JPS6348599B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention is provided with a container, and a small common part of the outer wall of the container is formed as a semipermeable membrane. This invention relates to a device for recovering (producing) drinking water.

In most countries, it is stipulated that ships and aircraft must carry maritime rescue equipment. Generally speaking, inflatable lifesaving islands equipped with survival equipment are at issue. This survival equipment ensures a supply of food and drinking water for survivors.

Rainwater harvesting devices are used in some places to recover potable water, but these devices are useless when there is no rainfall, and storage containers for collected rainwater cannot be used. is necessary. Solar distillation devices are generally either bulky glass structures or fragile inflatable structures. This inflatable structure can only be used when the sun's rays are strong and the sea is calm. Methods that use chemicals to desalinate seawater can also only be carried out when the sea is calm and require expensive containers. This is because only the uppermost layer of water can be drunk. This technology is still insufficient and the amount of chemicals required is still too high. Ion exchangers are relatively expensive, heavy, and must be regenerated quickly.

Since these devices have the above-mentioned important drawbacks, it is often advantageous to store potable water directly in the survival equipment of the life island. However, the quantity of this potable water is limited by weight and space requirements, and is made to last only for a short time.

It is known to install reverse osmosis materials to recover potable water from seawater. In this case, pressure is applied to the seawater in a compression-resistant container with walls configured as semipermeable membranes. This pressure is higher than the osmotic pressure and causes water to pass through the membrane. Salt, on the other hand, remains on the pressure side and increases the concentration of seawater there. The water separated by passing through a membrane is suitable for drinking (1969,
Periodical “Spinner Weber”
(See “Practical Uses of Reverse Osmosis” on page 724 of “Textilveredelung”).

In conjunction with the above-described method of recovering drinking water by reverse osmosis, the use of conventional osmosis is also well known. (German Patent Publication No. 1517577). in this case,
In devices of the type mentioned at the outset, the osmotic pressure generated in the highly concentrated salt water present on the other side of the membrane, due to the normal osmotic action of seawater through the semipermeable membrane, must likewise be formed as a pressure vessel. The second semi-permeable membrane is used to generate a pressure within the vessel that serves to reverse osmosis the seawater within the vessel through a second semi-permeable membrane. In this case, however, the normal osmotic action is
It is only used auxiliary to generate pressure, and the recovery of drinking water itself takes place by reverse osmosis.

Devices of this type are not suitable for producing potable water in the event of a maritime accident. This is because the required pressure vessels are relatively heavy and require pumping machinery or a supply of highly concentrated saline water to generate the pressure. Relatively heavy and expensive, this container is only economical if it can be used frequently. This is because it is more economical to have the same weight of drinking water as the lifesaving supplies for one-time use. However, it is difficult to use such devices over and over again. This is because the performance of existing semipermeable membranes quickly deteriorates.
Therefore, repeated use is not sufficient to equip it as life-saving equipment in the event of a maritime accident.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a compact, inexpensive, simple and durable device of the type mentioned at the outset, with which potable water can be produced simply and reliably from seawater, impure water, etc.

This problem is solved according to the present invention, when the container is a foil bag,
This is achieved in that at least one common part of the foil bag consists of a semi-permeable membrane and that the foil bag is provided with a storage chamber for the water-soluble edible substance.

In this device, normal osmosis is used directly to recover potable water, with the pure water in the seawater penetrating through the semi-permeable membrane to the water-soluble edible substances. The concentrated solution, i.e. the water-soluble edible substance in the foil bag, removes the solution medium, i.e. water, from the less concentrated solution, i.e. seawater etc., after normal osmosis. That is, the initial concentrated solution is diluted by supplying pure water, resulting in potable water. Although this drinking water is not pure water, it does contain edible substances rather than salt as dissolved substances necessary for permeation. This edible substance significantly increases the physiological value of this drinking water relative to pure water.

Semipermeable membranes are made as synthetic foils in various embodiments and are used particularly in the food and pharmaceutical industries. Since the device according to the invention is light, cheap and small enough to be prepared for one-time use, it does not suffer from the disadvantage that the available membranes are not durable enough for multiple uses. For one-time use, this membrane is very reliable.

Since the apparatus according to the present invention simultaneously performs desalination, sterilization and filtration, it is suitable for selectively treating almost all liquids including water. At the same time, foil bags serve as storage containers for drinks, so there is no need to prepare special containers in your survival equipment. Once wrapped, this foil bag can be used semi-permanently and is durable. Moreover, since no advanced technology is required for handling, there is no problem in handling. Because they are small and independent units, even if a large number of foil bags are damaged, the remaining foil bags are completely usable.

The foil bag operates independently of sunlight, water temperature, muscle power or other energy sources. An important advantage is that it is very light. Since the water-soluble edible substances account for the majority of the weight of the device, most of the total weight can be allocated to high value food.

The resulting drinking water is therefore an emergency drink as well as an emergency ration. Since it is light in weight, it is particularly advantageous when installed on an airplane. For example, one 75g foil bag can provide about 0.5 liter of delicious drinking water with about 260 calories.

Advantageous embodiments of the invention are the subject of the implementation section.

Hereinafter, the present invention will be explained in detail based on illustrated embodiments.

The upper part 2 of the foil bag 1 shown in FIG. 1 consists of a watertight synthetic resin foil. The lower part 3 of this hose-shaped foil bag 1 consists of a foil forming a semipermeable membrane 4. The upper part 2 of the foil bag 1 is provided with a closed capsule 14 that can be crushed. This capsule forms a storage chamber 5 for a water-soluble edible substance 6, such as flavored fructose for thirst quenching and invigorating purposes.

The sealed foil bag 1 has a hanging hole 7 and an opening 8 at its upper end. This opening is closed by a stopper 9. Adjacent membrane walls of the lower bag part 3 are connected to each other at a number of welding or bonding points 10.

To recover (produce) drinking water, the capsules 14 are crushed by pushing against the walls of the foil bag 1. At this time, the foil bag 1 is not damaged. And this foil bag 1
is suspended in seawater, low concentration salt water, urine, dirty or unknown fresh water, etc., and gradually fills with water. A sterile drink with low salt content is created within the foil bag. After drinking this drink, the foil bag 1 can be thrown away.

Many substances are suitable as the water-soluble edible substance 6 as long as they satisfy the following requirements. That is, it has the properties of having a molecular weight as low as possible, being physiologically compatible, having high nutritional value, good taste, long shelf life, low cost, and not causing thirst. For example, it is very advantageous to use fructose with addition of fruit acids or menthol as an invigorating and thirst-quenching palatability additive. If at the same time a satiety effect is desired, a pudding-like porridge can be obtained by adding bulking substances. Additionally, energizers such as vitamins, caffeine, and drugs can be added.

Depending on the type of membrane 4 used, fructose can be used in the form of a dry powder or a wet syrup.

By using a simple plastic foil for the upper bag part 2, manufacturing costs can be reduced. This is because the synthetic resin foil is much cheaper than the semipermeable membrane 4.

By connecting the membrane walls of the lower part 3 to each other at welding or bonding points 10, this lower bag part 3
The chamber becomes smaller. The water-soluble edible substance 6 will therefore come into contact there with a relatively large membrane area. This causes the infiltration process to start quickly.

Since the water-soluble edible substance 6 is contained within a sealed capsule 14, it does not come into unintentional contact with the membrane 4 during storage. Therefore, even when stored for a long time, the function of the membrane is not adversely affected. This compressible and sealed capsule 5 is attached to the foil bag 1 when the foil bag 1 is used.
can be opened without damaging it. after that,
As the substance 6 reaches into the lower pouch part 3, the osmotic action begins.

Another method for avoiding accidental contact between the substance 6 and the membrane 4 is to provide a receiving chamber 5 in the upper part of the foil bag 1, as shown in FIG.
and fold the foil bag 1 multiple times. The folds 1', 1'', 1 that occur in this case move the substance 6 into the membrane 4.
Avoid contact with. When the foil bag 1 is unfolded and shaken before use, the substance 6 collects in the lower bag part 3.

Since foil bags have to be stored for many years under unpredictable environmental conditions, e.g.
It is advantageous to pack it airtight in the folded state by welding it into a wrapper 11 (FIG. 3) of plastic foil, which can be opened at a tear-off strip 12 running around it.

The capacity of the foil bag 1 is designed to be just sufficient to accommodate the amount of water that enters the substance 6 during infiltration to balance the concentration from normal seawater containing approximately 3.5% salt. Ru. Then, completely filling the foil bag 1 means that the drinking water collection process is finished.

When the foil bag 1 is used to recover drinking water from low concentration salt water, such as plain mixed water, dirty river water, urine, etc., a large amount of drinking water can be recovered. In order to take full advantage of this advantage, it is necessary to increase the capacity of the bag and to add markings, for example a colored line 13 running around the foil bag 1, to the foil bag 1. This mark indicates the maximum permissible filling amount for use in normal sea water, which may be exceeded for use in low concentration salt water.

The retention capacity of the semipermeable membrane 4 is selected depending on the particular use or, if the foil bag is to be universally usable, the average salt content in drinking water at the highest salinity. should be selected so that it is 0.5% or less.

A semipermeable membrane made of cellulose acetate, for example, is usually attached to a support layer made of paper, for example.
It is advantageous if this support layer is provided outwardly, ie on the side of the foil bag 1 towards the sea water. This support layer then serves as a prefilter and as a protector of the membrane from mechanical damage. It is also possible to apply an additional filter layer on the outside, for example made of blotting paper. However, in the case of foil bags that are used only once, this filter layer made of blotting paper is not absolutely necessary since the bag is used only once and for a short time.

As shown in FIG. 1, the opening 8 can be formed as a mouthpiece. This mouthpiece can be closed with a plug 9. Alternatively, the foil bag 1 can also be equipped with a closure element, for example a tear strip in the plastic foil, which can be opened without tools.

FIG. 2 shows the lower part of the foil bag 1 in a different embodiment from FIG. In this case, the semipermeable membrane 4 is attached to the window 15 of the foil bag 1, for example by welding. In the same manner, the back wall of the foil bag 1 can also be provided with a window 15 with a semipermeable membrane 4. The stability of the lower bag part is thereby increased. This is because the strength of the semipermeable membrane is generally weaker than that of the synthetic resin foil used in the remaining bag portion.

Further, the strength of the foil bag can be increased as follows. That is, the aforementioned additional outer filter layer or support layer is made of a strong material, such as a non-tearable synthetic fiber fabric, and is not only external to the semipermeable membrane but also adjacent beyond this. It also covers welded or adhesive joints with the foil, thereby preventing or making tearing of this joint less difficult.

By hermetically wrapping at least the lower part of the foil bag with the semipermeable membrane and the adjoining joint by an additional outer bag 16 forming a covering bag, for example made of a synthetic fabric fabric. , the strength of the foil bag can be effectively increased. (See Figure 2).

The present invention is not limited to the bag shapes, materials and scope of use described above. Many other bag shapes and methods of bag folding are possible. Also foil bag 1
And/or the wrapper 11 can be made of a material other than synthetic resin foil, for example a metal-synthetic resin mixed foil of rubber or the like. Similarly, many other areas of use are possible. For example, recovering potable water from surface waters infected by chemical weapons.

A one-time use method, in which the foil bag is discarded after one use, is advantageous. However, it is also in principle within the scope of the invention to use foil bags multiple times.
For this purpose, for example, a number of capsules 5 containing water-soluble substances 6 are provided, so that only one capsule is crushed each time it is used. Alternatively, it is also possible to replenish the foil bag 1 with water-soluble edible substance 6 after each use. For multiple uses, the water-soluble edible substance 6 can be mixed with disinfectants or preservatives that are not detrimental to human taste.

[Brief explanation of the drawing]

FIG. 1 is a side view of a foil bag according to the present invention, FIG. 2 is a diagram showing a lower part of a foil bag according to a different embodiment,
FIG. 3 is a diagram showing a foil bag according to another embodiment of the present invention folded inside the package. Codes in the figure: 1...Foil bag, 2...Upper part, 3...
... Lower part, 4 ... Semipermeable membrane, 5 ... Containment chamber, 6 ...
...Water-soluble edible substance, 8...Open mouth, 10...
...Connection part, 11...Wrap, 13...Mark, 14...
...capsules, 16...additional bags.

Claims (1)

[Scope of Claims] 1. A container for recovering drinking water from seawater, impure water, etc. by the osmotic action of the semipermeable membrane, which includes a container, and a small portion of the outer wall of the container is formed as a semipermeable membrane. In the device, the container is a foil bag 1, the least common part of which is comprised of a semipermeable membrane 4, and the foil bag is provided with a storage chamber 5 for a water-soluble edible substance 6. A device for recovering drinking water from seawater, impure water, etc. by osmosis. 2. For recovering drinking water from seawater, impure water, etc. by osmosis according to claim 1, characterized in that the storage chamber 5 of the foil bag 1 contains water-soluble food. equipment. 3 Containment chamber 5 for water-soluble edible substances
is formed inside the foil bag 1 by at least one capsule 14 which is sealed and can be crushed. A device for recovering potable water by osmosis. 4 The foil bag 1 is formed into an elongated shape, and the lower part 3
Claim 1, characterized in that only the foil bag 1 consists of a semipermeable membrane 4 and that a storage chamber 5 for a water-soluble edible substance 6 is provided in the upper part 2 of the foil bag 1. A device for recovering drinking water from seawater, impure water, etc. by osmosis. 5. The foil bag 1 is folded and provided in a sealed package 11 that can be torn open, and is resistant to osmotic action from seawater, impure water, etc. as set forth in claim 1. A device for recovering drinking water. 6 The lower part 3 of the foil bag 1 with the semi-permeable membrane 4 has at least one place at which the connection 1 between adjacent membrane walls is formed.
An apparatus for recovering drinking water from seawater, impure water, etc. by osmotic action according to claim 1, characterized in that the device comprises: 0. 7. Drinking water is extracted from seawater, impure water, etc. by osmotic action according to claim 1, wherein the foil bag 1 is provided with a reclosable opening 8 formed as a suction port. A device for recovering. 8. Recovery of drinking water from seawater, impure water, etc. by osmosis according to claim 1, characterized in that an additional filtration layer is attached to the outside of the semipermeable membrane 4. equipment for 9. The filtration layer extends beyond the semi-permeable membrane 4 and covers the welded or bonded portions of adjacent foils, which prevents seawater, impure water, etc. from penetrating action as set forth in claim 8. A device for recovering drinking water. 10 Prevents penetration from seawater, impure water, etc. as set forth in claim 1, characterized in that a lower portion of the foil bag 1 is hermetically sealed with an additional bag 16. A device for recovering potable water by action. 11. Claim 1, characterized in that the semipermeable membrane 4 is attached to the common window portion of the foil bag 1.
A device for recovering potable water by osmosis from seawater, impure water, etc. as described in Section 1. 12. A device for recovering drinking water from seawater, impure water, etc. by osmosis according to claim 1, characterized in that the foil bag 1 is provided with a filling amount mark 13. 13. A device for recovering drinking water by osmosis from seawater, impure water, etc. according to claim 1, characterized in that the water-soluble edible substance contains fructose. 14 Seawater, impure water, etc. according to claim 1, characterized in that a water-soluble edible substance is added with a taste additive that suppresses thirst and/or a taste additive that increases energy. A device for recovering potable water from water by osmosis. 15. Drinking water by osmosis from seawater, impure water, etc. according to claim 1, characterized in that the water-soluble edible substance contains vitamins and/or pharmaceutically active elements. Equipment for collection. 16 Claim 1, characterized in that the water-soluble edible substance contains caffeine.
A device for recovering potable water by osmosis from seawater, impure water, etc. as described in Section 1. 17. For recovering drinking water by osmosis from seawater, impure water, etc. as set forth in claim 1, characterized in that the water-soluble edible substance contains a disinfectant or a preservative. equipment.