DE3036244A1 - HOT WATER TANK FOR A SOLAR COLLECTOR - Google Patents

Description

STIEBEL ELTRON GmbH & Co. KG *** '"'*" * " * -" ·· ' 3 0362

Holzminden / Weser

9/25/1980 Act 539

Hot water storage tank for a solar collector

The invention relates to a hot water storage tank for connecting at least one solar collector with a cold water inlet pipe and hot water drain pipe in one cylindrical storage container.

Such a memory is disclosed in US Pat. No. 1,889,238 described. The memory is arranged at the top of a sloping solar collector and with connected to this via two connections. Xm solar collector heated water flows through natural convection (thermosiphon effect) into the storage tank and can store it. «It is favorable with such systems that no electrical installation is necessary and that the facility is simple. It can thus also be used usefully in such places where electrical energy is not available and where a maintenance-free structure is of particular importance is.

The disadvantage of the memory of US Pat. No. 1,889,238 is that the domestic water itself flows through the solar collector, i.e. a heat transfer medium whose properties are adapted to the Conditions of the solar collector are adapted, is not provided. In TJS-PS 1 242 511 there is a hot water storage tank described with a connected solar collector, whereby the heating of the storage tank is about a heat exchanger coil takes place through which a heat transfer medium flows. It is thus a pressure equalization possible in the heat transfer circuit. The heat carriers— snake is inconveniently arranged in the storage tank, which has a detrimental effect on the heat transfer.

The object of the invention is to equip a hot water storage tank of the type mentioned with a heat exchanger in such a way that that the heat exchange can take place under natural convection, the heat transfer on the domestic water is cheap and the storage tank is simple.

According to the invention, the above object is achieved in that a double-jacket tube in the bottom area of the storage container is arranged horizontally, on whose interior and the outer jacket, closed off from the storage tank, the connections for the solar collector are provided and that the cold water inlet line in the area of the middle of the storage tank open inner jacket opens and is directed to the inner jacket.

The heated by the solar collector enters the annulus Heat transfer medium and heats the two jackets, which give off their heat to the adjacent water zones. That Water heated in this way rises gradually upwards in the storage tank under natural convection Area of hot water drainage. When tapping domestic water, the cold water flowing in is initially the Pressed on the inner jacket, at which the inflowing cold water flows off on both sides of the inner jacket and so on the one hand there is a large heat exchanger surface, but on the other hand there is no strong turbulence in the existing water stratification brings about.

It can be seen that the structure of the heat exchanger so it is simply that an inexpensive production is possible is * The two-circuit system ensures that the heat transfer circuit is corrosion-proof and that a frost-proof heat transfer medium can also be used.

In a preferred embodiment of the invention, a side wall of the storage container also forms a wall part a pressure equalization chamber to which the annulus is connected. Thanks to the integrated pressure equalization chamber a separate installation of a pressure equalization vessel is not necessary

About the onset of the convection flow of the domestic water To favor in the storage tank, is preferably the axis of the inner jacket opposite the axis of the storage tank slightly inclined.

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Further advantageous embodiments of the invention result from the following description of an exemplary embodiment and the subclaims. Xn the Drawing show:

Figure 1 is a side view of a solar hot water storage tank,

Figure 2 is a plan view of the memory of Figure 1,

Figure 3 is a schematic sectional view of the storage container and

FIG. K shows a schematic sectional view of the storage container along the line IV-IV according to FIG.

The solar collector memory according to FIGS. 1 and Z has two solar collectors 1 and 2. These are inclined, being held at the upper edge by a frame 3 and supported at the lower edge by means of a Stutζwanne k . The line system of each of the two collectors 1 and 2 has an inlet connection 5 or 7 and one. Drain connection 6 or 8 on. On the frame 3, a storage tank 9 is arranged, to which a cold water inlet line 10 and a hot water drain line 11 is connected. The cylindrical storage container 9 is arranged horizontally.

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In the bottom area of the storage container 9, a double-jacket tube 12 is provided, the diameter of which is smaller than the radius of the storage container 9. The double-jacket tube 12 is formed by an outer jacket 13 and an inner jacket Ik . The annular space 15 between the outer jacket 13 and the inner jacket Ik is closed off from the storage container 9. The outlets 6 and 8 are connected to the annular space 15 at the top and the inlets 5 and 7 of the solar collectors 1 and 2 are connected at the bottom. The annular space 15 is connected to a pressure compensation chamber 17 via a pipe socket 16. The pressure equalization chamber 17 is formed by a side cap 18 of the storage container 9 and by a further cap 19 placed thereon.

A filling and venting nozzle 20 is also connected to the annular space 15, which through the storage container 9 is led to the outside.

The interior 21 of the inner jacket "\ k is in direct connection with the storage space of the storage container 9". As can be seen from FIG and the storage container 9 is left so that a flow of water from the interior 21 is possible upwards.

The cold water supply line 10 is led approximately to the middle of the inner jacket Ik and angled there so that the mouth opening is directed towards the inner jacket Ik.

provided with a safety valve SV and

The axis of the outer jacket 13 lies essentially parallel to the axis of the storage container 9. The axis of the inner jacket 14, on the other hand, is slightly against the axis of the outer jacket 13 or of the storage container 9 inclined. The inner jacket l4 is thus arranged rising slightly from bottom to top.

The hot water drain line 11 is in the middle of the Storage container 9 out, opens at the top and is directed upwards.

The pipe system of the solar collectors 1 and 2 as well as the annular space 15 and partly the pressure equalization chamber 17 (see. Level line 22) are filled with a heat transfer fluid. The vent nozzle 20 is closed.

After the lines 10 and 11 have been connected to the water network, the storage tank 9 is filled with water.

The function of the device described is roughly as follows:

When sunlight of the solar collectors 1 and 2 heats up the heat transfer fluid and flows under the effect of convection by the Procedures 6 and 8 at the top of the annular space 15. Because of the offset of the feeds 5 ₅ 7 and flows 6, 8 in the annular space 15 (see FIG. 3) it is ensured that the outer jacket 13 and the inner jacket l4 heat up over their entire length. When the heat transfer fluid is heated, it expands. An amount of heat transfer fluid corresponding to the expansion volume of the same creates space in the pressure equalization chamber 17 filled with air at low pressure by compressing its volume of air.

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The pressure in the heat transfer circuit only rises to a beneficial extent, even in the event that no domestic water is taken is «When the heat transfer fluid cools down, the described process runs Procedure in the reverse order.

In the course of operation it cannot be ruled out that the top Collect air bubbles in the annular space 15 The distance between the inner jacket 14 and the outer jacket 13 is large enough that this does not affect the function. Occasionally, air may collect through the vent be drained.

The jacket 13 and l4 give off heat to the water, so that this also flows upwards under the effect of convection. The inclination of the inner jacket l4 favors the flow of heat when no water enters through the cold water supply line 10. In the storage container 9 there is a Temperature stratification without turbulence.

If hot water is drawn from the line 11, then cold water flows in through the line 10. This occurs first the inner jacket l4 and then flows to both sides out of the interior 21, whereby it withdraws heat from the inner jacket 14. Turbulence of the water layer due to incoming cold water are thus avoided.

Corresponding to the function of the storage tank 9 as a hot water storage tank this is provided with a thermal insulation not shown in detail in the drawing.

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Numerous other exemplary embodiments lie within the scope of the invention. For example, it is also possible to use the solar collectors 1 and 2 on the one hand and the storage tank 9, on the other hand, to be installed in separate locations, for example on a roof or under a roof. Then, under unfavorable conditions, the convection effect is not sufficient for the desired transport of the Heat transfer medium from, a circulation pump can be provided, which, however, has an electrical connection requires.

The double jacket tube 12 can also be rectangular Have cross-section.

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Claims (9)

9/25/1980 patent claims / protection claims (1.1 Hot water storage tank for connecting at least one ^ oxar collector with cold water inlet line and hot water outlet line on a cylindrical storage tank, characterized in that in the bottom area of the storage tank (9) a double jacket pipe (i2) is arranged, on its between inner and outer jacket (i4, 13) opposite the storage tank (9) closed annulus (15) the connections (5 to 8) for the solar collector (1) are provided, and that the cold water supply line (1O) in the middle of the storage tank (9) opens into the open inner jacket (i4) and is directed towards the inner jacket (ik) . 2. Hot water storage tank according to claim 1, characterized in that that a side wall (18) of the storage container (9) at the same time a wall part of a pressure compensation chamber (17) to which the annular space (15) is connected. 3. Hot water tank according to one of the preceding claims, characterized in that the inner jacket (i4) is slightly inclined to the horizontal. 4. Hot water storage tank according to one of the preceding Claims, characterized in that the double jacket tube (12) extends essentially over the entire length of the storage container (9) extends. - 10 - 5. Hot water tank according to one of the preceding claims, characterized in that the annular space (15) Connections (6, 8) supplying the heat transfer medium open into the duct space (15) at the top., 6. Hot water tank according to one of the preceding claims, characterized in that inlet and Drain connections (5 to 8) on the double jacket pipe (12) are arranged offset. 7. Hot water storage tank according to one of the preceding Claims, characterized in that a venting connection (20) is arranged at the top of the double-jacket pipe (12) is, which through the storage container (9) to the outside is led. 8. Hot water tank according to one of the preceding claims, characterized in that the mouth of the Cold water supply line (ίο) down on the inner jacket (14) is directed. 9. Hot water tank according to one of the preceding claims, characterized in that the hot water drain line (11) to the middle of the storage container (9) is enough and is directed upwards there.