RU2628615C1 - Method of producing drinking water in field and extreme conditions - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: as a driving force, providing push of the cleaned water through filter element, the pressure is used generated inside the cleaned water filled shell, reduced either directly filed it gas, such as propane, stored in a liquefied state or in an enclosed compartment filter.

EFFECT: invention makes it possible to intensify the process of obtaining potable water in marching and extreme conditions while at the same time excluding physical efforts in obtaining it.

1 ex

Description

The invention relates to the field of obtaining clean drinking water in the field, as well as in emergency situations using surface water sources with various natural and anthropogenic pollution, infected with pathogenic microorganisms, viruses and toxic substances, by filtering it with subsequent sorption of toxins and disinfection.

Known methods of water treatment in the field, implemented by the use of small filters, in which the purified water is taken and its subsequent injection using a pump on filter elements of various nature - membranes, ultramembrane, sorbing and ion-exchange filling, etc.

Devices using this method of water treatment are implemented, for example, in RF patents No. 2204433, cl. B01D 35/26 and No. 2271997, CL C02F 1/18, as well as in the patent for utility model No. 120370, class. B01D 35/26, in which the water to be purified is pumped by a pump integrated in the filter housing or connected to it.

All of the presented analogues, in fact, to a greater or lesser extent purify water to a state of drinking quality, however, according to /www.vse-o-vode.ru. Camping water filters / “the first and most important minus is the slow liquid filtration in some models. Many also are not comfortable with manual filtering, which requires human involvement in the process. Indeed, in emergency situations, when it is possible to reach the water source only after many hours of hard work in cramped conditions, it is very difficult to expend physical efforts to pump the source water. It should be borne in mind that the higher the required level of purification associated with filtration, the greater the effort needed to be spent on forcing water, for example, through membranes. So, according to / 2 / ultrafiltration membranes with a pore diameter of 0.2 μm, which do not pass, for example, viruses, require an inlet pressure of 3 to 5 atm.

This disadvantage is also obvious in the patent for utility model No. 120370, which we selected for the prototype due to the similarity of its design with the device in which the authors intend to implement the proposed method. This lack of a separate pump is the case itself, consisting of coaxial upper and lower parts that can telescopically slide and move apart, forming an internal cavity of variable volume, which serves to withdraw the purified water.

However, for the operation of the presented prototype, where the pressure for pressing the purified water is achieved by shifting both coaxial parts of the housing (i.e., by decreasing the internal volume of the filter), in which the lower part serves as a piston and the upper part as a cylinder, with a piston diameter of a little less 2 cm, a lot of effort is required. So, considering what is needed according to /www.membrane.msk.ru. Department of membrane technology / achieve a pressure of 3 to 5 atm, it is easy to calculate that the force will be from 9 to 15 kg.

Our performance test of the prototype (IF-10 filter manufactured by Polymerfilter CJSC) really showed the need to use very great effort to squeeze the filter filled with water. In addition, the volume of pure water leaving at a single squeezing was only 6-8 ml. So, to fill a soldier’s flask with a volume of 750 ml, at least 90-100 cycles of expansion-compression of the upper and lower parts of the filter must be completed.

For a more efficient filter operation, at least double the piston diameter. In this case, the force required to compress the upper and lower parts of the filter will increase in proportion to the square of the diameter, i.e. will amount to about 60 kg, which in principle is not feasible.

The aim of the present invention is to provide a method for producing drinking water in the field and extreme conditions, allowing to intensify the process of obtaining drinking water without the use of physical effort.

According to the invention, the goal is achieved in that as the driving force for forcing the purified water through the filter element, use the pressure created inside the housing filled with purified water, reduced or directly supplied to it by gas, for example propane stored in a liquefied state or in a closed compartment filter.

An example of the method

At the first stage, the filter housing is filled with purified water. This can be either scooping up water with an open filter from a water source, or in accordance with analogue patent No. 2271997, class. C02F 1/18 filling it with a mug through the filler hole, or according to the prototype patent by compressing and pushing two coaxial parts of the filter - upper and lower. The lower part in this case contains a filter element, as well as a nozzle for introducing purified water and a clean water outlet device after its treatment in the filter element, equipped with a valve. The upper part has an air or gas outlet, which is blocked if necessary. Filling is carried out by 2 consecutive compressions and extensions. 2 strokes are necessary to completely fill the volume, because with a single extension of the lower and upper parts of the filter, with equal volumes, the total volume will double and only half of the internal volume of the filter will be filled with water.

At the second stage, by opening the shut-off valve or by reducing the actuation force of the pressure reducing valve, gas, for example propane, stored in a liquid state in a closed filter compartment, is discharged into the main compartment where the water to be purified is located. In this case, depending on the type of filter element, by setting the pressure reducing valve, the pressure limit value at which the purified water will be forced through the filter element (cartridge) is pre-set. The value of such pressure can take any given value from atmospheric to existing above liquid gas (propane), i.e. depending on the temperature of the medium (0-40 ° C) from 1 to 15 atm. Since this pressure is achieved by reduction, it will be almost constant throughout the entire filtration cycle until all the water in the filter is squeezed out (for example, 750 ml to completely fill the flask). After that, the cartridge is blown and dried with a small additional volume of gas. The remaining water at the bottom of the filter is removed by opening the intake valve. After that, the water purification process can be repeated at any necessary time. It should be noted that propane practically does not dissolve in water and does not worsen its organoleptic characteristics.

The choice of gas in the liquefied state is explained by a sharp increase in volume during the liquid-gas phase transition. So, 1 g - a mole of liquid propane, weighing 48 grams and occupying a volume of only 40 ml when it enters the gas phase at a pressure of 1 atm, will take a volume of 22.4 l; at 3 atm - 7.5 liters, at 5 atm - 4.5 liters. Those. when creating a working pressure inside the filter with a capacity of 0.75 l (the volume of the flask to be filled) at 3 atm, using only forty milliliters of liquid propane, it will be possible to fill 9-10 flasks. At a pressure of 5 atm, 5-6 flasks can be filled.

For comparison. If you use not liquefied, but simply compressed gas at 100 atm, for example air, then subject to the creation of a minimum working pressure (3 atm) and taking into account the flow rate for drying the sorbent, it will be enough to fill only one flask. At the same time, it is very problematic to act in extreme situations, while carrying a small capacity with a pressure of 100 atm.

Claims (1)

A method of producing drinking water in field and extreme conditions by processing it, including filtering, characterized in that the pressure generated inside the housing filled with the water to be purified is reduced or directly supplied by gas to it as a driving force for pushing the purified water through the filter element stored in a liquefied state in a closed compartment of the filter.