SE510287C2 - Water heater and condenser - Google Patents

Abstract

Liquid purification device comprising interspaced plates fitted over a tube used for hot water to flow from the bottom to the top of the vessel, is new. The liquid purification device comprises a vessel with: (a) a bottom part containing a heating device; (b) a top part for receiving the liquid, containing a number of plates with a central hole for the tube and some with holes positioned around the central hole; and (c) a central tube for the upwards flow of heated liquid.

Description

a 2 about mšn1sgöter2u8tb7ytet of coarse filters, ultraviolet lamps, ion exchange masses and activated carbon carefully.

As an alternative to these multi-stage filters, equipment based on distillation and reverse osmosis has also been developed. however, none of these per se advanced methods are completely effective in removing chlorine and chlorinated hydrocarbons, but must be supplemented with a final filter with activated carbon. Although the load on this final filter is much less than on carbon filters in the previously mentioned multi-stage filters, these must also be replaced at regular intervals and the problem of overload remains.

An easier way to kill bacteria as well as to remove chlorine and chlorinated hydrocarbons and also other volatile substances from water is to boil the water in a pan or open vessel.

Disadvantages of this simple method are mainly three. A large amount of water must be boiled in order to be sure of getting rid of the volatile pollutants, which results in, firstly, waste of water and, secondly, concentration of the non-volatile pollutants which may be in the water. The third disadvantage is that a user does not know for sure when a satisfactory result has been achieved. In industry, a large number of methods have already been developed for separating liquid from gas, gas from liquid and one gas from another gas. The most common principle is the cyclone principle, which means that a steam / gas / water mixture is centrifuged and the liquid is thereby forced out of the mixture. A similar principle is that the mixture is led through a line with many bends, whereby the liquid is stopped by devices of different design in the bends.

Furthermore, surface enlarging devices are used in such a way that water / gas long mixtures are sprayed or sprinkled. on. large plates or steel gutter down large boards or other type of device with a story surface, for example such as steel wool or plastic balls.

Gas, t_ex_lutt or nitrogen passes through the mixture. This gas then expels or pulls other gases out of the mixture. A combination of the techniques just mentioned is often used.

The present invention means that a device according to this invention removes all chlorine and all chlorinated hydrocarbons from water in a simple manner and almost completely in one step. At the same time as these substances are removed, other potentially mutagenic substances are also removed, such as radon and chemical pesticides, from water. The device differs from the previously mentioned techniques by its simplicity. Neither the centrifugal force, nor specially supplied gases are used. The efficiency of the device is unchanged throughout its life and independent of filter changes or other user interventions. Furthermore, it can be manufactured at a price that is at most one tenth of the cost - for previously described equipment and can therefore be made available to even the poorest households, where water problems are greatest and often have a fatal outcome. Tens of millions of children die each year from infections from drinking water, and an even greater number are injured for life.

In cases where water is not chlorinated, such as in individual wells, the invention has the advantage that the device kills all bacteria, spores, amoebae, viruses, fungi and other living pathogens, and in addition removes unwanted odor and taste from the water. 51 0 2 8 7 a nEOOGÖNELSE FÖN INVENTION In a liquid cleaner of the kind mentioned above, a first plurality of discs are arranged in the upper part with center holes for the riser and with a plurality of holes spaced from but close to the center hole and a other plurality of discs with center holes for the riser.

Said discs are interleaved with and placed at a certain distance from each other.

According to a further development of the inventive idea, in the lower part in connection with the heating means there is a clock switch pre-adjustable by means of an internal time control and, possibly, an externally adjustable time control for setting the heating time for the liquid depending on the type of pollutant the liquid is to be purified from.

DESCRIPTION OF THE DRAWINGS The invention will be described in more detail in connection with the accompanying drawing, in which schematically: Fig. 1 shows a liquid jug; Fig. 2 shows a bottom plate with heating means and time control; Fig. 3 shows an outer lid; Fig. 4 shows riser means with a first and a second plurality of discs; Fig. 5 shows a disc from the first plurality of discs; and Fig. 6 shows a clock switch with internal and external time controls.

PREFERRED EMBODIMENT The liquid jug 11 looks like an ordinary jug with handle and spout, but has in its bottom a bowl-shaped heater 112, arranged to be heated from below by a heating plug 102 projecting upwards from a bottom plate 10. The bottom plate contains an electric heating means. ), not shown in the drawing, with the heat concentrated to the plug 102, and an externally adjustable timer 101. The complete liquid cleaner thus consists of the lower part 10 and the jug 11 assembled with the heat plug 102 inserted in the heating ring. It is ensured that water cannot penetrate via the ring 112 plug 102.

With the time control 101 you can set a suitable heating time for liquid to be purified; this setting is made depending on the type of pollutant you want to clean the liquid from.

The jug includes a lid 16, see Fig. 3, which fits the jug opening.

Fig. 4 shows the riser member 12, which is an inner, central and tubular member in the jug 11, intended for liquid heated at the heating ring 112, and rising upwards through the member.

The ladder member 12 has at its lower end 125 a foot 126 which fits into the heating ring 112 of the jug 11, which thus at the same time constitutes a bracket for the ladder member. Arranged in the upper part of the member are a first plurality of discs 121, 123 with center holes and with a plurality of holes (1211) spaced from but close to the center hole of the riser and a second plurality of discs 122, 124 with center holes for the riser 12 Said discs 121 ..., 122 ... are interleaved with and placed at a certain distance from each other.

The discs 121, 123 in the first plurality of discs have a diameter of about 10 cm and bend slightly upwards, while the discs 122, 124 in the second plurality of discs have a diameter of about 9 cm and bend slightly downwards. The distance between the discs is 1.5 - 2.5 cm.

Figs. 4-5 show the disc 121 with center hole 1210 and hole 1211 (8 pcs.), Near the center hole. The riser 12 with the first plurality of discs 121, 123 and the second plurality of discs 122, 124 into the jug 11 with the riser foot 126 in 11Z. liquid in the jug 11, and the timer 101 is set to a suitable value, whereby connection to the electrical network is automatically switched on (not shown). When liquids (water) are heated, gas bubbles are formed in the heating ring 102 which force heated water into the riser 12. This water sprays out of the top of the riser and is then distributed evenly over the first disc 121 by a device 161 in the lid of the jug. Liquid then flows towards the center of the disc 121 and downwards outside the riser through the holes of this disc located near the center hole of the disc. The liquid then flows out towards the periphery of the disc 122, again towards the center of the disc 123 and again out towards the periphery of the disc 124. This continues the cycle a certain number of times until the liquid has been purified from experience with the current contaminant.

As the heating ring 112 is heated by the heat plug 102, water present in the ring will boil. Vapor bubbles formed thereby push up water in the riser12. The ring 112 is subsequently filled with new water through a valve in the foot 126, which allows water to flow down into the ring but steam can not come out other than up through the riser 12; this is because when steam bubbles are formed they push to the valve, and when the steam bubbles go up through the riser 12 they release the valve and water can flow down into the ring 12. This technique is better known, see e.g. Swedish patent specification 339864, page 5, para. 4.

During the process, contaminants released disappear through the spout of the jug and through cracks between the jug and the lid of the jug and between the lid and the knob of the lid.

Once the treated liquid (water) has been transferred to another container, new liquid can be filled in batches from a liquid line. In another embodiment, the treated liquid is continuously discharged, and new liquid is continuously replenished in the same amount. Fig. 6 shows how time setting for the liquid purification can take place. In connection with the heating means 102, a clock switch 6 is arranged, which is presettable for a certain desired heating time, e.g. 20 minutes for purification of liquid from chlorobenzene. The setting is made with an internal control 61, which is fixed at the factory in the intended position. The jug is then intended for purifying liquid from a limited number of contaminants, and the outer control 101 is deleted. 510 287 5 In a more sophisticated version, the jug is intended for liquids with a larger number of different contaminants with the consequent required large time interval as a working area, e.g. 15 - 30 minutes. In this case, it is suitable (necessary) with an external time control 101, which is mechanically coupled to the internal, now non-fixed control 61, and whose setting by rotation can be varied as desired.

The new water purifier has undergone certain tests to examine the extent to which water samples have been released from pollutant (s). The following table shows from the left: column I pollutants; column ll amount of substance pg / l; resp. mg / l and Bq11; column III elimination in% of pollutant (s) after 15 mln heating; column IV "" 20 "" column V "" "" "" 27 "" I ll lll lv V chloroform 83 1, 1, 1-trichlorethylene 58 trichlorethylene 64 dichlorombromethane 92 95 99 100 tetrachlorethylene 83 dibromochloromethane 73 bromoform 140 free chlorine 3, 5 mg / l 100 radon 470 Bq / l 100 I lll IV V 3-hexanone 89 96 98 butyl acetate 94 100 100 chlorobenzene 95 98 100 1-chlorohexane 98 99 100 anisole 90 96 99 pentyl acetate 96 98 100 propylbenzene 96 98 100 dichlorobenzene 98 97 100 decane 96 99 100 1-chloroctane 98 99 100 Loss of water in% 4 »7 10-11 20-21 for all substances.

After 15 minutes, about 95% of the volatiles have been removed and 94% of the water remains.

After 20 minutes, just over 99% of the volatiles have been removed and 88% of the water remains. 510 287 6 After 27 minutes, all volatiles are below the measurement limit which is OJPg / l, i.e. in practice, 100% has been removed, while 79% of the water remains.

In the case of free chlorine, after 15 minutes chlorine has been removed to below the detection limit of 0.1 mg / L and 94% of the water remains.

In the case of radon, after 15 minutes radon has been removed to below the detection limit of 1Bq / l and 93% of the water remains.

In tests with 10 organic compounds with boiling points below 200 ° C the results were as follows: boiling point ° C elimination of substance in% after min: 15 (min) 20 (min) 27 (min) 3-hexanone 125 89 96 98 butyl acetate 127 94 1 00 1 00 chlorobenzene 132 95 98 100 1-chlorohexane 135 98 99 100 anisole 155 90 96 99 pentyl acetate 149 96 98 100 propylbenzene 159 96 98 100 dichlorobenzene 174 93 97 100 decane 174 96 99 100 1-cloctane 182 98 99 100 loss of water in% 3.8 10.6 20.0 It should be noted that with this liquid cleaner you get a faster process and less loss of water than with normal boiling.

The invention is not limited to the examples set forth above but may be modified in many ways within the scope of the appended claims.

Thus, the liquid cleaner can be designed for a few decilitres of liquid up to many liters, and for heating by means of electrical resistance at the bottom or with a flame for gas, LPG, biomass, coal or other fuel in solid or liquid form or solar energy. The cleaner can be freestanding or built into a stove, oven, stove or other device for heating. It can also be connected to a water pipe for continuous filling of water. In one embodiment, the purified liquid (water) can be transferred to a special container where it can be used as it is or kept warm, for example with an electric coil, or cooled, for example with a compressor.

In another embodiment, the heated liquid is pumped up through the riser with, for example, an electrically driven pump.

Liquid cleaners with significantly larger capacity can be separately installed or built into heating plants for single- or multi-family houses. These cleaners are then suitably switched on automatically as the need for clean water arises. Such larger cleaners can be used in restaurants, hotels, the food industry and the like. 510 287 7 A major problem in connection with heating water is in all vessels precipitation of lime and iron oxide. Therefore, it may be appropriate to place a lime filter or other type of ion exchanger in a special container above the water surface but below the mouth of the central riser. Since this body is the part that will be most exposed to liming, it is advisable to make it from a flexible material so that it is easy to clean from hard deposits. The body can also be provided with sharp edges so that lime can be easily broken off. However, descaling can also easily take place by means of weak acids such as citric acid or acetic acid or by magnetic action.

Claims (4)

510 287 PATENT REQUIREMENTS Liquid cleaner, intended for purifying liquid from pollutants and comprising a vessel (1) with a lower part (10) provided with heating means (102), an upper part (11) intended for the liquid, and an inner General, tubular riser means (12) for heated liquid rising upwards through the riser, wherein the heated liquid from the upper open end (120) of the riser flows back downwards through the upper part (11) outside the riser (12) for re-heating, new rise upwards through the riser member, etc., characterized in that in the upper part (11) is arranged a first plurality of discs (121, 123 ...) with center holes (1210) for the riser member (12) and with a plurality of holes (1211) at a distance from but close to the center hole (1210), and a second plurality of discs (122, 124 ...) having center holes for the riser (12), said discs (121 122 ...) being interleaved with and placed at a certain distance from each other. Liquid cleaner according to claim 1, characterized in that in the lower part (10), in connection with the heating means (102), a clock switch (6) is arranged presettable by means of an internal control (61) for heating time for the liquid depending on which type of pollutant the liquid must be purified from. Liquid cleaner according to Claim 2, characterized in that an externally adjustable control (101) for setting the heating time of the liquid is connected to the clock switch (6), depending on the type of pollutant the liquid is to be purified from. Liquid cleaner according to one of Claims 1 to 3, characterized in that the discs (121, 123 ...) in the first plurality of discs have a diameter of approximately 10 cm and bend slightly upwards towards the edge, while the discs (122, 124). ..) in the second most discs have a diameter of about 9 cm and bend slightly downwards towards the edge, and that the distance between the discs is about 1.5 - 2.5 cm.