NL7909122A - THERMALLY INSULATED HEAT STORAGE DEVICE. - Google Patents

Description

a

* r 70 3T91

Hit el: Thermally insulated heat storage.

The present invention relates to a thermally insulated heat storage device for heating water systems and / or systems for water that is consumed.

It is known that a great deal of effort has recently been made to recover energy in the form of heat by means of solar collectors or heat pumps. Independently of this, efforts are constantly being made to improve the efficiency of existing coal, gas and oil heating plants. to improve.

In the case of heat recovery by means of solar • j η # collectors, it is very disadvantageous that in our climate the solar radiation is very irregular and, in addition, relatively weak in winter, so that with solar collectors especially when one uses a lot of energy consumed, ie in winter, not much heat can be continuously extracted. It is therefore all the more important to extract and store as much heat as possible in the case of solar radiation, particularly in winter, in order to be able to move forward over longer periods, during which the sun does not shine. This generally does not work, because the storage capacities are too small. normally hot water boilers, which are heated by means of the circulating solar colloctor liquid, only have a capacity of 300-500 liters, that is to say that this amount of warm water cannot be used for long, especially if the undefeated heat is not only for heating the water that is used, but additionally or only wanting to use it for heating purposes. In the case of coal, gas and oil heaters, great efforts are made to control technology using external thermostats. thermostatic valves located in the heating system, by increasing the efficiency of the time relays for the boiler after-change and the like.

However, it is disadvantageous with these heaters, in particular with gas and oil heaters, that because of the relatively small volume of the boiler, the burner switches on and off at relatively short intervals, so that the burner always burns for short periods, causing a greater loss of energy.

Furthermore, electric storage devices are known which use the inexpensive night power and store the heat in relatively small volume units. These storage units thereby heat up to very high temperatures, which not only causes special heat insulation problems, but also problems with regard to a rational and sensible removal of the stored heat.

The object of the invention is therefore to provide an environmentally friendly heat storage device, which on the one hand makes it possible to obtain the heat recovered by solar collectors or heat pumps or the like, with which only relatively small temperature attempts can be achieved in the heat storage device. , which, on the other hand, makes it possible to usefully increase, or make meaningful for the first time, the efficiency of coal, gas and oil heating, as well as other types of heating.

This object is achieved according to the invention by the use of a thermally insulated heat storage device, which as heat storage medium contains water and / or another environmentally friendly liquid or an easily melting substance, is correspondingly large in size and partly or wholly for The heat radiation reflecting coating or a reflecting foil coating, preferably a coating of highly polished aluminum foil, can be seen.

The invention therefore relates to a heat-insulated heat storage device for the heating water systems and / or systems for water to be used, characterized in that the heat-storing medium contained therein contains water and / or another environmentally friendly liquid or a an easily melting substance is that the storage capacity is correspondingly large, that the storage device is wholly or partly provided on the inside with a heat-reflecting coating or a reflective film coating, preferably a coating of highly polished aluminum, and provided with devices for supplying and releasing heat.

According to the invention, water is particularly preferred as a heat storage medium, because it is easy to obtain and is particularly environmentally friendly. Instead of water, however, it is of course also possible to use other liquids, for example glycerine, optionally mixed with water, or oils, such as, for example, scraffine oil or silicone oil. On the other hand, however, it may also be advantageous to use as a heat storage medium according to the invention a substance which, while solid under normal conditions, melts already at relatively low temperatures. These kinds of substances include, for example, hard paraffin with melting points between 50 ° C and 62 ° C, waxes, low molecular weight inert polymers, as well as alloys with a very low melting point, such as Woods alloy (melting point: o0 ° C to 70 ° C ). The heat storage effect is increased by such low-melting substances, because additional energy is required for melting. For example, if heat is supplied to hard paraffin, its temperature will continuously rise to its melting point. After that, its temperature does not rise for a longer period of time because all the heat energy supplied is used for melting. Only when all hard paraffin has melted does it become warmer. This amount of heat required for melting is called melting heat. When the substance cools, this heat of fusion is released again in the form of heating heat in addition to the actual cooling.

The storage capacity of the heat storage device depends on the one hand on the properties of the heat storage medium used and on the other hand on the amount thereof. Preferably, the storage capacity is so great that the stored heat without additional heating is sufficient to provide a normal household with the usual amount of hot water for a few days.

Since according to the invention as water storage medium 7909122 * u is particularly preferred, the heat storage device preferably has a volume of at least 1500 liters, in particular from 5000 liters to 15000 liters, and has preferably a columnar, in particular cylindrical, perpendicularly arranged form. The inner diameter of such a hollow cylinder 5 is preferably about 0.8 meters to 2.0 meters at a height of about 3 to 5 meters. The drum shell, as well as the bottom and the lid can consist of any suitable material, which - if it is not automatically thermally insulating by itself - has an additional thermal insulating layer, the thickness of the insulation layer depending on the X value. (heat target value) and is so thick that practically no heat losses occur due to the jacket of the container, the bottom and the lid. The thermally insulating layer preferably consists of a polyurethane foam and has a thickness of about 15 cm. The thermally insulating layer can either form the heat storage device directly as a self-supporting element or the insulating layer is applied to the wall of the container including the bottom and the lid on the outside or inside or placed between corresponding formwork. The walls of the heat storage device can consist of metal, plastic or concrete rings. The same goes for the formwork. In accordance with the invention, for example, concrete rings arranged one above the other are advantageously used, which are centrally surrounded by concrete rings, the diameter of which is preferably 30 cm larger than the diameter of the inner concrete rings. The interspace between the concrete rings is then foamed on site with polyurethane foam, the filling with foam preferably being carried out step by step, ie depending on the height of the concrete rings, one or two inner concrete rings and correspondingly many outer concrete rings are placed and the intermediate space is filled with foam before the next concrete rings are installed one above the other. Of course, instead of the outer concrete rings, corresponding rings of metal or plastic can be used, or only the outer rings of concrete and the inner rings of metal or plastic. Naturally, the tin and outer rings can also consist of metal or plastic at the same time. Moreover, the filling with foam does not have to take place on site, but the heat storage device can be delivered ready for use.

However, as has already been mentioned, the cylinder jacket, the bottom and the cover of the heat storage device can also be designed as self-supporting elements, these elements possibly being held together by additional auxiliary members. For example, the cylinder jacket may consist only of polyurethane foam, in the form of a tube, or may consist of tubular rings arranged in a trembling manner, which correspond in construction to the concrete rings, or consist of two half shells or a number of longitudinal segments of a cylinder. . The half-shells or the longitudinal segments of the cylinder either have a length corresponding to the desired height of the heat storage member, or they are dimensioned to provide the desired height by placing them one above the other. In order to allow superimposing without shifting, the pipes, the tubular rings, as well as the half shells and the layer segments at their 20 foot and possibly head ends have correspondingly shaped groove or spring-shaped projections, as are customary with concrete rings .

Preferably, the longitudinal segments of the cylinder are further shaped such that the inner and outer surfaces have an equal radius of curvature. With the same radius of curvature, the cylinder longitudinal segments can be placed one above the other in a space-saving manner and protected against damage during transport, without the corners being exposed to any damage.

The half-shells preferably also have grooves and springs or corresponding protrusions or recesses on their longitudinal edges 30, while this is not necessary for the cylinder longitudinal segments, because they are formed on the longest side thereof according to the principle of vaulting stones lie against each other. The position of the side surfaces of the longitudinal segments 35 is selected in such a way that the theoretical extension of the side 7909122 4 «*» β surfaces passes through the longitudinal axis of the cylinder.

The half-shells, respectively the cylinder longitudinal segments, are preferably held together by steel hands, which are screwed together at the ends thereof, for example, in the manner of hose clamps 5, or by concrete rings placed one above the other.

The columnar, in particular cylindrical, shape and the perpendicular arrangement are therefore preferred, because this ensures that the hot water always collects in a relatively small space at the surface, from which it is either extracted or where the heat is delivered to one or more heat exchangers in which the water to be consumed and / or heating is heated.

The heat storage device need of course not only have a columnar or cylindrical shape and be arranged perpendicularly, but it can also be placed horizontally or in the form of a pyramid, a cone, a block or a cube, wherein then, however, a pyramid-shaped or hemispherical or a similarly designed extension piece must be arranged on the container, which ensures that the hot water can always collect in the space which is relatively small due to these elements.

The surfaces which form the inner surfaces of the heat storage device are preferably covered with aluminum foil, in particular with a highly polished aluminum foil. In accordance with the invention, for example, the half-shells, or the cylinder longitudinal segments, can be manufactured continuously as a sandwich element and the outer layers consist of aluminum foil and the core of polyurethane foam. It is hereby noted that for the feature according to which the heat storage device is wholly or partly provided on the inside with a covering layer reflecting the heat radiation or a reflecting foil coating, preferably a coating of aluminum foil or the like, not only together with the heat storage device according to the invention, protection should be provided, but it should also be protected as a separate element for heat storage devices of a different design, for example for smaller hot water boilers with a capacity of 300 to 500 liters. turn into.

In cases where the insulating housing of the heat storage device is not watertight or susceptible to corrosion, a bag of foil material of such dimensions that it is attached to the bottom is mounted in the heat storage device at the top end of the cylinder-jacket. and the inner wall of the cylinder comes to rest. When such a foil bag is used, it can also take over the function of the heat-reflecting coating, in particular if the foil bag 10 ointment is formed from a heat-reflecting material, or with a heat -reflective layer is covered.

Because of the size of the heat storage device which is preferred according to the invention, these are preferably used, for example in the case of detached houses or two-family houses, outside the house, preferably in the ground. In many cases, cesspools still present can be 'converted' into heat storage facilities according to the invention.

According to a preferred embodiment according to the invention, the cylinder jacket, the bottom and the cover of the heat storage device consist of polyurethane foam, this preferred embodiment will be explained in more detail below with reference to the drawing, in which: 1 is a longitudinal section of a preferred embodiment 05 of the heat storage device according to the invention, the cylinder jacket, the bottom and the lid of which consist of polyurethane housing, the cylinder jacket 2 being composed of cylinder longitudinal segments 5, which in the following Figures U, 5 and 6 are shown in cross section. The cylinder hose 3 segments 5 are covered on the inner and outer sides with aluminum foil (not shown in the figure}, so that the inner walls of the cylinder jacket 2 can reflect the heat. Preferably, the inner surfaces of the bottom 3 and the cover k are also covered with aluminum foil .

The filling height of the heat storage device is indicated by "h" 35 and the inner diameter by "i". The heat storage device is filled 7909122 ί 8 with water 6. Preferably below the water surface and at the bottom of the heat storage device heat exchangers fitted together with their supply and discharge pipes are not shown The supply pipe terminating in the air cushion T with the inlet opening 8 and the discharge pipe terminating in the water slightly above the bottom with the suction opening 9 form the supply and discharge pipes for a special embodiment according to the invention, which will be discussed in more detail below together with a solar collector as a heat source.

FIG. 2 shows an enlarged longitudinal section of the top end 10 of the cylinder jacket 2 with the edge 11 of the lid U, which is connected to the top end 10 of the cylinder jacket 2 by lid screws 12, with elastic sealing rings 13 connecting hermetic sealing is obtained. The fastening 15 1 of the foil bag 15 is schematically shown in longitudinal section at the top end 10 of the longitudinal segment 2.

Fig. 3 shows in an enlarged longitudinal section the bottom end 16 of the cylinder jacket 2 provided with an all-round spring 18 ', which engages in the circumferential groove 17 of the bottom plate h 20.

Fig. k shows in cross section Ed: cylinder longitudinal segment 5 assembled into a cylinder jacket, the inner surfaces of which have a smaller radius of curvature than the outer surfaces, the radius of curvature of the inner surfaces being directed to the desired inner diameter i of the heat storage device and the radius of curvature of the outer surfaces are oriented to the desired wall strength of the cylinder jacket 2, which also has a circular shape in cross section.

Fig. 5 is a sectional view of the cylinder longitudinal section and 5 assembled into a cylinder jacket 2, the surfaces of which have a circular cross-section, while the outer surfaces give a wave-shaped, curved circular arc, because the radius of curvature of the inner surfaces is equal to the radius of curvature of the outer surfaces.

Fig. 6 shows perspective longitudinally spaced segments 5 according to FIG. 5 * 7909122 * 9

Fig. T shows a longitudinal section through a known concrete ring with the diagrammatically shown circumferential projection 21 and the corresponding circumferential recess 22, thereby allowing the placing of concrete rings on top of each other without any risk of shifting? is.

The following properties are still important with regard to the various embodiments of the invention.

Preferably, above the heat storage medium o is a gas cushion 7, which preferably consists of air or an inert gas, for example nitrogen. The gas cushion is hermetically sealed from the outside air in the usual manner and is dimensioned such that its volume is capable, under normal circumstances. buffering the pressure increase occurring when the water storage medium 6 is heated. On the other hand, however, it can also be advantageous if the gas cushion is not hermetically sealed from the outside atmosphere. but is connected to it. In this way, a simple pressure equalization in the system can be obtained, provided that the connection to the outside atmosphere is designed in such a way that larger evaporation losses are avoided. The way in which such a connection has to be made rotten to the outside atmosphere is known to the skilled person. It goes without saying that in a special embodiment of the invention it is also possible to omit the gas cushion completely, but it is then advisable to arrange a pressure equalizing vessel customary in the heating technique in another location. Furthermore, it is possible for the heat storage medium 6, for example the preferred water, to be placed under a pressure corresponding to the pressure prevailing in the water pipe. On the other hand, it is of course also possible to connect the heat storage device to the water pipe via a corresponding pressure reducing valve. This embodiment will be chosen in particular if one wants to consume the water heated in the heat storage device directly as hot water.

The devices for supplying heat are preferably arranged a little above the bottom of the heat storage device, because in this way it is achieved that the hot water is contained in the upper part of the heat storage device. the heat storage device collects and the cold water collected at the bottom of the heat storage device is always heated. The devices for supplying heat are, for example, a heat exchanger which is arranged at the bottom of the heat storage device and is fed by the circulating water, which is heated, for example, in solar collectors or in heat pumps. In accordance with a particularly preferred embodiment of the invention, the water in the heat storage device can be pumped out at the bottom and passed directly through the solar collector or through the boiler of an oil, gas or coal burner and at the top again. be supplied to the heat storage device. Such an embodiment will be described in more detail below, together with the use of a solar collector.

In many cases, however, it can also be advantageous if the medium contained in the heat storage device is heated by means of electric energy, which is cheaper to obtain in particular during the night hours. For this purpose, an electrically heated heat source, for example one which is comparable to a large electric immersion heater, is located at the bottom of the heat storage device.

Under the surface of the heat storage medium 6, the heat-emitting devices, i.e., oyer-like heat exchangers, are preferably arranged, through which the consumable and / or heating water is passed and warms therein.

In an efficient arrangement, two corresponding heat exchangers are arranged one above the other or next to each other, one water exchanger passing the water intended for the consumers and the other the water intended for heating purposes.

In the same way that the water serving as heat storage medium can be heated directly in the solar collector, the stored water can also be passed directly through the heating body of the heaters or through the underfloor heating. The same applies in the case already mentioned, that one wishes to immediately use the warm water, which has been unbeaten in the heat storage device, as warm water.

Sen. a particularly interesting application of the heat storage device according to the invention consists in the use in combination with a solar collector, whereby a solar collector heating is obtained, which essentially consists of a solar collector, the heat storage device according to the invention, recirculation pipes, which make it possible to circulate the coliector liquid through the solar collector and the heat storage device in a cycle, and the actual heating body - or system for the water to be consumed - exists. This combination is characterized in that; the thermally insulated heat storage device 1 has a content of at least 1500 liters, and on the inside is wholly or partly provided with a cover layer reflecting the heat radiation or a reflective foil coating, preferably a coating of aluminum foil or the like, which colloid liquid is not passed through the heat exchanger located in the heat storage device 1, but through the heat storage device 1 itself and that the water serving for heating the heating bodies or the water to be consumed warmly by a water contained in the heat heat exchanger 1, the content of which is dependent on its purpose, varies in that the heat storage device 1 contains a gas cushion 7 above the colloctor liquid to be circulated, so that the heat storage device is so designed, that the gas cushion 7 is located above the heat exchanger, which is so indicated in the heat storage device 1 During the operation of the solar collector, it is caused to be slightly below the water surface 6, which is located in the lower part of the heat storage device 1, preferably at the bottom, an extraction opening 9 and in the upper part of the heat - storage device 1 has a supply opening 8 for the colliery liquid, the supply opening 8 terminating in the upper part of the gas cushion 7, and that the solar collector is placed such that during the operation of the solar collector the collier liquid contained therein after the Switching off the circulation pump 7909122 / * ► 12, which pumps the solar fluid around, can run out of the solar collector and the corresponding recirculation cycles through the inlet opening 8 or the extraction opening 9 in the heat storage device 1.

The essence of the invention with this solar collector heating can therefore be seen in combination of the heat e-storage device, the air cushion and the deflation of the solar collector when the pump is stopped, the deflation of the collector only when the pump is stopped. it can then be obtained when one works with the aforementioned air cushion. This air cushion therefore has two functions in this case, on the one hand enabling the solar collector to deflate when the pump is not in operation and, on the other hand, as a pressure buffer, because during heating of the inland water at a temperature of approximately 20 - 25 ° C up to 60 ° C 15 non-negligible pressure differences occur.

Preferably, the gas cushion 7 located in the heat storage device 1 is connected via a pipeline to the highest point channel in the solar collector, via a valve located at the solar collector, which valve switches off when the solar collector is switched off. circulation pump, ie when the internal pressure is lost, opens and thereby allows the collector liquid to leak out of the solar collector The gas cushion 7, as already mentioned, is an air cushion or an inert gas cushion, for example a nitrogen cushion, where under normal circumstances, the volume is selected so that it is capable, on the one hand, of buffering the pressure increase occurring in the system when the collector liquid is heated and, on the other hand, at least so large that it is present in the solar collector and in can replace the regeneration pipes during the circulating collector liquid The channels in the solar collector, through which the collector liquid circulates, are n is preferably placed at an oblique angle such that the collector liquid can flow back through the inlet opening -3 as well as through the suction opening 9 in the Harmte storage device 1 when the circulation pump is switched off.

7903122

Claims (18)

13. C0NCLÜSI2S: Thermal, insulated heat storage device for heating water systems and / or systems for consuming water, characterized in that heat storage medium (6J water and / or another) just present in the heat storage medium (1) environmentally friendly liquid or an easily meltable substance is that the storage capacity, i.e. the content of the heat storage device (1) is correspondingly dimensioned, that the heat storage device (1) is wholly or partly on the inside. the heat radiation reflective coating or a reflective film coating, preferably a highly polished aluminum foil coating, which has the heat storage device (1) for supplying heat and releasing heat. Heat storage device according to claim 1, characterized in that it has a capacity of at least 1500 liters. 3. Heat storage device according to claims 1 and 2, characterized in that it is axxi-shaped, preferably cylindrical and arranged perpendicularly. Heat storage device according to Claims 1 to 3, characterized in that it has an inner diameter (i) of 0.8-2 meters and that the cylinder jacket has a height (h) of 3 -5 meters on the inside. Heat storage device according to claim 1 - k, characterized in that the cylinder jacket (2) as well as the bottom (h} and the cover (3) are made of a chemical, insulating material, preferably a foamed plastic, in the especially a polyurethane hard foam, it is recommended that the wall thickness in the case of polyurethane hard foam is preferably 15 cm, and that the inner surfaces of the jacket, of the bottom and of the cover are coated with a highly polished aluminum foil. Heat storage device according to claims 1 to 5, characterized in that the cylinder jacket (2 ^ of the hot water storage device (".}) Consists of a tube or of pipe rings placed one above the other, or of two half shells or a number of cylinder longitudinal sections, 7909122 These either provide a length of nets which give the desired height of the heat storage device or provide the desired height by placing them together. Heat storage device according to claims 1 to 6, characterized in that the inner surfaces (19) and the outer surfaces (20) of the cylinder longitudinal segments. (5) have the same radius of curvature (r). Heat storage device according to Claims 1 to 7, characterized in that the pipe rings which are mounted one above the other and the cylinder longitudinal segments are connected to each other via a groove (17) and a spring (18 '). Heat storage device according to Claims 1 to 8, characterized in that the drum shell (2) of the heat shells (1) forming half-shells or longitudinal segments (5) by steel hands, which are preferably at the ends on the hose-15 'clamps are screwed together, or held together by concrete rings placed one above the other. Heat storage device according to claims 1 to 9, characterized in that the thermally insulating layer of the bottom plate (h) and the cover plate (3) of the heat storage device (1) consists of the same material as the cylinder jacket ( 2) and has the same thickness. Heat storage device according to claims 1-10, characterized in that the heat storage medium (6) is contained in a foil bag (15 ') or a. foil Bladder Located against the inner walls 25 of the heat storage device, where the foil bag or foil bladder can be provided on the inside with a heat-reflecting layer. 12. Heat storage device as claimed in claims 1-11, characterized in that the foil bag (15) or the foil bladder consists of a plastic foil, which is covered on the inside with a highly polished aluminum foil. Heat storage device according to claims 1-12, characterized in that in the heat storage device (1) there is a gas cushion (7) above the heat storage medium (6), preferably from air or from an inert gas, preferably nitrogen. / 9 0 9 1 2 2 Q i. Heat storage device according to Claims 1 to 13, characterized in that the heat storage device (1} is hermetically sealed and under normal circumstances the volume of the gas cushion (7) is selected so that it is able to to buffer the heating of the pressure increase occurring in the heat storage medium (o). Heat storage device according to claim 1-1 * 4-, characterized in that the gas cushion (7) is in communication with the outside temperature. 16. Heat storage device according to claims 1-15, characterized in that the heat storage medium (o) is under a pressure of about 1-2 atm or under the pressure prevailing in the water pipe. 1T. Heat storage device according to claims 1-16, characterized in that the device for supplying heat is arranged slightly above the bottom of the heat storage device. 13. Heat storage device. according to claims 1 to 17, characterized in that the heat supply device is a heat exchanger fed by circulating water, which water is heated in a solar collector or by means of heat pumps. Heat storage device according to claims 1 - 18 ', characterized in that the water contained in the heat storage device is pumped away at the bottom, passed directly through the solar collector or through the boiler of an oil or gas or coal burner and is fed back to the heat storage device at the top. A heat storage device according to claims 1-19, characterized in that the device for supplying heat is an electrically heated heat source. 21. Heat storage device according to claims 1 - 20, characterized in that the device for delivering heat is arranged below the surface of the heat storage medium. 22. Heat storage device according to claims 1-21, characterized in that the device for delivering heat is a heat exchanger through which the water to be consumed or the heating water flows, two corresponding heat exchangers 7903122 J * Ϋ can be placed next to each other or drilling and one heat exchanger can heat the water to be consumed and the other can heat the heating water. Heat storage device according to claims 1 to 22, characterized in that the water present in the heat storage device as heat storage medium is led directly through the heating body of the heating device or through the underfloor heating. 2k. Heat storage device according to claims 1-13, characterized in that the water present in the heat storage device as heat storage medium is consumed directly as hot or hot water, respectively. 7909122