RU222201U1 - Membrane for saving water when operating plumbing fixtures - Google Patents

Abstract

The utility model relates to plumbing devices and can be used to save water by creating a mixture of liquid and air at the outlet of hot and cold water inlets, as well as at the outlet of spouts or aerators of mixers, taps and other plumbing devices. The essence of the utility model is a membrane for plumbing fixtures containing a disk-shaped base, characterized in that the base is made of heat-resistant polymer and its thickness ranges from 0.1 to 0.3 mm. The technical result that the utility model is aimed at achieving is maintaining the deformation resistance of the membrane to save water at operating temperatures of plumbing fixtures ranging from 4 to 75°C. 1 salary f-ly, 3 ill.

Description

The utility model relates to plumbing devices and can be used to save water by creating a mixture of liquid and air at the outlet of hot and cold water inlets, as well as at the outlet of spouts or aerators of mixers, taps and other plumbing devices.

As a prototype, a membrane for plumbing fixtures was selected, containing a base in the form of a disk, in which through holes are made, in the plane of the disk having the shape of a polygon, while protrusions are made along the perimeter of the disk, while the membrane has a thickness of 0.4 mm and is presumably made of polymer material [RU 186723, publication date: 01/30/2019].

The disadvantage of the prototype is the increased material consumption of the membrane due to its thickness. However, eliminating the existing drawback by reducing the thickness of the membrane can lead to another drawback, which is the low deformation resistance of the membrane, since not all types of polymer materials from which it can be made have deformation resistance at low thickness and operating temperatures from 4 to 75 °C, corresponding to the permissible temperatures of hot and cold water in places of water intake, and therefore the polymer material may be subject to glass transition, leading to an increase in the hardness and fragility of the polymer, and as a result, failure of the membrane made from it when a load is applied to it, or it may be subject to softening, melting and various types of inelastic deformations, in which the operation of a membrane made from it may be difficult or impossible, which significantly impairs the performance characteristics of a membrane made from such material.

The technical problem that the utility model is aimed at solving is the need to improve the performance characteristics of the membrane to save water when operating plumbing fixtures.

The technical result that the utility model is aimed at achieving is maintaining the deformation resistance of the membrane to save water at operating temperatures of plumbing fixtures ranging from 4 to 75°C.

The essence of the utility model is as follows.

The membrane for saving water during the operation of plumbing fixtures contains a base in the form of a disk, in which through holes are made, in the plane of the disk having the shape of a polygon, while protrusions are made along the perimeter of the disk. Unlike the prototype, the base is made of heat-resistant polymer - polylith, and the thickness of the base ranges from 0.1 to 0.3 mm.

Plumbing devices in which a membrane can be installed include devices such as taps and mixers; in particular, the membrane can be installed inside the nuts of flexible hoses for supplying hot or cold water to the above-mentioned devices, as well as at the outlet of spouts or aerators.

The membrane for plumbing fixtures contains a base in the form of a disk, along the perimeter of which there are protrusions that allow the membrane to rest against the walls or threads of the seat when installing it. The protrusions in the plane of the disk can be in the shape of a polygon, in particular a triangle, square or trapezoid. The projections can be equidistant from each other. The number of protrusions may vary depending on their size and the minimum permissible distance between them, and may be at least six. The size of the protrusions and the distance between them can be such that the figures lying in the cross section of the protrusions do not intersect with each other, and when installing the membrane on its seat, the creation of areas for the passage of liquid is ensured, in the cross section limited by the ends of the protrusions and the inner surface seat for the membrane.

At the base of the membrane there are through holes that ensure the creation of turbulence zones behind the membrane (in the direction of the flow of liquid passing through it) and a reduction in liquid consumption by increasing the intensity of its mixing with air. In the plane of the disk, through holes can be of any size to ensure the passage of liquid. The total area of all through holes in the plane of the disk can be from 1 to 30% of the base area in the same plane, which is necessary to maintain an optimal level of hydraulic resistance in the water supply system, which ensures its stable operation. The minimum number of holes can be at least two, and their maximum number can be limited by the total area of all through holes in the plane of the disk and the size of each hole individually.

In the plane of the disk, the through holes have the shape of a polygon. A polygon lying in a through hole in the plane of the disk can be represented by a triangle, square, pentagon and other polygons.

The longitudinal axes of the through holes can be located on one circle, the center of which in the most preferred embodiment is located in the center of the disk-shaped base. The longitudinal axes of the through holes can be located at any distance from each other, and can also be equidistant from each other.

The thickness of the membrane base ranges from 0.1 to 0.3 mm. In this case, if the thickness of the membrane base goes beyond the established range, it will not lead to the achievement of a technical result in its entire volume, since making a membrane with a thickness of more than 0.3 mm will lead to an increase in its material consumption, while no increase in water saving will be observed, and making a membrane thicker less than 0.1 mm will lead to a decrease in its deformation resistance and may lead to its failure or lack of effect in saving water.

The base of the membrane is made of heat-resistant polymer, which ensures the preservation of its deformation resistance at temperatures corresponding to the permissible temperatures of hot and cold water in places of water intake.

In this case, deformation resistance refers to the ability of a product to resist deformation, as well as the ability to undergo elastic deformation when the product is exposed to loads that change its linear dimensions.

Polylit is presented as a heat-resistant polymer from which the base of the membrane is made, ensuring temperature stability of the geometric dimensions of the membrane at operating temperatures from -30 to 105°C, which increases the deformation resistance of the membrane.

A utility model can be made from known materials using known means, which indicates its compliance with the patentability criterion of “industrial applicability”.

A utility model is characterized by a previously unknown set of essential features from the prior art.

Thanks to this, the technical result is achieved, which consists in maintaining the deformation resistance of the membrane to save water at operating temperatures of plumbing fixtures ranging from 4 to 75 ° C, thereby improving its performance characteristics.

A utility model is characterized by a set of essential features previously unknown from the prior art, which indicates its compliance with the patentability criterion of “novelty”.

The utility model is illustrated by the following figures.

Fig. 1a-1c - a membrane for saving water when operating plumbing fixtures, in the disk-shaped base of which there are three holes, in the plane of the disk having the shape of a pentagon (a), square (b) or triangle (c), and protrusions are made along the perimeter of the disk, in the plane disks shaped like a trapezoid.

Fig. 1a-1c - a membrane for saving water when operating plumbing fixtures, in the disk-shaped base of which there are three holes, in the plane of the disk having the shape of a pentagon (a), square (b) or triangle (c), and protrusions are made along the perimeter of the disk, in the plane disks shaped like a triangle.

Fig. 3 - geometric parameters of the membrane, determined during testing, demonstrating the achievement of a technical result by the utility model.

To illustrate the possibility of implementation and a more complete understanding of the essence of the utility model, a variant of its implementation is presented below, which can be changed or supplemented in any way, while this utility model is in no way limited to the presented variant.

The membrane for saving water when operating plumbing fixtures contains a disc-shaped base made of polylit, polypropylene or polyvinyl chloride with a thickness of 0.1 to 0.3 mm. The base has from three (Fig. 1a, Fig. 2a) to four (Fig. 1b-c, Fig. 2b-c) holes, in the plane of the disk having the shape of a triangle (Fig. 1c, Fig. 2c), a square (Fig. 1b, Fig. 2b) or a pentagon (Fig. 1a, Fig. 2a). Along the perimeter of the disk there are protrusions, in the plane of the disk having the shape of a trapezoid (Fig. 1a-c) or a triangle (Fig. 2a-c).

The utility model works as follows.

Before connecting a flexible hose to the mixer for supplying hot or cold water, install a membrane inside the hose nut, then install a rubber gasket and connect the flexible hose to the mixer. Or the membrane is installed in the mixer aerator near the outlet. A membrane installed by any of the above methods acts as a diaphragm and ensures the formation behind it (in the direction of liquid flow) of turbulence zones in which liquid and air are mixed, which allows reducing liquid flow without changing the volume of the jet.

When a fluid flow under pressure passes through the membrane, it is subjected to mechanical deformations, in particular bending in the direction of flow, as well as thermal deformations when a liquid with a temperature of 60-75 ° C passes through it if the membrane is installed in the nut of a hose for supplying hot water, or a temperature of 4-20°C in the case of installing a membrane in the nut of a hose for supplying cold water, or a temperature of 20-40°C in the case of installing a membrane in a mixer spout; in particular, the membrane experiences thermal expansion and contraction. Making the membrane from polylith, polypropylene or polyvinyl chloride provides the possibility of its elastic deformation, in which it, regardless of the temperatures of its operation and the force of the flow acting on it, has the ability to restore its shape from a bent-deformed state to its original state without a significant change in its thickness and dimensions.

To demonstrate the achievement of a technical result by the utility model, a series of 6 tests were carried out for various versions of the membrane and various options for its installation and operation.

For testing, membranes made of polylit, polypropylene and polyvinyl chloride were used, in two thicknesses of 0.1 and 0.30 mm. A total of 6 sets of 3 membranes each were made from polylit with a thickness of 0.1 mm (set 1), from polylit with a thickness of 0.30 mm (set 2), from polypropylene with a thickness of 0.1 mm (set 3), from polypropylene with a thickness of 0 .30 mm (set 4), from polyvinyl chloride with a thickness of 0.1 mm (set 5) and from polyvinyl chloride with a thickness of 0.30 mm (set 6). The membranes for each set were installed in the mixer in accordance with the installation options described above (in the nuts of flexible hoses for supplying hot and cold water and in the aerator).

The tests consisted of operating the installed membranes while the mixer was operating and opening both of its valves to obtain liquid at the outlet of the aerator with a temperature of 20-40 ° C, and passing through the membranes installed in the nuts of flexible hoses for supplying hot and cold water, liquid with a temperature of 60- 75°C and 4-20°C respectively. The membrane was operated for five cycles lasting 40 minutes, with breaks between cycles of 10 minutes, after which the operation was completed.

Before and after operation of the membranes, their geometric parameters, shown in Fig., were determined using a micrometer with a measurement step of 0.001 mm. 3, where:

D ₀ - diameter of the membrane before its operation (mm);

D is the diameter of the membrane at the end of its operation (mm);

s ₀ - thickness of the membrane before its operation (mm);

s is the thickness of the membrane at the end of its operation (mm);

δ is the deviation of the center of the membrane from its original position due to its bending (mm).

Based on the measurement results, the deviation of the geometric parameters of the membrane at the end of its operation from its parameters before the start of its operation was determined, in particular, AD was determined - the deviation of the membrane diameter (%) and As - the deviation of the membrane thickness (%). The obtained measurement results, as well as the results of determining deviations for membranes for each of the sets, were entered in Table. 1-6 experimental results for membranes from sets 1-6.

Based on the test results of membranes for sets 1-6, it is clear that the best results among all sets were achieved by all membranes in sets 1 and 2, made of polylit with a thickness of 0.1 and 0.30 mm, as well as membranes in set 4, made of polypropylene with a thickness of 0.30 mm, in particular, the geometric parameters of the membranes for sets 1, 2 and 4 at the end of their operation remained unchanged, regardless of the location of their installation and the temperature of the liquids passing through them.

In this case, the membranes of set 3, made of polypropylene with a thickness of 0.1 mm, as well as the membranes of sets 5 and 6, made of polyvinyl chloride with a thickness of 0.1 and 0.30 mm, and installed in the nut of a flexible hot water supply hose, upon completion of their operation had different geometric parameters from the initial ones, however, the deviation of the final parameters from the initial ones was insignificant (ΔD = 0.09-0.11%, Δs = 1-3%, δ = 0.004-0.008 mm), and the membranes for these sets, installed in the nut of a flexible cold water supply hose or an aerator, at the end of operation had geometric parameters corresponding to the initial ones, which indicates that their operation is possible at temperatures of 4-40 ° C with full preservation of their geometric parameters in accordance with the original ones, as well as with their partial preservation during operation at temperatures of 40-75°C.

This ensures the achievement of a technical result, which consists in maintaining the deformation resistance of the membrane to save water at operating temperatures of plumbing fixtures ranging from 4 to 75°C, thereby improving its performance characteristics.

Claims (2)

1. A membrane for saving water during the operation of plumbing fixtures, containing a base in the form of a disk, in which through holes are made, in the plane of the disk having the shape of a polygon, with protrusions along the perimeter of the disk, characterized in that the base is made of a heat-resistant polymer - polylith, and the thickness of the base is from 0.1 to 0.3 mm. 2. Membrane according to claim 1, characterized in that the total area of all through holes in the plane of the disk can be from 1 to 30% of the area of the base in the same plane.