DE2628442A1 - Solar water heater - uses collection panel insulated around the edges and with internal air circulation - Google Patents

Abstract

Solar heating of water uses an absorber plate which has several transparent plates above it facing the sum with spaces between them. they are thermally insulated from the surroundings around the edge and on the back. The plates and the absorber being spaced apart from each other, form a series of flow passages. Air or other gas is blown through these by means of >=1 fan and recirculated. In its coolest state, the air passes through the outer passage. Here it is warmed and then passed over the absorber plate. Built into this recirculating system are >=2 heat exchangers, one connected to the cooler zone and the other with the warmer. The air is circulated round these and then into the cooler passage under the outer plate and back over the absorber. Heat losses are reduced. Short sunshine periods and low radiation intensities are well utilised because of short inertia times. Frost sensitivity is avoided.

Description

Device for solar heating of water

The invention relates to a device for solar heating of Water exposed to solar radiation, on the sunny side by an or several spaced apart transparent panes covered absorber plate, wherein the disk or disks at the edge and the absorber plate at the edge and on the back are thermally insulated from the environment.

It is known to control solar radiation with the help of blackened metal plates to convert in Wörme. Devices suitable for this are called solar collectors designated. So-called plates or flat-plate collectors are common. Here it is plate-shaped. large-area bodies that come from an absorber, a pipe system for the heat transfer medium, a thermal insulation and a cover. These collectors work something like this: The Short-wave solar radiation hits the covers, is partially reflected there, partially let through and reaches the absorber. There is solar radiation converted into heat. However, as it heats up, the absorber radiates heat again according to Wien's law of displacement in the form of longer-wave @ infrared radiation which is the cause of considerable losses if there is no solar-side insulation. Further losses arise from convection and conduction. In detail increase the losses due to radiation with the fourth power and those of the convention and the heat conduction with the simple power of the respective temperature difference between the collector surface and the ambient temperature. It is obvious that Great efforts are made, especially to reduce the radiation losses in dcii To reduce collectors. They amount to about @ 0 to 70% of the total losses. One Reducing radiation losses has recently been achieved through the use of so-called more selective layers as a black layer for the absorber. This is it mostly around electrolytically applied, very thin metal layers, for example made of black chrome. These reduce radiation losses by up to 90%. Similar good ones Results can also be achieved by applying infrared radiation ungsreflekt i erenden layers on the opposite sides of the covers from the absorber. Suitable for this are z.

B. Layers of indium oxide or zinc oxide. The disadvantage is that the service life of these coatings is either limited or the light transmission in the case of infrared reflective layers decreases by up to 25 ° ZS. A disadvantage is also the high price and furthermore that the coatings do not have a significant impact on the lonvection and heat conduction losses. Rather, the latter is insulated through the use of double glass panes, or more recently also through use of vacuum tubes, which by coating with indium oxide also reduce are equipped with radiation losses.

The vacuum insulation process is relatively expensive and elaborate apparatus, which, although they are an optimal containment of all on thermal radiation, Convection and heat conduction-based losses represent themselves only in the economy must have proven their worth in calibrated use. Another very significant disadvantage of the for The collectors used to generate domestic water are their regulation. This happens usually in such a way that the temperature of the heat transfer medium is controlled by thermostats, a circulating pump that feeds the heat transfer medium when a specified temperature is reached transported through the absorber, switched on or off. Other systems are working with differential temperatures compared to the heat storage, d. H. the heat transfer medium is only after reaching a certain temperature difference between the storage tank and absorber switched on These methods of regulating the collectors are very uneconomical and worsen the efficiency of the collectors, because in our latitudes the solar energy accumulates very irregularly.

The radiation intensity often changes within a minute of around 800 to 1000 s / qm in clear sunshine down to 50 to 100 W / qm Clouds or brief rain. Furthermore, the intensity of the on the collector incident radiation depending on its position and angle of inclination to the sun. This changes the conditions with a permanently installed collector - the Usual installation method - continuously throughout the day. The higher the temperature is specified for a collector, the worse it gets in cloudy weather seirnell changing irradiation intensities the efficiency, as a result of the mostly considerable sluggishness of the collectors (response time) short periods of sunshine can no longer be recycled at all. The inertia of the collectors is conditional by taking into account the weight of the absorber and the heat transfer medium the specific heat. For example, it takes about 50 l per square meter of collector surface and a temperature specification of approx. 50 ° C with an irradiation intensity from approx. 800 W / sqm 4 to 5 hours until the heat transfer medium has reached the specified temperature reached and the circulation pump can be switched on. Go in this time significant amounts of heat are lost through radiation, conduction and convection. remedy can be achieved by using light metals or plastics in the manufacture of the Absorber, as well as smaller dimensioning of the pipe diameter for the Heat transfer medium be created, albeit because of the increase in pipe friction losses and the The higher energy consumption of the circulating pumps caused by this, but only a small constructive one Leeway is given.

Another problem that arises from the fact that the heat transfer medium during sunless periods, especially in winter and at night, cools down so much that if it freezes, one counteracts that the heat transfer medium falls below given temperatures or mixed with antifreeze. Against it results long periods of sunshine, insufficient storage capacity and lower Withdrawal or, if the circulation pumps fail, there is a risk of steam formation in the heat transfer system. This requires the installation of safety valves, pressure monitoring devices and the like

The invention is based on the above-described disadvantages to fix the known collectors. Through the 13rfindung the heat losses reduced, short-term sunshine periods and low irradiation intensities well used due to the short response time and the sensitivity to frost eliminated which facilitates the very desirable broad application of solar technology would.

The solution to this problem consists in the wesen union according to the invention that through the absorber plate, the transparent | pension (n) disk (s), which are arranged offset from one another or one on each side with respect to the opposite disc or plate offset slot or a | To-have opening, and the cjußereil insulation a multiple on top of each other running channel system is formed by which air or similar gases is circulated by means of at least one fan such that the air or the like. in the cooled state, the outermost one, which runs under the cover on the sun side Channel strand fed and after heating to the transpareiiten Sciieibcn and the Absorber plate over the | The duct section located on the absorber plate is discharged will.

Instead of water, air is used as a heat transfer medium. Thereby form the black absorber sheet and the sun-side covers made of infrared radiation absorbing material normal window glass as heat exchange surfaces an IC-channel running in opposite directions, in which the air circulates.

The circulation is through. causes a l: linen fan, whereby the air through at least two finned tube heat exchangers of different Temperature level is passed.

The secondary heat transfer circuit is operated as usual with water, the heat exchangers exposed to air from the outside with a heat accumulator are connected by leads. The heat accumulator has different temperatures on, the heat exchanger with low temperature level with the lowest Part of the error memory is connected, where the colder water is accumulates and the heat exchanger with a higher temperature level with the upper part of the heat storage tank, where the water with a higher temperature is located.

The air is circulated in such a way that it will after leaving the heat exchanger low temperature level flows along the sun-sciigen cover and keeps this at a relatively low temperature of approx. 20 to 30 ° C. After that, the Air with global warming by the glass plates or the like. In iraro ts trailea-absorbing material partially directed channel system and redirected. Eventually the air reaches the absorber sheet, where it - bercits preheated - further heated depending on the radiation intensity and air velocity. Then it gives its heat in the heat exchanger with the higher temperature level to the water circulating here. The regulation responds in several stages. During commissioning or when there is less irradiation, only the heat exchanger works lower temperature levels. This increases the temperature level of the colder Tcil of the heat storage tank raised. If the air temperature rises after the Collector or in the case of greater radiation intensities, the heat exchanger is also used higher temperature level put into operation, whereby the already preheated water from the colder part of the heat storage tank further warmed up and set to the specified Temperature level is brought. Thanks to the system's at least two temperature levels the entire solar energy that hits the collector is used in the best possible way, provided the absorber reaches a temperature of approx. 30 ° C, which is usually the case during the day even with heavy cloud cover and rain.

If there is a predominance of low irradiation intensities, For example, mornings and evenings or very woolly weather can water up to Temperatures of about 30 ° C can be generated with the best collector efficiency, which very advantageously raised to the service water level of approx. 450C by means of heat pumps can become, or with the increase of the radiation intensity easier as a result of the Preheating can be brought to the specified temperature level. Through the Use of air in the primary transfer circuit and the formation of the circulation channels of light rays or infrared rays absorbing material, as well as the arrangement of heat exchangers in at least two temperature levels will have the following advantages achieved: The inertia (loading time) of the collector is minimal, since the primary System does not contain water or the like. Heat transfer media in plate-shaped or tubular Metallic collectors, which are usually very heavy, are warmed up got to. Due to the different temperature levels, practically every irradiation intensity is achieved in connection with the temperature-stratified heat storage with optimal efficiency utilized. Due to the low temperature of the run along the outer cover Air keeps the outside temperature of the collector relatively cool, which reduces heat losses (Radiation, Convection, heat conduction), which all increase with the temperature difference, minimized will.

The heat exchange between those circulating in the duct system Air and the water in the heat accumulator can abcr - otherwise in principle same mode of action - also provided so that the circulation of air od. The like by means of insulated pipelines over the partially a heat exchanger for the air equipped heat storage is conducted.

The heat exchanger in the heat accumulator penetrates the temperature zone with the lowest temperature and at least one temperature zone higher, preferably the highest temperature; Of course, several corresponding heat exchangers can also be used be provided in the various temperature zones.

Since in this embodiment the heat exchanger (or

the exchanger) for the air is provided directly in the heat storage, so no cooling water from the heat storage to the collector or the heat exchanger installed there (or installed heat exchangers) to be brought up /, so you save the corresponding pipelines and pumps.

It should be mentioned that this consists of the front and rear disks and panels in a simple manner formed channel system also advantageously used can be achieved if, as before, mostly water is used as a heat transfer medium then the specific vortices which rest on the air as a heat transfer medium of course not.

The material used for the manufacture of the collectors, such as panes of glass, Absorber sheets, insulating panels, can be mass-produced cheaply. The Kollelctorcji according to the invention are because of the collapse of Piiren or the like. very easy for ciii liquid heat transfer system. The weight can be increased by using can be further reduced by using foils instead of panes of glass. Dics allows great. Flat collectors up to 10 and more square meters, eliminating the need for side insulation and assembly is made easier. This also applies to costs for the fans and the heat exchangers, which are less important, the larger the area of the collector unit. The system does not require any safety devices since the formation of steam is practically impossible.

The risk of leaks is low. There is no risk of frost for the heat transfer medium of the secondary circuit, as the heat exchangers are frost-protected can be accommodated, for example under the collectors in the attic.

The previously known collectors with air as the heat transfer medium z. B. von Denovan-Bliss, Löf, Francia all work according to a different principle Use of fresh air as a heat transfer medium without primary or secondary circuits and without the proposed use of different radiation intensities by means of heat carriers of different temperature levels through connection with a Heat storage.

The extraction of low-temperature heat is particularly important at Inclusion of heat pumps in the system. as a result, Icannot use Cooling towers or without inflow of cooling water from rivers, lakes or from the groundwater a very economical operation through the use of low-temperature energy the collectors for the evaporator system of the heat pump are made possible. Included it is recommended to place the evaporator in the lower part of the heat storage tank and the condenser in the upper part of a double jacket boiler or the like.

The cover of the collectors according to the invention can be known Way done by double panes of glass or plastic sheets. The backside the absorber sheet can be thermally through non-combustible insulating jacket or plastic foams to be isolated. When the heat storage device is fully charged, for example in summer, when you are absent the resident of a house, or during long periods of sunshine, can circulate for the air are used in connection with the outside air through flaps, whereby the fan in connection with a thermostat the overtemperature protection causes. To achieve a better heat transfer, the absorber sheet can be corrugated or be ribbed.

A common plate collector and examples are shown below of the invention with reference to schematic drawings: Fig. 1 shows a plate collector simplest execution, Fig. 1 shows a plate collector of the simplest Execution, wherein the absorber plate is denoted by 1, the water ducts for the transfer of thermal energy with 24 the back and side insulation for insulation against heat conduction and convection losses with 3 and the cover with 4.

In the schematic drawing of FIG. II, this is designated as a whole by 1 Absorber sheet on the back and sides with a gap to form the cincs air duct 9 isolated by insulating layers 8. The channel system is formed by the absorber plate 3, the infrared ray absorbing glass sheets 2 and 3, the cover 4, as well as e as mentioned above by the insulation 8.

In the channel system heat exchangers 5, 6 are arranged, which through Pipelines 5a, 5b and 6a, Gb, are connected to a heat accumulator 12. The air circulation is caused by a fan 7. It could also be used for every heat exchanger a separate fan can be provided, which increases the operating safety because if one fan fails, the other will still work. Cheap is that the absorber top plate is flowed around on both sides by the air.

The circulation of the water between the heat accumulator 12 and the heat exchangers 5, 6 cause circulation pumps 19, 20. The flaps provide overheating protection 14 represent, which if predetermined temperatures are exceeded or shutdown of the collector can be opened. To be on the safe side, the heat accumulator 12 is provided with a Expansion vessel 13 provided.

In the schematic drawing Fig. III @@@ the system in connection shown with a heat pump @ @@ @ collector 1 to 7 transfers the circulating Air the heat energy in two stages to the heat exchangers 5, 6. The heat is by water via the lines 5b, 6b to the heat accumulator 12 in two temperature levels depending on the irradiation intensity.

During long periods of bad weather, the heat pump is 15 switched on, which takes the energy from the heat accumulator 12 through the Evaporator 14 the hot water level in the boiler 17 through the condenser 16 to about 60 to 70 ° C.

The throttle valve of the heat pump system is designated by 18.

In winter, additional heating 21 can reduce the heat deficit in our Bridging widths.

Fig. IV also shows schematically a further variant of the invention Device, especially the assignment of the individual parts of the device to the individual parts of the house can be seen. The collector with the duct system 1, 2, 3, 4 is built into the roof of the house. They're in the attic Heat exchangers @, @ installed, those for cooling the circulated through the duct system Air water is supplied from the heat accumulator 12, as described from different temperature zones. The heat accumulator extends essentially over the entire height of the - single-storey indicated - house, from the bottom to the Attic. The temperature stratification is favored by this great height.

Claims (1)

P a t e n t a n s p r ü c h e 1. Device for solar heating of water exposed to solar radiation, on the sunny side by an or several spaced apart transparent panes covered absorber plate, where the disc resp. Panes on the edge and the absorber plate on the edge and on the back against the surroundings are thermally insulated, characterized in that the absorber plate (1), the transparent pane (s) (2, 5, 4). which are offset against each other are or on one side one each with respect to the opposite disc or plate have an offset slot or opening, and the outer insulation (8) a multiple superposed channel system is formed through which Air or similar gases are circulated in this way by means of at least one fan (7) is that the air od. Like. In cooled State to the extreme @ under the sun-side cover (4) running duct strand fed and after Heating on the transparent panes and the absorber plate via the one on the absorber plate (1) located sewer system is discharged. 2. Apparatus according to claim 1, characterized in that the iii Channel system or at least two heat exchangers (@, @) connected to it are, of which @ner (5) with the colder temperature zone and at least one further (6) with the warmer temperature zone of a water or the like. Containing heat storage (12) are connected by pipelines, and that those than the one with the colder water Od. The like. Acting on the heat exchanger coming air first to the outermost, under the sun-side cover (4) running ductwork is fed and after Warming your heat energy to the second or further heat exchanger (6), in which the water coming from the warmer temperature zone of the heat accumulator or the like. Circulates, releases. 5. Apparatus according to claim 1, characterized in that the circuit the air or the like by means of insulated pipelines via one with at least one Heat exchanger for the air or the like. Equipped heat storage is routed, wherein the heat exchanger penetrates different temperature zones of the heat accumulator or in corresponding several heat exchangers is divided. 4. Apparatus according to claim 1, 2 or 3, characterized in that that the transparent panes (2, 3) and the cover (4) made of window glass or Plastic foils exist. 5. Device according to Weii at least one of claims 1 to 4, characterized geliennzeiclmet that the blackened absorber plate (1) made of steel, light metal or plastic. 6. Device according to at least one of claims 1 to 5, characterized characterized in that the blackened absorber plate to achieve a better one Heat transfer has a corrugated or ribbed surface. 7. Device according to at least one of the preceding claims, characterized in that the heat exchangers (5, 6) air-side thermostats are assigned through which, depending on the temperature of the circulating in the sewer system Air the water supply from the different temperature zones of the heat storage is supplied or discharged to the noise exchangers. 8. Device according to at least one of the preceding claims, characterized in that a heat pump (15) is assigned to the heat accumulator (12), whose Verdam «grant (14) is located at the bottom in the colder zone of the heat accumulator and its condenser part (16) in the upper part of one connected to the heat accumulator Boilers (1g) is arranged. 9. Device according to at least one of the preceding claims, characterized in that for controlling the temperature stratification in the heat accumulator in the return lines, which come from the heat exchangers (5, 6), temperature regulators are arranged that the water depending on the temperature is relatively warmer or colder Feed part of the temperature zones.