an inflow port 13 is formed. Has been. Further, a rectification path 15 is formed downstream of the flow rate adjustment unit 20.
In this embodiment, the rectifying path 15 is a cylindrical inner hole made of a magnet material 16 that generates a strong magnetic force. The magnet material 16 made of a cylindrical body is held by a holding piece 17 of the magnet material 16. The magnet material 16 that is configured as a separate body can be attached as a part of the water-saving device by the holding piece 17.
The flow rate adjusting ring 23 can be exchanged with respect to the flow rate adjusting unit 20. In this case, for example, the upper end of the flow rate adjusting unit 20 is configured as a lid so that it can be removed.
The magnet material 16 may be a neodymium magnet, for example. In short, the position where the magnet material 16 is applied is at least part of the inner surface of the flow path formed by the water-saving device.
By applying the magnetic material 16 that generates a strong magnetic force, an effect of improving the quality of running water is expected.
Of course, in the water-saving device of the first embodiment, a magnet material may be applied to at least a part of the inner surface of the flow path, for example, a magnetic material that generates a strong magnetic force is applied to the rectifying path 15.
[0026]
【The invention's effect】
The present invention has the above-described configuration and operation. According to the water-saving device according to claim 1, the water-saving device can be easily attached by locking the water-saving device to the connection end of the water pipe by the locking portion. Can do. Further, when attaching a terminal such as a curan, it is convenient to attach a water-saving device to the insertion end of the water pipe of the terminal.
According to the water-saving device according to claim 1, in the flow rate adjustment unit, a plurality of combinations having different dimensional relationships between the flow rate adjustment flow path and the flow rate adjustment ring loosely fitted therein are prepared in advance. Thus, it is possible to save water appropriately in any place by attaching the appropriate combination according to the condition or situation of the place of attachment.
Further, according to the water-saving device according to claim 1, the flow rate adjusting ring loosely fitted in the flow channel of the flow rate adjusting unit is configured to change and adjust the flow channel cross-sectional area by moving by the water pressure. Therefore, a stable water-saving flow rate can be discharged with respect to the water pressure that changes depending on other conditions such as the installation location and time.
Moreover, according to the water-saving instrument of Claim 2, there exists the same effect as the effect by the structure of the said Claim 1.
In addition, since the flow rate adjustment ring loosely fitted in the flow channel of the flow rate adjustment unit is configured to change and adjust the flow channel cross-sectional area by moving with water pressure, A stable water-saving flow rate can be discharged against the water pressure that changes depending on the situation.
Further, according to the water-saving device according to claim 3, in addition to the effect of the configuration according to claim 1 or 2, stable water-saving can be performed while automatically adjusting the flow rate to flow out according to the change in water pressure. it can.
Further, when the outflow amount decreases due to a change in water pressure, the reduced flow rate is allowed to flow out through the ring hole of the flow rate adjustment ring, so that the water flow can be collected and maintained at an appropriate flow rate. . Therefore, it is possible to maintain a good feeling of use without sparsely flowing out water.
Further, according to the water-saving device according to claim 4, in addition to the effect of the configuration according to any of claims 1 to 3, the posture of the flow rate adjusting ring can be stabilized by forming the shaft column. And a stable water-saving flow rate can be discharged.
Further, according to the water-saving device according to claim 5, in addition to the effect of the configuration according to any one of claims 1 to 4, a rectification path is continuously formed downstream of the flow rate adjustment unit. The water that has been saved and reduced can be discharged from the terminal in an easy-to-use state.
Further, according to the water-saving device according to claim 6, in addition to the effect of the configuration according to any one of claims 1 to 5, by making the flow rate adjustment ring interchangeable, the place where the water-saving device is used and the water-saving device Depending on the conditions, other conditions, and circumstances, the flow rate adjustment ring can be replaced with the most appropriate conditions and circumstances, and more appropriate water saving can be performed. It is also convenient for replacing a deteriorated flow adjustment ring.
Further, according to the water-saving device according to claim 7, in addition to the effect of the configuration according to any one of claims 1 to 6, the flow rate adjusting ring is replaced as a flow rate adjusting body composed of one independent unit. By making it freely attachable, it is possible to easily attach and replace the optimal flow rate adjusting body according to the place where the water-saving device is used, water-saving conditions, other conditions, and conditions.
Further, according to the water-saving device according to claim 8, in addition to the effect of the structure according to any one of claims 1 to 7, a water quality improvement effect by magnetic force is added to the water-saving device, and one device It is possible to provide a convenient instrument that can exhibit the two effects together.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view of a water-saving device according to a first embodiment of the present invention.
FIG. 2 is a longitudinal sectional view of the main body of the water-saving device.
FIG. 3 is a longitudinal sectional view of a flow rate adjusting unit of the water-saving device.
FIG. 4 is a plan view of a flow rate adjustment unit of the water-saving device.
FIG. 5 is a longitudinal sectional view showing a state in which the water-saving device is attached to a water pipe connection part such as a water supply.
FIG. 6 is a perspective view illustrating where the water-saving device is mounted.
FIG. 7 is a longitudinal sectional view of a water-saving device according to a second embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Instrument main body 11 Cylindrical part 12 Outer flange 13 Inlet 14 Fitting recess 15 Rectification path 16 Magnet material 17 Holding piece 20 Flow rate adjustment part 21 Short cylinder part 22 Flow rate adjustment path 23 Flow rate adjustment ring 24 Drop prevention lattice 25 Shaft 26 Receiving seat S Clearance H Ring hole

Claims (8)

A water-saving device that is arranged in a pipe in a water pipe or the like to save water so that an excessive flow rate is not discharged from a terminal such as a currant, and the other water pipe of the pair of water pipes constituting the water pipe connecting portion There is at least a locking portion for locking with respect to the insertion end portion of the water pipe inserted into the end portion, and a flow rate adjusting portion arranged in the insertion end portion of the water pipe by the locking by the locking portion. The flow rate adjusting section constitutes a flow rate adjusting flow path, and a flow rate adjusting ring is loosely fitted in the flow rate adjusting flow path. A water-saving device that is arranged in a pipe in a water pipe or the like to save water so that an excessive flow rate is not discharged from a terminal such as a currant, and the other water pipe of the pair of water pipes constituting the water pipe connecting portion There is at least a locking portion for locking with respect to the insertion end portion of the water pipe inserted into the end portion, and a flow rate adjusting portion arranged in the insertion end portion of the water pipe by the locking by the locking portion. The flow rate adjusting portion constitutes a flow rate adjusting flow path and loosely fits the flow rate adjusting ring in the flow rate adjusting flow path, and the flow rate adjusting ring moves in the flow rate adjusting flow path by water pressure. A water-saving device characterized in that the flow passage cross-sectional area is changed and adjusted. The flow rate adjustment part is formed with a seat for receiving the flow rate adjustment ring moved by the water pressure, and the flow rate adjustment ring abuts on the seat, thereby blocking the water flow passing outside the flow rate adjustment ring, The water-saving device according to claim 1 or 2, wherein only a water flow passing through a ring hole of the flow rate adjusting ring is discharged. The axial column for stabilizing the attitude | position of this flow volume adjustment ring in the direction orthogonal to a water flow direction by inserting the flow volume adjustment ring in the flow volume adjustment part is characterized by the above-mentioned. A water-saving device according to any one of the above. The water-saving metal fitting according to any one of claims 1 to 4, wherein a rectifying path that rectifies and collects the flow of running water that has flowed out of the flow rate adjusting unit is formed continuously downstream of the flow rate adjusting unit. . The water-saving metal fitting according to any one of claims 1 to 5, wherein the flow rate adjusting ring is loosely fitted to the flow rate adjusting unit in a freely replaceable manner. The water-saving metal fitting according to any one of claims 1 to 6, wherein the flow rate adjusting unit is composed of a flow rate adjusting body as one independent unit, and is attached to be exchangeable. The water-saving device according to any one of claims 1 to 7, wherein a magnet material that generates a strong magnetic force is applied to at least a part of the inner surface of the flow path that is in contact with running water.

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