DE2907657A1 - Water storage tank with solar heating - has circuit with by=pass path through heat exchanger near tank to avoid freezing - Google Patents

Abstract

The solar heating system, which supplies hot water to a storage tank (20), includes a flow path which by-passes the tank in cold weather, to prevent freezing. this path consists of the discharge line (21) from the heat collector panel (22), with branches (31, 32) to a control valve (V4), then to a warm air heat exchanger (33) above the tank, and back to the inlet line (26) to the panel. The tank is supplied cyclically with hot water, forming layers at different temperatures through a supply line (34), terminating in a section (37) between control valves (V1 V3), at the entry point. A tube (42) immersed in the tank delivers water from low level for further heating. Hot water drawn off by a branch line (38), downstream of the other control valves (V1, V3), is replaced by cold water through a branch line (27) at the top of the tank.

Description

Solar system for direct domestic water heating

The invention relates to a solar system for dl rek.t-t water heating with flat plate collector, storage tank, connection lines, pump control fittings, fresh water connection and boost for otherwise heated domestic water.

Systems of the type mentioned are known. You can do this because of the implemented and proposed technical facilities of the last years two different ways speak: Firstly, domestic water is directly in the collectors heated and fed into the hot water pipe network, mostly via a storage tank, on the other hand, a closed circuit is established, so that the recorded Heat must be transferred to the domestic water via a heat exchanger.

The first method is in Central European and comparable Spread given the risk of freezing in the cold season; one lets the System therefore run empty.

The second method does this by adding an antifreeze prevented, but the systems work sluggishly according to these procedures and can do not make optimal use of short parts of the sun. In addition, the investment and Operating costs are higher with the second method.

The concept of direct domestic water heating without interconnection of heat exchangers must be at least in the use of solar energy for the private Priority should be given to the budget, as the relatively small plants with their competitiveness stand and fall. You have to be uncomplicated without, among other things many Components, @@ @ @f @ rotatable and without @ref space requirement also @@@@@@ in @@ te @@@@@ r be upgradeable.

Dealt with solving the problem of direct domestic water heating DE-OS 25 25 723. U! a shutdown of the system during periods of frost In order to avoid this, a thorough emptying is also carried out, but then an air circulation with which the heat is to be transported away from the collector. The heated Air can be used for space heating. This is associated with being separated Routes for air and water and a complicated regulation for idling, air circulation, Additional line etc. must be available.

DE-OS 26 14 142 makes other disadvantages associated with the concept clear, e.g. corrosion problems as a result of ventilation as an open system. the DE-OS 26 14 142 tries to counteract the disadvantages that air and water never be exchanged, i.e. remain in a closed system. That likes It may be possible and advantageous when used purely as room heating, necessarily is a system for domestic water that goes beyond space heating, e.g. as washing water should serve, so not conceivable.

The object of the invention is to provide a solar system for direct heating of domestic water indicate when the need to idle against freezing is no longer necessary and a complete system for optimal domestic water heating to be specified by means of solar energy The system for solving the task is characterized by that to protect against freezing when falling below a minimum temperature Direct circulation to the collector via an air heat exchanger installed in the boiler room can be produced without including the memory, which is generated when the minimum Temperature can be canceled again that a cyclical, shift-wise loading of the Storage with heated water can be carried out, inden that in the collector heated water can be fed to the storage tank through an upper 7uleitung and at the same time water to be heated up from the bottom of the tank through a lower drain It can be seen - that the water to be heated up while bypassing the storage tank circulates until there is an adjustable usable temperature that can be removed from the upper supply line has reached and can then be fed to the memory, and that also during the cyclical Loading the storage tank through a branch of the upper supply line heated water Removal is possible with the simultaneous introduction of Fris.chwasser through the lower one Derivation that when the water temperature drops below an adjustable temperature On the top of the storage tank, the solar system from the consumer network by means of a temperature switch and the valve can be switched off with the connection of otherwise heated domestic water to the consumer network, and that if the temperature is exceeded, the old condition can be restored - that for the discharge of excess solar energy at the collector output there is another temperature age above which if one specifiable maximum collector outlet temperature an outlet valve for the heated Water is evident and the valve closes again if the value falls below this limit.

A system is created which has a minimum of valves and lines and their regulation is extremely pimple. The system unites Quick responsiveness to the solar supply with efficient hot water preparation and protection against both overheating and freezing. It is guaranteed that Solar-heated domestic water is automatically preferred, so that heating costs are reduced will.

The system ensures that highly efficient solar collectors are used the heat gained is also optimally passed on. Only this unit from the collector to the consumer ensures that solar systems become competitive.

For a better understanding, the invention is based on the single figure described in more detail. The figure shows a circuit diagram for a solar system for direct Domestic hot water heating - The essential parts of the system are a flat plate collector 22 with output line 21, in line 21 a temperature switch S1 for minimum Collector outlet temperature Tmin, another temperature switch S4 for maximum Collector outlet tampon Tmax, followed by a node 45 to an outlet valve Vii and a vent valve V5, at the node 45 a discharge 31 with a branch 32 to an air heat exchanger 33 with an upstream valve V4, which has a temperature switch S1 is switchable, and a branch 34 in which a temperature switch S2 for the useful temperature TNutz is arranged, a further branch 35 into a Branch 36 to the collector input 26 and a branch 37 to the storage input 23, in the branch 36 to the collector a switch S2 switchable valve V2 and a check valve V12, followed by a pump P, which can be switched by switch S1 for Tmin, and a Junction 39 from air heat exchanger 33; in branch 37 to memory 20 a check valve V3, a switchable from switch S2 for TNutz valve V1 and a junction 38 to Consumer network, including a temperature switch S3 for switching off the Solar system operated by the consumer network, shut-off valve V8, one junction 44 for otherwise heated domestic water, as well as one from the temperature switch S3 actuatable shut-off valve V9; a fresh water supply line 27 with a confluence 41 into a line 42 reaching to the memory base 24 and with a branch into the Line 43 to pump P.

The function of the system is based on distinguishable operating states explained: 1. Frost protection: Since the collector circuit is filled with tap water, it must be protected from freezing. This is done by a natural circulation that provides the necessary low amount of heat in the air in the boiler room withdraws. The frost protection is only required in the heating season, during which there is excess heat in the shark room anyway is available. If the temperature falls below Tmin, the temperature switch St switches the Pump P off and opens the valve V4 (currentless circuit status, the valves V1 and V2 are on bypass at Tmin). If the collector temperature falls below the boiler room temperature, Natural circulation begins in the collector circuit through the air heat exchanger installed in the boiler room 33. The absorbed heat prevents the collectors from freezing -22 Achieved the temperature at the temperature switch S1 by solar energy again Tmin, the Pump switched on, valve V4 closes and preheating begins. The air heat exchanger 33 is then inoperative again.

2. Preheating exceeds the temperature at the temperature switch St the set value Tmin (e.g. 20 C), the pump P switches on and the valve V4 closes Because the circuit has not yet reached the useful temperature TNutz; holds the temperature switch S2, the valve V1 is closed and the valve V2 is opened The collector circuit circulates in the storage bypass and is vented through the valve V5-. When exposed to sunlight, the entire circuit heats up evenly.

3. Loading of the storage tank Has the bypass operated for preheating Collector circuit to the useful temperature T use set on temperature switch S2 (e.g. 60 ° C), valve V2 closes and valve V1 opens The water content of the circuit is fed to the memory 20 from above. The accordingly executed Water distribution enables thermal stratification in the storage tank 20, so that cold Water is simultaneously displaced from the memory 20 in the collector circuit. To single flow through the collectors 22 has the cold water not yet heated to the usable temperature TNutz, which is why it is when the temperature switch is reached S2 switches the valves V1 and V2 back to bypass. The number of to go through Cycles until re-heating to the useful temperature depends on the irradiated Light intensity and the ambient temperature.

- - 0 The storage tank 20 is used by drawing off hot domestic water discharged through the junction 38 from above. The bottom of the storage tank flows 24 a corresponding amount of cold tap water z-u. The position of the valves V1 and V2 are not affected by this, i.e. loading and unloading are also simultaneous possible.

Even when discharging, thermal water stratification is created in the storage tank Maintain appropriate water flow. If the cold water front reaches the temperature switch 53, it switches off the solar system from the consumer network via valve V8 and the otherwise heated domestic water via valve V9. Becomes from the collector circuit If hot water is refilled in the storage tank, the temperature switch S3 switches the valves V8 and V9 again around.

5. Destruction of excess solar energy.

If the storage tank is full or there is an interruption in the collector circuit (pump defect, Power failure) and solar radiation at the same time, the temperature at the collector output rises above the value set at S2 (e.g. 50 ° C). The one attached to the collector exit Temperature switch S4 opens valve V11 when e.g. 55 ° C is reached, whereby Warm water flows out of the circuit and is replaced by cold fresh water. The check valves V3 and V12 force the fresh water even when the pump P is not running into the collector, which is initially only partially heated at S4 a-n, whereby V11 again closes. This emergency cooling cycle is repeated when the sunshine continues few minutes. The water consumption at maximum solar irradiation (1st kW / m²) per 1 m2 collector surface approx. 12 l / h. Since 54 is thermo-hydraulic on V11 acts, the entire system is protected from overheating (e.g. greater than 55 ° C) even in the event of a power failure.

Since the flow velocity in the collector is approx. 0.3 m / sec (Tube absorber), no calcium deposits are to be expected on the smooth tubes. If the water is very hard, small amounts of limescale will build up on the bottom of the storage tank Place where a flow-free space with a maintenance opening can be arranged.

Claims (2)

Solar system for direct domestic water heating P a t e n t a n s p r ü c h e 1. Solar system for direct domestic water heating with a flat plate collector, Storage tank, connection lines, pump, control fittings, fresh water connection and Connection for otherwise heated domestic water, thus not indicated e t - that to protect against freezing when falling below a minimum temperature (Tmin) a direct circuit (21,31, 32, 26,22) via one installed in the boiler room Air heat exchanger (33) to the collector (22 'without including the memory (20) can be produced which can be canceled again when the minimum temperature (T in) is exceeded, - That a cyclic, layered loading of the memory (20) with heated water can be carried out by the water heated in the collector (22) through an upper supply line (37) can be fed to the memory (20) and at the same time to the memory (20) of its Bottom (24) water to be heated can be removed through a lower drain (42) is, that the water to be heated up is bypassing the storage tank (Storage bypass 21,31,36,22) revolves until there is an adjustable one in front of the upper supply line (37) removable useful temperature (T useful> has reached and then the storage tank (20) can be fed, and that also-during the cyclic loading through the memory (20) a branch (38) of the upper supply line (37) heated water can be taken, with simultaneous introduction of fresh water through the lower drain (42), - That when the water temperature drops below an adjustable temperature at the Top of the storage tank (23) the solar system from the consumer network by means of a temperature switch (S 3) and valve (V 8) can be switched off, with the connection of otherwise heated Domestic water to the consumer network, and that when the temperature is exceeded, the old one State can be restored - that to dissipate excess solar energy Another temperature switch (S 4) is available at the collector output (21) via when a specified maximum collector outlet temperature (TmaX) is exceeded an outlet valve (V 11) for the heated water can be opened, and if the value falls below this the valve (V 11) closes again. 2. Solar system according to claim 1, g e k e n n z e i c h n e t through the arrangement and presence of the following components: flat plate collector (22) with Output line (21), in line (21) a temperature switch (S 1) for minimum Collector outlet temperature (Tmin), another temperature switch (S4) for maximum Collector outlet temperature (Tma), then a node (45) to an outlet valve (V 11) and a vent valve (V 5), at the node (45) with a discharge line (31) Branch (32) to an air heat exchanger (33) with an upstream valve (V 4), which can be switched by the temperature switch (S 1), and a branch (34) in which has a temperature switch (S 2) for the useful temperature (T Nut2) a further branch (35) into a branch (36) to the collector input (26) and one branch (37) to the storage tank input (23), in the branch (36) to the collector a switch (S 2) switchable valve (V 2) and a check valve (V 12), then one of the switch (S 1) for Tmin switchable pump (P) and one Junction (39) from the air heat exchanger (33); in the branch (37) to the memory (20) Check valve (V 3), a valve (V 1) that can be switched by the switch (S 2) for TNutz and a branch (38) to the consumer network, -in one of a temperature switch (S 3) shut-off valve that can be activated to switch off the solar system from the consumer network (V 8), a junction (44) for otherwise heated domestic water, and also one shut-off valve (V 9) which can be actuated by the temperature switch (S 3); a fresh water supply line (27) with confluence (41) in a line (42) and extending to the storage base (24) with branching into the line (43) to the pump (P).