EA012657B1 - Method for water removal from supply pipe of pillar fountain - Google Patents

Abstract

The invention relates to methods of water removal from a supply pipe of pillar fountain for dispensing drinking water. The aim of the invention is to find a method of how to full removal of water immediately after water intake is stopped (cutout from water supply network) from the supply pipe of pillar fountain. The method of water removal from a supply pipe of pillar fountain is characterized in that a dynamic element is installed into internal volume of the supply pipe, wherein the required passing section for water supply is formed by changing the diameter or volume of the dynamic element and when the water flow is disconnected residual water is removed from the pipe in the direction of its supply reducing the passing section. The diameter or volume of the dynamic element can be changed using properties of the element made of elastic resilient material by compressing or stretching across the pipe by water discharge flow and returning to the initial state due to the element elastic deformation. The diameter or volume of the dynamic element can be changed using non-freezing liquid or gas, the non-freezing liquid or gas are introduced when the flow is disconnected and removed starting the flow. The present embodiment can be used both independently or in a combination using the element elastic deformation properties, e.g. when the element elastic deformation properties are not enough for water full removal. In all above cases for better result and making water removal easier the pipe is filled from the side opposite to the discharge.

Description

The invention relates to methods for removing water from the feed stand of a standpipe for dispensing tap water.

A serious problem of operation is the failure of water standpipes in the winter. The main reason is the freezing of residual water in the supply pipe of the standpipe, standpipe, or in the underground part of the standpipe or hull, when it reaches the border of the frozen ground or close to it. For reasons of accumulation more than the permissible amount of residual water, i.e. inadequate removal during the process or after dismantling includes both the drawbacks of the disposal methods used and “misuse”. There are three main ways of removing water: gravity by gravity, by creating a piston stroke in piston columns and using the energy of the flow supplied to the spout (ejection).

There is a method of removing water from the standpipe of a standpipe, which is used during the operation of a standpipe for installation on water mains for household use of water disassembled by the Voronezh factory "Watermashoborudovanie" or under the patent of the Russian Federation No. 2078178, published 04/27/1997. The residual (return) water from the supply pipe is pre-poured into the receiving tank located below the ground freezing level, and its removal occurs by ejection of a stream of water supplied to the spout. In existing column constructions, an ejector is a means of eliminating the problem that occurs when water at the end of the dismantling process remains in the pipe and riser and fills the entire internal space of the riser, which causes this remaining water to freeze, and the ice impedes subsequent shunting. Using an ejector allows you to drain only part of the water from the pipe and the riser. If the column does not meet the requirements for operation, not all the water from the pipe is ejected into the stream, which leads to a gradual increase in the water level in the pipe and in the riser in the passive mode. Installing such a column in an open well (improving maintenance conditions) ensures that cold air enters the lower part of the column, which leads to freezing of even the smallest portion of water remaining in the riser, which also prevents subsequent collection. Insufficient residual water suction from the supply pipe can occur due to, for example, instability (insufficiency) of pressure in the supply network and due to "incorrect" water intake, carried out in small gaps or using a watering hose. The result is a gradual filling of the column housing with water remaining from previous selections.

The principle of delayed discharge of residual water leads to the supply of dirty water to the user, a noticeable increase in the flow rate of flushing and waterlogging of the space around the column.

The applicant is also known columns, built on the principle of forced pumping of water using pumping equipment, the disadvantage of this method is the requirement of the presence of energy supply.

The applicant has known methods for removing water from the supply pipe by gravity through an exhaust valve arranged in an underground part, for example, implemented by the design of the Victoria water column (LUC, France). The disadvantage of this method is the need for a special drainage device for the removal of water, as well as the impossibility of using it in the case of high groundwater levels.

A known method of removing water by gravity by collecting in a special drainage tank with the subsequent removal of water from it.

A known method of removing water pressure created by the stroke of the piston (AS No. 125519 "Water Piston Column", published in the "Bulletin of inventions" No. 1 for 1960). The disadvantage of this method of removing water is the technological complexity of the implementation, as well as the impossibility of completely removing residual water (part of the water is drained into a collection tank located in the underground part, and is removed with subsequent withdrawal), which can freeze, for example, if such a column is installed in open wells .

Water columns are known in which, in order to prevent water from freezing in winter conditions, a chamber filled with water is used as a sensor, the elastic bottom of which interacts with the spindle and the running nut, allowing to create a discharged pressure in the chamber (RF Patent No. 2230859, publ. 20.06.2004 ). This device, based on the principles of increasing the volume of water freezing and thermal conductivity of materials, is inert in working condition and does not provide reliable water analysis.

In order to fundamentally exclude the possibility of freezing, it is necessary to ensure the removal of residual water from the standpipe of the column immediately after the extraction. None of the solutions known to the applicant solves the task.

The task is to find a way to completely remove water immediately after the end of the water intake (disconnection from the water supply network) from the standpipe column.

The technical result is to improve the removal of residual water while ensuring the conditions for its removal immediately after disconnecting from the water supply network.

The problem is solved in the method of removing water from the supply pipe of the water column, I conclude

- 1 012657 that the dynamic element is placed into the internal volume of the pipe, while forming the necessary flow area for supplying water through the pipe by changing the diameter or volume of the dynamic element, and when the flow is disconnected to the spout, the residual water from the pipe is removed in the direction of its supply , reducing the flow area.

It is possible to change the diameter or volume using the properties of the elastic deformation of an element of an elastic elastic material, by compressing or stretching across the pipe with a stream of water supplied to the spout, and returning to the initial state due to the elastic deformation of the element.

A variant of the element can be an elastic sleeve, while the flow area is formed inside the sleeve.

An embodiment of the element can be an elastic rod, while the flow area is formed between the outer wall of the rod and the inner wall of the pipe.

Possible options for elastic elastic material of the element: sponge rubber or hermetic chamber filled with gas.

It is possible to change the diameter or volume using an antifreeze liquid or a gas, while introducing an antifreeze liquid or a gas when the flow is turned off and free of an antifreeze liquid or gas when the flow is turned on.

This option can be used both independently and in conjunction with the use of the properties of the elastic deformation of the element, for example, in the case when the elastic properties of the material of the element are not enough to completely displace the water.

Thus, there is an option when the volume or diameter is regulated (changed) only by introducing a gas or an antifreeze liquid, and an option when a gas or liquid is used as an auxiliary element to “press” the residual water, while the main mass is displaced by the elastic deformation of the element .

It is possible to introduce an antifreeze liquid or gas into the space formed by the inner wall of the pipe and the wall of the element, while forming a dynamic flow area between the walls of the sleeve and the inner walls of the pipe.

As an element it is possible to use an elastic sleeve. Or make the element of waterproof thin-walled material, such as cloth. The sleeve can be corrugated, then you can use a non-elastic material.

It is possible to introduce an antifreeze liquid or gas into the existing internal axial cavity of an elastic rod, thus forming a dynamic passage section between the external walls of the rod and the internal walls of the pipe. The best option for supplying gas or antifreeze is to supply it (her) through a rigid tube located in the axial cavity of the element, while it is necessary to ensure that there is no gap between the walls of the tube and the walls of the cavity when the flow is turned off. Place the tube in the element, pre-heating it, while the absence of a gap must be maintained, at least in the range of the temperature of the water supplied (from 4 to 30 ° C).

In order to achieve the best effect and facilitate the removal of water in all the above cases, the filling starts from the side opposite to the drain.

Signs to the applicant are unknown.

The dynamic element is placed in the internal volume of the pipe, while forming the required flow area for supplying water through the pipe by changing the diameter or volume of the dynamic element, and when the flow is disconnected from the pipe, the residual water from the pipe is removed in the direction of flow, reducing the flow area.

An element from an elastic elastic material is used, while changing its diameter or volume is carried out by compressing or stretching across the pipe with a stream of water supplied to the spout, and returning to the initial state due to the elastic deformation of the element.

To change the diameter or volume of the element, an antifreeze liquid or gas is used, an antifreeze liquid or gas is injected when the flow is turned off, and an antifreeze liquid or gas is released when the flow is turned on.

The task is solved, while unlike existing solutions, where water remains in the system or is removed from it through additional openings or using an additional energy source (besides human muscular strength to open the valve), the proposed solution is aimed at using only available resources (existing spout, human muscular strength, pressure force of water in the network).

Obviously, the water itself is not able to overcome the force of gravity and rise above the level of the spout, therefore, in the proposed method, an additional element is introduced (an inexpensive device), which, at the end of the discharge, occupies the entire volume of the pipe.

The claimed invention resolves the following contradiction: the flow area in the pipe must be in order to carry out the flow of water, at the same time there must be no flow area so that water does not remain in the pipe.

When the valve is closed, the pipe independently removes water due to the property of the walls (pipe or element), reducing the flow area, i.e. section disappears.

- 2 012657

When the valve is open, the water itself creates a cavity in the pipe due to the pressure.

Over-effect is a decrease in the volume of residual water removed; improvement of hygienic properties; water saving; extends the temperature range of application.

The exclusion of special devices for the removal of water, such as an ejector, allows, for example, to reduce the diameter of the column riser in order to minimize the amount of water to be removed.

Residual water is removed immediately after the valve is closed in the consumer's tank (bucket), i.e. water does not stagnate, it does not need to be drained before water extraction.

Using the proposed method allows to solve the problem of residual water removal immediately after the end of the water intake, thereby preventing its freezing.

The proposed method can be implemented using the example of a water column system shown in FIG. 1 and 2.

FIG. 1 is an enlarged diagram of the part of the water column (supply pipe), made using an elastic element in the form of an elastic sleeve.

FIG. 2 - the conditional scheme of the water column with the supply pressure conduit.

Water column contains (Fig. 1) feed pipe water column 1, placed in the internal volume of the pipe dynamic element 2 and connected to the supply 3 (Fig. 2) conduit and control system 4 water analysis. The control system 4 for the disassembly of water can be made in the form of a pressure valve 5 connected, for example, to a supply conduit 3, and a power device 6.

Power 6 device can be made in the form of a mechanical, electric, pneumatic or hydraulic actuator 7, which is connected to the control element 8 (shown in the drawing as a pressure lever) and pressure valve 5.

FIG. 1 shows a variant of the dynamic element 2, which is an elastic tubular element mounted in the supply pipe 1 with a gap 11. The water supply cavity 9 is hydraulically connected via a pressure valve 5 (FIG. 2), for example, to a pressure supply conduit 3 with a water mains .

The cavity 9 for supplying water is made with the possibility of increasing or decreasing its volume depending on the volume of water supplied from the supply conduit 3. Inside the elastic pipe 2 can be installed rigid pipe 10 with a gap or without between them.

The elastic tubular element can be made, for example, from silicone rubber. The tests have shown that this elastic material, in addition to its elastic properties, has hydrophobic properties, which additionally contribute to the removal of residual water from the cavity.

For the manufacture of rigid pipe 10 and the supply pipe 1 can be used any material whose stiffness value is sufficient for the formation of the tubular element. The use of metal pipes is less preferable, since the high thermal conductivity of metals can contribute to the freezing of water in the supply pressure 2 conduit. When testing as a material with the specified characteristics used polyethylene. If necessary, in addition to the manufacture of the housing (not shown in the figures), a layer of insulation may be applied to it.

The water column works as follows. The operation of the water column is described on the example of the execution of the power device 6 in the form of a pneumatic drive 7.

When you press the push lever 12 moves down the piston of the pump 13, the working cavity of which is connected to the pneumatic drive 7 of the power device 6. The displaced working medium (air) from the piston pump 13 enters the rod cavity of the pneumatic drive 7 and moves the piston 14. By displacement of the specified piston 14 The pressure valve 5 opens and water from the pressure feed channel 3 enters the elastic pipe 2 into the cavity 9.

In the case of an elastic element in the form of an elastic rod (not shown in the figures), water flows into the cavity 11, which is formed between the inner side surface of the pipe 1 and the outer side surface of the elastic rod.

Under the pressure of the incoming water from the pressure supplying water supply conduit 3, an increase in the volume of the cavity 9 occurs (for the variant with a tubular element) or an increase in the cavity 11 for the variant with an elastic rod is proportional to the volume of the incoming water.

Water analysis is completed when the load is removed from the pressure lever 8. In this case, the pressure valve 5 closes. Upon completion of the water supply from the pressure supplying water supply conduit 3, the volume of cavity 9 or 11 is reduced by the action of the elastic forces of elastic elements, respectively. As a result, the residual water is completely removed from cavity 9 or 11.

Considering the initial value of cavity 9 or 11 (the minimum is chosen, for example, the size of the gap formed between the outer wall of the elastic rod and the inner wall of the supply pipe can be 0-1 mm) and the hydrophobic properties of the material (silicone rubber), a minimum amount of residual water is formed. Tests of the device showed that the appeared thin film of ice (or its fragments) is easily destroyed and removed when a new portion of water is supplied. The destruction of the ice film contributes to a change in the diameter or volume of the elastic element (tension-compression) during the supply of tap water from the pressure feed 3 conduit.

The proposed method can be implemented using well-known modern techno

- 3 012657 logies, do not require the use of expensive, scarce materials.

In general, the proposed technical solution allows to improve the removal of residual water after disconnecting the pressure supply conduit (water supply network).

Claims (11)

CLAIM 1. The method of removing water from the supply pipe of the water column, which consists in placing a dynamic element in the inner volume of the pipe, and forming the necessary cross-section for supplying water through the pipe by changing the diameter or volume of the dynamic element, and when the flow is turned off, the residual water from the pipe is removed in the direction of its supply, reducing the flow area. 2. The method of removing water from the supply pipe of the water column according to claim 1, characterized in that an element of elastic material is used, while changing its diameter or volume by compressing or stretching across the pipe with the flow of water supplied to the spout, and returning to the initial state due to the elastic deformation of the element. 3. The method of removing water from the supply pipe of the water column according to claim 2, characterized in that an elastic sleeve is used as an element, and a flow section is formed inside the sleeve. 4. The method of removing water from the supply pipe of the water-lifting column according to claim 2, characterized in that an elastic rod is used as an element, and a bore is formed between the outer wall of the rod and the inner wall of the pipe. 5. The method of removing water from the supply pipe of the water column according to claim 4, characterized in that they use a rod made of sponge rubber, or use a rod, which is a sealed chamber filled with gas. 6. The method of removing water from the supply pipe of the water column according to claim 1 or 2, characterized in that non-freezing liquid or gas is used or additionally used to change the diameter or volume of the element, while non-freezing liquid or gas is introduced when the flow is turned off and exempted liquid or gas when the flow is turned on. 7. The method of removing water from the supply pipe of the water column according to claim 6, characterized in that non-freezing liquid or gas is introduced into the space formed by the inner wall of the pipe and the wall of the element. 8. The method of removing water from the supply pipe of the water column according to claim 7, characterized in that an elastic sleeve is used as an element. 9. The method of removing water from the supply pipe of the water column according to claim 6, characterized in that an elastic rod is used as an element, and non-freezing liquid or gas is introduced into the existing internal axial cavity of the elastic rod. 10. The method of removing water from the supply pipe of the water column according to claim 9, characterized in that gas or non-freezing liquid is introduced through a rigid tube located in the axial cavity of the element, while ensuring that there is no gap between the walls of the tube and the walls of the cavity when the flow is turned off. 11. The method of removing water from the supply pipe of the water column according to claims 7, 9 or 10, characterized in that to facilitate the removal of water, the filling is started from the side opposite to the drain.