DE4429838A1 - Solar=operated water heater - Google Patents

Abstract

Part of the top surface of the housing (2) has a heat-absorber (6) supplied with colder water, while hot water is stored in a number of tanks (9), the water outlet from each tank being connected to the inlet to the adjacent one. Control can be by a thermostat detector (16) after the absorber and a thermostat valve (15) in the water circuit. The valve and/or pump (13) can be at the absorber inlet. The housing can be of triangular cross-section, with the hypotenuse forming the absorber, while the tanks are tubular and of decreasing cross-section to fit inside the triangle. They can consist of pressure vessels, and the mounting shells accommodating them can form part of the heat-insulating material (10).

Description

The invention is directed to a device for warm Water generation using solar energy in claim 1 given genus.

From a publication "Sunworld / Volume 3 / Number 2/1979 ", page 30, is a generic device known. In the known solution, a plurality of stacked tanks with inlet and outlet of the art linked that including the collector the ent speaking device can be operated in natural circulation can.

A device with a slightly different design is included known for example from DE-A-37 28 551, with there tel are provided, the warming water from under different areas of a hot water reservoir with the help to circulate a pump. A temperature stratification can be there cannot be maintained. Under the product name "Rainbow 300" is such a device by the applicant known in the Swiss patent application 01 933 / 92-0 is described in more detail. With this solution The exact amount of hot water flowed through the collector sends that is necessary to the desired final temperature to achieve, then the domestic water in one  Tank saved, which is empty again when hot water is drawn running. Instead of hot and cold water layers, it contains corresponding storage only hot water and air, being only pressureless hot water is available there.

In some of the known solutions one tries to use Zwi shelves or dividers either in the hot water tanks a temperature stratification of that heated by solar energy Reach heat transfer medium or in the filled Spei chances to reduce the heat loss chances. In the too the last-mentioned Swiss patent application is also a Divider solution or a tank-in-tank solution known, at which can be made possible by appropriate regulations the cold process water through the solar system cause the desired end at the outlet of the device temperature is reached, so that a reheating by Zu energy is unnecessary. Will not be a heated custom water is needed, the warmed water becomes a warmth isolated storage, held there like this also described in the aforementioned DE-A-37 28 551 is.

Problems of the known solution exist. a. in that only unpressurized hot water is available or that the Temperature stratifications in the stores in comparison can be degraded by heat conduction in a short time A night  part, the one that is as flat as possible and here in the front have basic solar water heaters.

The object of the invention is therefore to create a solution, with the also in comparatively flat, compact Vorrich a stratified storage of hot Pressurized water is made possible with high availability.

With a device of the type described in the introduction solved this problem according to the invention in that the Storage tanks essentially horizontally side by side arranged and that for the circulation of the water a pho tovoltaically operated pump is provided.

With the invention, the advantages of a compact construction wisely linked to simple regulation. Through the integra tion of a storage collector and a stratified storage in a compact design with thermal separation of the individual NEN temperature ranges with the possibility of these isolate each other, with the invention, the front parts of closed-loop controlled solar systems with layer spit linked.

Embodiments of the invention result from the Unteran sayings:  

According to the invention, for example, at least for regulation a thermostat sensor behind the absorber and a thermos tatventil be provided in the water circuit, the Thermostatic valve and / or the pump useful in the area of the absorber inlet is arranged.

This has the advantage that in the area of the absorber inlet the water temperatures are the lowest and therefore the least risk of calcification.

According to the invention can in a device with a cross-section approximately triangular housing, the die Triangle hypotenuse forming the surface of the heat absorber or solar collector forms, an embodiment therein stand that the storage tanks are tubular with smaller who fill the cross-section of the housing shape of the triangle, where the linked storage tanks are useful as Druckge barrels are formed.

The thermal insulation of the storage tanks can be advantageous at least partially as long shells made of insulating material fabric formed, resulting in easy assembly in Ver binding with the compact design.

The invention is below with reference to the drawing explained in more detail, for example. This shows in the only one  Figure in partially broken, simplified perspective vischer representation of a device according to the invention.

The generally designated 1 device has a cross-sectional approximately triangular housing 2 , which is equipped with egg nem cold water inlet 3 and a hot water supply 4 .

On the housing surface facing the main solar radiation, an absorber 6 is arranged under a transparent cover 5 , which is provided in the direction of gravity with a lower inlet 7 and an upper outlet 8 . A basic water supply would be such that cold water is supplied to the absorber via the inlet 7 via the inlet connection 3 and is removed via the outlet 8 above and is then directly available to a hot water consumer via line 4 .

Inside the housing 2 , three storage tanks 9 with a decreasing cross-section are seen in the example shown, which are housed in insulation, designated by 10 in the figure and only partially indicated.

Each of the storage tanks 9 has a water drain 11 a, 11 b and 11 c seen in the conveying direction of a pump 13 and corresponding hot water inlets 12 a, 12 b, 12 c, the water drain 11 c with the water inlet 12 b of the adjacent container and the water outlet 11 b with the water inlet 12 a, as shown, is connected such that the storage tanks 9 are cascaded ver linked. When hot hot water is withdrawn via line 4 , cold water is pressed via inlet 11 a into the assigned storage tank 9 a.

A pump 13 , which is operated by means of solar cells 14 , is arranged in the connecting line between line 11 a and the absorber inlet 7 . Here, a thermostat control valve 15 is indicated behind the pump 13 , which interacts with a temperature sensor at the end of the Absorberauslau fes 8 .

With the pump 13 , it is possible to carry out the circulation of the stored water, the pump being able to be operated independently of a network. In direct Stormversor supply via a photovoltaic solar module takes place before a coarse rough regulation of the volume flow so that a lot of water is circulated at high energy radiation, less at lower energy radiation.

It is possible to improve the control characteristics operate the device differently, e.g. B. a ensure the desired predetermined final temperature.

So it is possible to interrupt the pump 13 until a final temperature is reached at the absorber outlet or, alternatively, the thermostatic control valve 15 z. B. to control the tem perature sensor 16 at the output 8 of the absorber 6 , which has the additional advantage that at Warmwasserentnah me no too cold water flows directly through the absorber instead of from the memory 9 c when in this case the valve the absorber output 8 closes.

The mode of operation of the device according to the invention is as follows:
The device 1 is a print version of a storage collector system for domestic water, which can be closed, for example, on the cold water network via line 3 of a house. The device is operated with a pressure of e.g. B. operated up to 3 bar.

In the absorber 6 , the water is heated by solar radiation. The thermostatic valve 15 , which can be regulated continuously between 40 ° C and 60 ° C, ensures that the water only leaves the absorber when it has reached the set temperature. The hot water is then in the storage tank 9 c of the memory 9 z. B. initiated via a longitudinally slotted line 17 so that there is the least possible turbulence in the tank 9 c. The memory is c 9, as already described above, b and connected to the neighboring stores 9 9 a cascade moderately such that there is a ge coated operation: hot water above, cold water downwardly within the respective tanks, wherein the Tem peraturniveaus the adjacent tanks each from tank 9 c backwards to tank 9 a are lower. The absorber is only fed in cold water in an amount that it is warmed to the actually required preselected final temperature, so that the heat losses of the collector are significantly lower than that of conventionally operated solar systems. The water withdrawal via line 4 to the consumer takes place from the hot part of the memory 9 , ie in the example shown via line 17 from the tank 9 c.

The photovoltaically powered pump 13 circulates the water, with the solar cells simultaneously taking over control functions: in the case of large solar radiation, when a large amount of heat can be absorbed in the absorber 6 , the pump 15 also receives a lot of electricity in order to have a sufficiently large amount of water through the Pump absorber 6 . If the sun's rays decrease, the water in the absorber takes a longer time to heat up, but at the same time the pump runs slower.

In the start-up phase, for example immediately after sunrise, the first water is brought to the desired temperature with the first sun rays at a low pump output and stored in the tank 9 c. An undesired mixing, which would inevitably lead to a lower average temperature, is prevented by the selected flow guide and the partial tanks 9 a to 9 c.

As a storage volume of the storage 9 , for example, 300 liters can be provided, with 300 liters can be heated up to 50 ° C in the course of a day with normal sunshine. If the entire memory is filled with hot water, the absorber 6 is also charged with hot water via the pump 13 so that the temperature can rise above the temperature set on the thermostat, for example 70 ° C. If this is the case, the circulation pump 13 is switched off in order to protect temperature-sensitive components.

Of course, the described embodiment of the invention can be modified in many ways without departing from the basic idea. For example, in addition to the three storage tanks 9 shown here with a round cross section, another cross-sectional shape can also be selected. The invention is not limited to any particular insulation u. Like. more.

Claims (7)

1. A device (1) energy for producing hot water by means of Solarener, wherein a surface portion of the device housing (2) fed by colder water heat absorber (6) is assigned, and wherein an image formed from a plurality of storage tanks (9) hot water within the housing (2) Reservoir is provided with water inlets and water drains, the water outlet and water inlet of adjacent containers being connected to one another, characterized in that the storage tanks ( 9 ) are arranged essentially horizontally next to one another and that a photovoltaically operated pump ( 13 ) is provided for circulating the water is. 2. Apparatus according to claim 1, characterized in that for regulating at least one thermostat sensor ( 16 ) down the absorber and a thermostatic valve ( 15 ) is provided in the water circuit. 3. Apparatus according to claim 2, characterized in that the thermostatic valve ( 15 ) and / or the pump ( 13 ) is arranged in the region of the absorber inlet. 4. The device according to claim 1 with a cross-sectional approximately triangular housing, the bilateral housing forming the triangular hypotenuse forming the heat absorber, characterized in that the storage tanks ( 9 ) fill the triangular shape of the housing ( 2 ) with a decreasing cross-section. 5. Apparatus according to claim 1 or one of the following claims, characterized in that the interconnected storage tanks ( 9 ) are designed as pressure vessels. 6. Device according to one of the preceding claims with heat-insulated storage tanks ( 9 ), characterized in that the thermal insulation ( 10 ) of the storage tanks ( 9 ) little least partially as the storage tanks ( 9 ) receiving La gerschalen are formed. 7. Device according to one of the preceding claims, characterized in that solar cells ( 14 ) for loading the pump ( 13 ) are provided on the housing on the surface facing the sun in the use position Ge.