KR200392186Y1 - Water Flow Regulating Device - Google Patents

Abstract

The present invention is directed to a water flow-regulating device that can be used to conserve liquid through hydraulic control and can be used at high, medium and low water pressures. The regulating device of the present invention is designed to adapt to any tubular watertight or inlet in a sprinkler, a ventilator or injector for a sink, a washbasin or a system requiring water saving. According to the present invention, the device is essentially cylindrical in shape and includes a cylindrical channel that allows the flow of water. The top of the device includes one or more openings that form the inlet channel. The device also includes a spring used to shut off the liquid entering the upper opening to facilitate the introduction of the liquid at low water pressure, along with the pressure exerted by the water.

Description

Water Flow Regulating Device

In general, the present invention is directed to an adjustment to water flow that functions automatically and saves a significant amount of water by hydraulic adjustment. In particular, the present invention relates to a device that can be fitted to sinks, sinks, sprinkler outflows, as well as certain systems that want to precisely regulate water flow. The device can function under low and medium pressures, providing a maximum water flow of 9 liters per minute.

The ever-increasing demand for water in residential areas, especially in urban areas, is forced to use methods and devices that save such resources. A way to conserve water is to regulate its flow through the outflow of sinks, sinks, sprinklers, and other systems.

Currently, there are some devices that can be matched to sinks, sinks, sprinklers, and other system outflows, which control this by blocking the water flow. In other words, the flow controller is manufactured by US companies such as Neoperl, Ondin and Teleedyne. These flow controllers are very small (about 19 mm diameter and 6 mm high). The controller consists of a plastic protective cover, a central nucleus with an asymmetric drill hole, and a rubber ring approximately 7 mm diameter and 3 mm thick. The rubber ring expands as the hydraulic pressure increases and begins to close the central core drill. In that way, the water flow gradually decreases while the pressure increases more. One problem with this kind of flow controllers is that their parts are brittle and made mainly of ABS plastic, enabling microbial propagation. Another disadvantage is that the controller is fixed in all sprinkler tubular round adapters via rubber gaskets. This allows all sprinkler users to remove the regulator, which increases water consumption. In addition, the expansion of the plastic ring due to pressure presents several problems: First, the rubber ring can rupture or wear out due to frequent use of the sprinkler and water temperature. The ring can be affected by salts contained in water such as bicarbonate, calcium and magnesium carbonates, which harden the ring and make it brittle. Thus, the ring can no longer be inflated hydraulically. This effect is greater when the water is exercise hard water. In addition, certain debris or small stones can clog the ring. That kind of obstruction interferes with the proper functioning of the ring, resulting in high water consumption.

Then, there is actually a need for a water flow control device that can also be used for superhard water and is not consumed with use and does not require any maintenance. It is also desirable that the regulating device be easily installed, safe and reliable. At the same time, it is important that the device cannot be removed by the user. Moreover, it is proposed that the device be made of a resistant and durable material that prevents the formation of microorganisms.

The present invention aims to:

1) To provide automatic flow control that can be well adapted to spills from sprinklers, sinks, sinks, and all systems requiring precise control of the flow.

2) Provide water flow control devices that do not require testing during installation to various building levels to determine different water flows in the sprinkler, wash basin, and sink.

3) To provide a water flow control device that can function at low, medium and high water pressure.

4) to provide a water flow control device capable of functioning under a pressure range of 0.2 kg / cm ² to 5 kg / cm ² , providing a maximum water flow of 9 liters per minute.

5) To provide a water flow control device that can not be removed by the user and easy to install.

6) To provide a water flow control device that can be installed throughout the world.

7) To provide a water flow control device that can save water and energy.

8) To provide maintenance free water flow control device.

9) To provide a device for controlling the flow of water to prevent the growth of microorganisms in the humid conditions of the pipe.

10) Even if the water is super hard water, to provide a water flow control device that does not break in water salt.

11) It is to provide a device for controlling the flow of the mechanism which is not affected by the cracks or small stones contained in the water.

In a preferred embodiment, this water flow regulating device has five parts assembled to each other. These parts are shown in FIG. 1 and are now described in detail.

The part 1 of the present invention, then the tube body, is formed predominantly of hollowed cylindrical fittings, which have an inner diameter of approximately 8 mm and a length of 15.7 mm. The tube body 1 comprises a perimetrical belt 5 after the upper edge, which has a threaded exterior. The outside has a 19.8 mm screw with a threaded pitch of 14 screws per inch. The outer circumferential belt 5 has two drill holes 9 formed through the thickness thereof in the opposite directions, approximately 3 mm in diameter. As will be described below, the drill hole 9 is a support for facilitating fitting of the accessory in a thread located in the sink and sink ventilator, or in a tubular circular adapter or a removable coupling of the sprinkler and turbo injector. The fit prevents the device of the present invention from being removed by the user, thus preventing more water and energy consumption.

The component 2, then the cylindrical channel of the device of the present invention, is a cylindrical structure comprising a head 10 thereon. As shown in FIG. 2, corresponding to the vertical portion of this accessory, the cylindrical channel 2 has an inner diameter of approximately 5.94 mm and a height of approximately 18.4 mm.

The head 10 of the cylindrical channel 2 has an upper circular plane with a diameter of approximately 7.13 mm. The height of the head is approximately 5.15 mm. The head 10 preferably has two holes 3 in opposite directions. The holes 3 are about the same, they are circular and have a diameter of approximately 2.79 mm. As described below, these holes 3 are usually first inlets of high pressure water in the range of 3 to 6 kg / cm ² .

At the bottom of the head 10, the cylindrical channel 2 presents three circular identical holes 4 in the selected mode. These holes 4 have a diameter of approximately 4.09 mm. The holes are set at the same height and equidistant from each other. The holes 4 are usually second inlets of water of medium pressure in the range of 0.2 to 1 kg / cm ² , as for medium pressure in the range of 1 to 3 kg / cm ² .

As shown in Fig. 2, the cylindrical channel 2 also includes a peripheral circular slot 12 located after the lower edge. Under the slot 12, the cylindrical channel 2 presents a narrower portion when compared to the rest of the fitting, which is a spring seat 18. The functions of parts 12 and 18 are described in more detail later.

As evident from the above description, the cylindrical channel 2 can slip in the tube body 1, where the head 11 of the cylindrical channel 2 determines the amount of leakage of the cylindrical channel 2. It is the limit line.

As shown in FIG. 3, the movement between the accessories 1 and 2 is caused by the hydraulic pressure applied on the upper surface 11 of the cylindrical channel 2 and the spring 7 located in the lower part of the cylindrical channel 2. Is automatically determined by the pressure applied in the opposite direction.

In order to fix the cylindrical channel 2 inside the tube body 1 and to prevent the channel from being released by the operation of the spring 7, the tube body 1 has a retention ring inside thereof. 6). This ring is forcibly fitted through the upper end into the peripheral slot 12 of the component 2. The retention ring 6 is made of stainless steel, although other resistive materials, preferably metallic materials, may be used at the time of manufacture.

The spring 7 is forcibly fitted through the lower end, above the washer top 8. The washer 8 is a circular fitting formed by three concentric ring-shaped sections 13, 14 and 15, with the central part 13 fitted with the ring. The ring portion 14 is between the central portion 13 and the peripheral portion 15. The ring portions 14 and 15 are supports for forcing the washers 8 into the tube body 1. It is well known that the outer diameter of the periphery 15 of the washer is the same as the outer diameter of the tube body 1.

Preferably, parts 1, 2 and 8 are made of self-lubricating homopolymeri resin from acetals, although other homopolymers or hybrid polymers may be used. In particular, the resin prevents the coating of salts even when the water is ultra hard water, and also prevents the formation of microorganisms usually generated from moisture in the pipe. As explained, these devices do not require maintenance. In addition, these materials do not lose form due to heat and have little moisture absorption.

Apart from the materials already mentioned, other polymers such as teflon, polycarbonate, PVC, polyethylene or polyurethane can be used; Likewise, metallic materials such as brass, copper or stainless steel, or combinations thereof may also be used.

Reference is made to FIGS. 1 and 3 to assemble five parts of the inventive device together. The cylindrical channel 2 is fitted into the tube body 1 until the head 10 contacts the upper edge of the tube body 1. The retention ring 6 is then forced into the peripheral slot 12. Thereafter, the spring 7 enters into the cylindrical channel 2 seat 18, and finally the washer top 8 is forcibly fitted to the spring 7 and the tube body 1.

In the arrangement described previously, based on FIG. 3, it is shown that the head 10 and the upper hole 3 and the lower hole 4 located below the cylindrical channel 2 are on top of the tube body 1. Shown. The holes 3 and 4 are the first and second two inlets, respectively. As water approaches the interior of the cylindrical channel 2, water flows through the channel and is discharged through the washer tower 8 holes.

As mentioned from the beginning of the description, such a water flow control device can be used with a water saving turbo injector sprinkler, as in Mexican Patent No. 201176, or other sprinkler, wash basin, sink, or water flow can be adjusted. It can be adapted to any other system. The fitting of the device of the present invention into a sprinkler movable coupling or tubular circular adapter is now described.

The adjusting device of the present invention is fixed to the movable coupling 16 in the axial direction (see FIG. 5). The movable coupling 16 includes an internal threaded pipe, as shown in FIG. The threaded portion 5 of the tube body 1 of the device is fitted into the inner thread of the movable coupling 16 by threading clockwise. The spherical or movable coupling 16 comprises an intermediate inner sheet 17 on which the device of the present invention rests.

When the device is adapted to a sink or sink, a procedure similar to that mentioned above is performed. In that case, the threaded portion 5 of the tube body 1 is fitted in the internal thread of the sink or sink ventilator to block outflow.

When the regulator of the present invention is fitted, it automatically compensates for fluctuations in water pressure, providing a maximum water flow of 9 liters per minute.

The device of the present invention functions in three ways or under conditions determined by the resistive force exerted by the spring 7 under different water pressures. These three modes of operation are described in detail based on Figs. 4A and 4C.

In the first condition, then the upper stop condition (see FIG. 4A), the water flows at a low pressure in the range of 0.2 to 1 kg / cm ² . In this case, the upper hole 3 and the lower hole 4 are completely free and are two inlets to the cylindrical channel 2. The inlet through which water flows is clearly one of the lower holes 4. Under the second condition, then dynamic conditions (see FIG. 4B), water flows at a medium pressure in the range of 1 to 3 kg / cm ² . In this state, the pressure exerted by the water is applied against the pressure exerted by the ring 7 to displace the cylindrical channel 2 downward. The water flow then decreases towards the cylindrical channel 2 because of the partial closure of the lower hole 4. Finally, in the third condition and then in the lower stop condition (see FIG. 4C), the water flows at a high pressure in the range of 3 to 6 kg / cm ² . The flow of water is further reduced because the pressure exerted by the water closes the lower hole 4 almost completely and entirely. The upper hole 3 is thus a free inlet for water towards the cylindrical channel 2.

Under these three conditions, the fluctuations in water pressure are compensated by the final flow of water, enabling a continuous dynamic process that guarantees the installation of this technology throughout the world.

The shape, size and / or quantity of the components of the water flow regulating device can be modified to deviate from the scope of the present invention. For example, the holes 3 and 4 can be square, oval, or other geometric shape that can be adapted to the design of the device. The size of the hole can also be modified; Nevertheless, it can be seen that the shapes and dimensions described herein provide an effective and reliable mechanism, which can allow for minimal use of the material to lower manufacturing costs. Moreover, although the number of holes in the selected mode is very effective, the number of holes 3 and 4 can be increased or decreased.

According to the above description, it is evident that the water flow control device of the present invention allows the compensation of pressure fluctuations in the water supply pipes in homes, buildings, hospitals, hotels and factories around the world, allowing them to function automatically. Such devices can avoid field testing to determine the water flow of sprinklers, sinks and sinks. Another advantage of the present invention is that there is no need to test pressure at various building levels, which can reduce such service costs. Another advantage of the present invention is that it can reduce water consumption and cost, and thus the gas required to heat the water. Thus, the device of the present invention reduces the emission of pollutants harmful to the atmosphere. Moreover, by reducing the water outlet pressure, such a device also reduces the electricity consumption in kilowatts per hour, due to internal pumping.

Although the present invention has been shown and described in accordance with the selected mode, those skilled in the art will appreciate that the mode can be changed. Also, some equivalent elements may be substituted for those described above, depending on the purpose and scope of the present invention, as described in the following claims.

1 is an enlarged view of all the components of the water flow control device of the present invention in the selected mode.

Figure 2 is a vertical sectional view of the cylindrical tube of the water flow control device of the present invention in the selected mode.

3 is a vertical sectional view of the assembled water flow control device of the present invention in the selected mode;

Figure 4a is a perspective view of the flow regulator of the present invention, adapted to low water pressure.

Figure 4b is a perspective view of the flow regulator of the present invention, adapted to heavy water pressure.

Figure 4c is a perspective view of the flow regulator of the present invention, adapted to high water pressure.

Fig. 5 shows the fitting of the water flow control device of the present invention with a removable coupling of sprinkler or a tubular circular adapter.

Fig. 6 is a vertical sectional view of the water flow regulating device assembled in the movable coupling of the sprinkler.

Claims (34)

A water flow regulating device comprising a tube body that slides into a water flow regulating device, and a hollow cylindrical piece having a diameter narrower than the diameter of the tube body, The hollow cylindrical part piece allows water to flow inside for at least one inlet use, and sliding movement of the cylindrical part piece inside the tube body results in a hydraulic pressure applied to the system, and within the sheet of the cylindrical piece piece. Determined by the pressure exerted by the spring on which it is located, The water flow control device The cylindrical piece has a spring seat at the bottom thereof, is supported by the spring and fixed to the tube body; When the cylindrical piece piece slides down the tube body, the head of the cylindrical piece piece forms a limit line for movement between both piece pieces, and when the head contacts the upper edge of the tube body, the device Is operated under three conditions, wherein the first operating condition occurs when water flows at low pressure, and in the first condition, the first and second inlets of water freely flow through them toward the cylindrical piece; The second form of operation occurs when water flows at an intermediate pressure, where the water pressure displaces the cylindrical piece piece downward against the pressure exerted by the spring and places it at a height that partially blocks the second inlet channel, The partial blocking of the second inlet channel comprises a partial reduction of the water flow towards the piece of cylindrical part; A third mode of operation occurs when water is introduced at high pressure to displace the cylindrical piece piece downwards and place it at a height that entirely blocks the second inlet channel; When the second inlet is totally blocked, the first inlet located on the head of the cylindrical piece is the only inlet that causes water to enter the cylindrical piece. Water flow control device, characterized in that. 2. The water flow control device according to claim 1, wherein both the tube body and the spring are forcibly fitted on a circular top. The device of claim 1, wherein the spring is metal and conical. 2. The tube body of claim 1 wherein the tube body presents a peripheral belt thereon, the peripheral belt including an outer thread and one or more drill holes through the thickness, which drill holes the sprinkler, turbo injector, Water flow control device, characterized in that the support (support) to easily fit the outflow of the sink or sink. 5. The water flow regulating device according to claim 4, wherein the number of drill holes in the screw portion is two opposite in the radial direction. 2. The cylindrical piece of machine part according to claim 1, wherein the cylindrical part piece comprises a head on top of which is slightly wider in diameter than the rest of the cylindrical part piece; And the head comprises a circular flat top surface, the vertical surface of which includes one or more holes, wherein the holes of the head are the first inlets of water towards the inside of the cylindrical piece of material. 7. The water flow control apparatus according to claim 6, wherein the holes of the head have the same circular shape. 8. The water flow control device according to claim 7, wherein the head includes two holes facing in the radial direction. 8. The device of claim 7, wherein the head comprises three equidistant holes. 8. The device of claim 7, wherein the head comprises four equidistant holes. 7. A water flow control as claimed in claim 6 wherein there is one or more holes below the cylindrical piece piece head which are second inlets into the cylindrical piece piece, the inlet holes causing water to flow at low or medium pressure. Device. 12. The device of claim 11, wherein the second inlet holes are circular, identical, at the same height, and equidistant from each other. 13. The apparatus of claim 12 wherein the diameter of the second inlet holes is slightly wider than that of the first inlet holes. 14. The device of claim 13 wherein the second inlet comprises two, three or four holes. The retaining ring of claim 1, wherein the hollow piece of cylindrical part includes a peripheral circular slot located proximate its lower edge, the cylindrical piece of piece retaining pressure under pressure with the slot around the cylindrical part piece. A water flow control device, characterized in that secured to the tube body by a retention ring. 16. The water flow control device according to claim 15, wherein the retention ring is made of a metallic material, more preferably stainless steel. 3. The water flow control device according to claim 2, wherein the circular tower is made of three concentric portions of different diameters. 18. The method of claim 17, wherein the concentric portion of the circular tower is a mating region between the spring and the circular tower, and the two remaining concentric portions of the circular tower allow the circular tower to be adjusted under pressure into the tube body. Water flow regulating device. 3. The water flow regulator of claim 2, wherein the tube body, the cylindrical part piece and the circular tower are made of homopolymer or interpolymer material. 20. The device of claim 19, wherein the homopolymer or interpolymer material is an auto-lubricating material. 21. The apparatus of claim 20, wherein the auto-lubricating homopolymer material is a material derived from acetal resin. 3. The water flow of claim 2 wherein the tube body, the cylindrical piece of piece and the circular tower are made of Teflon, polycarbonate, PVC, polyethylene, polyurethane, brass, copper, stainless steel, or a combination thereof. Regulator. 2. The water flow control device of claim 1, wherein the water flow control device works in conjunction with a water saving turbo injector sprinkler. The system of claim 1, wherein the water flow control device is adapted to a system in which the water flow can be regulated; And the system relies on a sink, sink, sprinkler and turbo injector. The water supply system of claim 1, wherein the system in which the flow of water can be regulated includes a feed pipe threaded therein; And the inner screw fits the thread of the tube body of the device to block water flow. 26. The sprinkler according to claim 25, wherein the water flow regulating device is threaded in a clockwise movement through an internal screw located in a movable coupling or tubular circular adapter of the sprinkler or turbo injector to control the flow in axial form. Water flow control device, characterized in that fixed to the turbo injector. 27. A water flow regulating device according to claim 26, wherein the circular adapter or movable coupling comprises an intermediate inner sheet on which the device rests so as to be fully fixed. 28. The water flow control according to claim 27, wherein the water flow adjusting device is fixed to a sink or a sink where the water flow needs to be controlled in an axial form by making a thread in a clockwise movement through an internal screw located in the adapter. Regulator. 2. The apparatus of claim 1, wherein when the device is secured to the system where water flow needs to be controlled, the device may be configured in three forms determined by the resistance applied by the spring at different water pressures to automatically control the water flow. Water flow control device, characterized in that operating under the conditions. The water flow regulating device according to claim 1, wherein the water pressure is regarded as low pressure when the range is 0.2 to 1 kg / cm ² . The water flow regulating device according to claim 1, wherein the intermediate pressure is in the range of 1 to 3 kg / cm ² . The device of claim 1, wherein the water pressure is considered high pressure when in the range of 3 to 6 kg / cm ² . 3. The water flow control device according to claim 2, wherein the material constituting the tube body, the cylindrical component piece, and the circular tower prevents salt coating even when hard water is used. 3. The device of claim 2, wherein the material constituting the tube body, the cylindrical component piece, and the circular tower prevents microbial propagation.