WO2008134999A1

WO2008134999A1 - System and method for water purification using a solar collector

Info

Publication number: WO2008134999A1
Application number: PCT/DE2007/001321
Authority: WO
Inventors: Bernd HÖFLER; Peter TÜRK
Original assignee: TÜRK GMBH UND Dr. BERND HÖFLER GBR
Priority date: 2007-05-03
Filing date: 2007-07-26
Publication date: 2008-11-13
Also published as: TN2009000415A1; IL201540A0; DE202007018537U1; MX2009011765A; CA2685895A1; EP2152634A1; ZA200907188B; MA31425B1; AU2007352929A1

Abstract

The invention relates to a water purification system having at least one solar collector (1) operating an evaporator (2) and a condenser (5) for the evaporated, purified water. The solar collector (1) comprises an absorber (7) for the solar radiation, enclosed from bottom to top in a transparent housing (8), and a metal pipe (9) connected in a heat-conductive manner to the absorber (7) extending in the longitudinal direction of the housing, said pipe being filled with a fluid and the end of said pipe protruding out of the top of the housing (8) being provided with a condenser head (11) for condensation of the fluid evaporated in the metal pipe (9). The evaporator (2) has a container (13) holding the water (15) to be evaporated into which the condenser head (11) of the solar collector (1) protrudes in order to evaporate the water (15) by heating said water to the boiling point.

Description

SYSTEM AND METHOD FOR WATER CLEANING WITH THE HELP OF A SOLAR COLLECTOR

The invention relates to a water purification system according to the preamble of claim 1, in particular for the desalination of seawater or brackish water, but also for wastewater treatment. It also has a process for water purification to the object.

In addition to the reverse osmosis belong

Distillation process, in which the water is evaporated and then condensed, to the main processes for seawater desalination. The solar radiation is also used for this purpose (cf., for example, US Pat. Nos. 4,329,204 and 6,821,395 B1). However, the known plants for seawater distillation using solar radiation have only a low power, which is usually only a few liters of fresh water every day.

The object of the invention is to provide a system and a method for water purification high performance and low construction costs.

This is inventively achieved with the water purification system according to claim 1. In claims 2 to 12 preferred embodiments of the inventive water purification system are given. The claim 13 has the inventive water purification method to the subject.

In the system according to the invention and the method according to the invention, a solar collector is used, which has an absorber for the solar radiation, in a transparent from bottom to top, ie for solar radiation permeable housing, in particular a housing made of glass, is included. The absorber, the z. B. consists of a copper sheet or a solar radiation absorbing coating in the housing is thermally conductively connected to a metal tube, which extends in the housing in the housing longitudinal direction. The absorber and the metal tube are preferably sealed gas-tight in the housing in order to preclude thermal convection with the ambient air.

The metal tube is partially filled with a liquid, preferably water. At its upper end, which protrudes from the housing, the metal tube is provided with a condenser head having a communicating with the metal tube cavity. In this cavity, the water vapor is condensed, which is generated by evaporation of the water in the metal tube due to the heat that supplies the solar radiation absorbing absorber to the metal tube.

The absorber can z. B. by a copper sheet or z. B. a solar radiation absorbing coating of metal or metal ceramics may be formed inside the housing. For thermal insulation of the absorber and the metal tube relative to the environment, the housing is preferably evacuated. The metal tube, including the condenser head can z. B. made of copper or a copper alloy.

Such solar panels with an evacuated glass or double glass tube as a housing are also referred to as evacuated tube collectors and used in building services for domestic water heating and heating support (see the company's prospectus 3

RZ Solartechnik, Friedrich-von-Teck-Strasse 20, 89420 Höchstedt, Germany). The heat of the condenser head is discharged to a heat transfer fluid, which is supplied to a heat exchanger.

It has been found that the condensation of the evaporated water due to the sunlight in the condenser head, in which the heat of vaporization is released, can lead to a heating of the condenser head up to 200 ⁰ C. According to the invention, this high temperature of the condenser head is used to distill the water to be purified in the evaporator. For this purpose, the evaporator vessel is provided with an inwardly projecting receptacle into which the condenser head of the solar collector for heat transfer to the water in the evaporator can be plugged.

Thus, a commercially available solar collector is used according to the invention, so that the construction cost of the water purification system according to the invention can be kept low.

At the same time, the system according to the invention has an extraordinarily high performance. Because unlike other distillation plants using solar radiation, which only lead to evaporation of water, according to the invention, the water in the evaporator is heated to boiling temperature, so that the condenser of the system according to the invention considerable steam and thus amounts of water are supplied.

The receptacle in the evaporator housing, in which the condenser head is plugged into the solar collector, may for example be sleeve-shaped. To go through a planar contact of the condenser head to the Einsteckaufnahme to achieve a high heat conduction, the inner cross section of the Einsteckaufnahme is adapted to the outer cross section of the condenser head. The plug-in receptacle is preferably made of metal in order to dissipate the heat of the condenser head as lossless as possible into the water to be evaporated in the evaporator housing.

The evaporator housing is filled during operation of the system in the lower part with the water to be evaporated, while the upper portion is provided for the steam formed. Thus, the heat is dissipated by the condenser heads of the sun collectors on the shortest path in the water to be evaporated, the condenser head extends into the receptacle preferably only up to the height of the water level, at least in part to the height of the steam region in the evaporator vessel.

The evaporator housing is provided to the outside with a suitable for the high temperatures occurring thermal insulation, such as rock wool with aluminum foil or silicone.

Preferably, the housing of the solar collector is tubular. In this case, the length of the tubular housing, for example, 1 to 2 meters and its diameter z. B. 5 to 10 cm. Preferably, several, z. B. 10 to 40 such tubular solar panels arranged side by side in a plane parallel. The upper ends of the solar collectors are inserted with their condenser heads each in a receptacle in the evaporator vessel. The evaporator vessel, which extends substantially horizontally over the bottom-up tubular tubular solar collectors, z. B. be formed by a tube. The sleeve-shaped receptacles, in which the condenser heads of the solar panels are inserted, can extend transversely, ie from bottom to top, through the elongated evaporator housing or pipe from the lower to the upper side. You can at the top of z. B. be closed with a lid.

The receptacles of the evaporator housing for insertion of the condenser heads of the solar panels represent the heat transfer surfaces for transferring the heat from the condenser heads into the water to be evaporated in the evaporator vessel. To increase the ratio of these heat transfer surfaces to the water to be heated in the evaporator vessel is Evaporator vessel preferably not formed as a tube with a continuous same cross-section, but such that it has only in the area of Einsteckaufnahmen such a large cross-section that the water flow around the Einsteckaufnahmen, so can flow between the Einsteckaufnahme and the surrounding vessel wall, while the sections of the evaporator vessel between two adjacent Einsteckaufnahmen have a smaller diameter.

For this purpose, the evaporator vessel in the region of the insertion receptacles can be adapted to the shape of the sleeve-shaped insertion receptacles, that is, for example, have cylindrical or prism-shaped sections extending from below to above.

As mentioned, the evaporator vessel is at the bottom of the plant with the water to be evaporated and at the top filled with the formed steam. The plant is preferably operated continuously, ie, the evaporator vessel is continuously supplied, for example with a feed pump new to be cleaned water, while the vapor formed is withdrawn and condensed in the condenser to purified, distilled water. The distilled water is also germ-free, at least if at normal pressure so 100 ⁰ C or distilled over.

So that the evaporator vessel is always filled to a predetermined level with water, a device for controlling the level in the evaporator vessel is provided, for example, when falling below or exceeding the predetermined level, the feed pump is actuated or switched off.

The feed pump can be operated with a photovoltaic system that can be connected to a battery. This makes it possible with the feed pump, the evaporator vessel z. B. at night to rinse it z. B. in the seawater desalination of the deposited salt, sediments and the like to clean impurities.

Preferably, a tilting device is provided for the water purification system, with the help of which it is possible to empty the brine from the evaporator vessel before it is rinsed (cleaned). The brine can then be processed into seawater in the usual way to sea salt.

In addition, a pump can be advantageous with which the vapor is sucked out of the evaporator vessel and fed to the condenser. As a result, a negative pressure is generated in the evaporator vessel above the water surface, the 2007/001321

7 promotes the evaporation in addition. This pump can also be operated with the photovoltaic system.

So that no water but only steam can get into the evaporator vessel in the condenser, the evaporator is preferably connected via a riser to the condenser.

Preferably, the water supplied to the evaporator is preheated with a preheater. When the condenser is condensed to condense the evaporated water in countercurrent with water or other fluid, the countercurrent in the condenser, heated fluid can be supplied to the preheater, and the preheater can be operated with one or more solar panels, as according to the invention be used the evaporator. The higher the temperature of the water supplied by the preheater to the evaporator, the smaller the evaporator's solar panels can be dimensioned. That is, instead of, for example, a two meter long and a corresponding wide solar collector unit for the evaporator may then optionally a much smaller unit can be used.

The invention is explained in more detail with reference to the accompanying drawings. In each case schematically show:

Figure 1 is a front view of a system according to the invention;

Figure 2 is a view of a portion of a solar collector of the system of Figure 1; Figure 3 is a longitudinal section through part of the evaporator along the line III-III in Figure 4 with the upper ends of the solar panels of the system of Figure 1, but without heat insulation of the evaporator vessel. and

Figure 4 is a section along the line IV-IV in Figure 3, but without condenser heads or solar panels.

According to FIG. 1, the water purification system has a plurality of solar collectors 1, which are arranged parallel to one another in a plane and operate an evaporator 2 which extends over the solar collectors 1.

On the evaporator 2, a line 3 for supplying the water to be purified and at the other end a riser 4 is connected at one end, via which the vapor formed in the evaporator 2, a capacitor 5 is supplied, in which the formed in the evaporator 2 Steam to purified water or condensed in the seawater desalination to fresh water, which exits at 6 from the condenser 5.

As shown in Figure 2, each solar panel 1 has a z. B. formed as a copper sheet absorber 7, which extends in a tubular glass housing 8 from bottom to top. The absorber 7 is thermally conductively connected to a extending in the housing longitudinal direction metal tube 9, z. B. by soldering, surface conditioning or the like. The metal tube 9 protrudes with its upper end out of the housing 8 to the outside, which is evacuated for thermal insulation. The solar panels 1 are aligned so that the solar radiation falls perpendicular to the absorber 7 as possible.

The protruding from the evacuated housing 8 end of the metal tube 9 is provided with a condenser head 11, which is also made of metal. The metal tube 9 is filled at the bottom with a liquid, in particular water.

In sunlight, the heats up the

Absorbing solar radiation absorber 7, wherein it transfers its heat to the metal tube 9. Thus, the water is evaporated in the metal tube 9, wherein the water vapor condenses in the condenser head 11, whereby the heat of condensation of the water released and thus the condenser head can be heated to a high temperature of about 200 ⁰ C. The condensed in the condenser head 11 water flows back into the metal tube to re-evaporate in the circuit.

According to FIG. 3, the condenser heads 11 of the solar collectors 1 are inserted into sleeve-shaped receptacles 12, which extend transversely through the evaporator vessel 13 of the evaporator 2. The evaporator housing 13 is filled up to the level of the water level represented by an arrow 14 with the water 15 to be cleaned. The space 16 above the water level 14 forms the steam room.

Due to the high temperature of the condenser heads 11 of the solar panels 1, the water 15 in the evaporator vessel 13 is heated to boiling temperature ie at normal temperature to above 100 ⁰ C until boiling and thus evaporated in large quantities. 21

10

In order to ensure optimum heat transfer, a flat contact of the condenser heads 11 is provided on the inside of the receiving sleeves 12.

Thus, the heat from the condenser heads 11 as short as possible lossless passes over the existing metal receiving sleeves 12 in the water to be evaporated 15, protrude the condenser heads 11 of the sun collectors 1 only to about the level of 14, at least not or only slightly Height of the steam room 16.

If the evaporator housing 13 only consists of a simple tube whose diameter is not greater than the length of a condenser head 11, this penetrates the sleeve-shaped receptacle 12, of course, entirely.

As shown in Figure 1, the evaporator vessel 13 is provided with a thermal insulation 10.

The receiving sleeves 12 for inserting the condenser heads 11 of the sun collectors 1 form the heat transfer surfaces for the transfer of heat from the condenser heads 11 in the water to be evaporated 15 in the evaporation vessel thirteenth

In order to increase the ratio of these heat-transferring surfaces, ie the outer surfaces of the condenser heads 11, to the volume of the water 15 to be heated in the evaporator vessel 13, the evaporator vessel 13 is preferably designed such that it has a large cross-section in the region 17 of the receiving sleeves 12, so that the water 15 can flow around the receiving sleeves 12 on both sides, as in Figure 4 illustrated by the arrows 18. In contrast, between the regions 17 with the receiving sleeves 12, the evaporator vessel 13 has sections 19 with a smaller width, as can be seen from FIG. In order to further increase the ratio of the heat-transferring surfaces to the volume of the water 15 in the evaporator vessel 13, moreover, as can be seen in FIG. 4, the regions 17 are adapted to the shape of the receiving sleeves 12, that is to say they are cylindrical or, as in FIG right area 17 shown schematically by dashed lines, for example, prism-shaped.

The water to be purified is supplied via the evaporator 10 via the line 3 with a feed pump 21, while the steam formed in the evaporator 10 is withdrawn via the riser 4 and condensed in the condenser 5 to the purified, distilled water. Since the water in the evaporator 10 has been heated to 100 ⁰ C and more, it is also germ-free.

Thus, the evaporator vessel 13 is always filled up to the level 14 with water 15, a device, not shown, for regulating the level of the water 15 is provided in the evaporator vessel 13, wherein the predetermined level 14 is set, for example by pressing or switching off the feed pump 21.

The condensed in the condenser 5 water exits at 6. As shown by dashed lines in Figure 1, the condenser 5 is cooled in countercurrent with water, which enters the condenser 5 at 23 and exits at 24.

The water to be purified can be supplied via a line 26 to a preheater 25, which is connected to the Water supply line 3 is connected. The heated water discharged at 24 in countercurrent to the condenser 5 at 24 may be supplied to the pre-heater 25 for preheating.

Claims

claims

1. Water purification system having at least one solar collector (1), which operates an evaporator (2) and one connected to the evaporator (2) capacitor (5) for the evaporated, purified water, characterized in that the solar collector (1) an absorber ( 7) for the solar radiation, which is enclosed in a bottom-up transparent housing (8) and a thermally conductive with the absorber (7), in

Has housing longitudinally extending metal tube (9) which is filled with a liquid and its top of the housing (8) projecting end with a condenser head (11) for condensing the vaporized in the metal tube (9) liquid is provided, wherein the evaporator (2) a vessel (13) with the water to be purified (15) into which the condenser head (11) of the solar collector (1) protrudes to evaporate the water to be purified (15) in the evaporator vessel (13) by heating to boiling temperature.

2. Water purification system according to claim 1, characterized in that the evaporator vessel (13) has an inwardly projecting receptacle (12) into which the condenser head (11) of the solar collector (1) for heat transfer into the water to be purified (15) in the Evaporator (2) can be plugged.

3. Water purification system according to claim 1 or 2, characterized in that the housing (8) of the solar panels (1) is tubular.

4. Water purification system according to one of claims 1 to 3, characterized in that a plurality of solar panels (1) are provided and the evaporator vessel (13) with a plurality of insertion receptacles

(12) for inserting the condenser heads (11) of the solar panels (1) is provided.

5. Water purification system according to claim 4, characterized in that the evaporator vessel (13) for flowing around the Einsteckaufnahmen (12) with the water to be cleaned (15) in the region (17) of the Einsteckaufnahmen (12) has a larger cross section than in the area ( 19) between two adjacent insertion receptacles (12).

6. Water purification system according to one of the preceding claims, characterized in that a device for regulating the level (14) of the water (15) in the evaporator vessel (13) is provided.

7. Water purification systems according to claim 6, characterized in that the means for controlling the level (14) in the evaporator vessel (13) comprises a feed pump (21) for supplying the water to be purified in the evaporator vessel (13).

8. Water purification system according to claim 5 or 6, characterized in that a photovoltaic system is provided for operating the level control device.

9. Water purification system according to one of the preceding claims, characterized in that the evaporator vessel (13) via a riser (4) to the capacitor (5) is connected.

10.Wasserreinigungsanlage according to any one of the preceding claims, characterized in that a preheater (25) for preheating the evaporator (2) supplied water (15) is provided.

11.Wasserreinigungsanlage according to claim 10, characterized in that the condenser (5) is cooled in countercurrent with a fluid and in the condenser (5) in countercurrent guided heated fluid is supplied to the preheater (25).

12.Wasserreinigungsanlage according to claim 10 or 11, characterized in that the preheater (25) is operated with at least one solar collector (1) according to claim 1.

13. Process for water purification, in particular

Seawater desalination by evaporation of the water under the action of solar radiation and condensation of the evaporated water, characterized in that the water to be evaporated (15) using at least one solar collector (1) according to claim 1 is heated to boiling temperature.