DE102009036550A1 - Device for intermediate storage of thermal energy, comprises a first part area that is traversed by a tube guide system, and a second part area in which a thermal unloadable and reloadable storage medium is arranged - Google Patents

Abstract

The device comprises a first part area that is traversed by a tube guide system (11) in which a process medium (14) flows to feed and discharge of thermal energy, a second part area in which a thermal unloadable and reloadable storage medium (6) is arranged, a current-guiding device for controlling and/or regulating fluid streams, and means for direct coating or discharging of storage medium with thermal energy. A fluid (15) flows to the first and second part areas of the device for the transmission of thermal energy between the tubular guide system and storage medium. The device comprises a first part area that is traversed by a tube guide system (11) in which a process medium (14) flows to feed and discharge of thermal energy, a second part area in which a thermal unloadable and reloadable storage medium (6) is arranged, a current-guiding device for controlling and/or regulating fluid streams, and means for direct coating or discharging of storage medium with thermal energy. A fluid (15) flows to the first and second part areas of the device for the transmission of thermal energy between the tubular guide system and storage medium during loading and/or unloading of the storage medium. The storage medium comprises flow spaces for flowing the fluid. The first and the second part areas are directly adjoined to each other within the device. The first part area is arranged along an axis and is surrounded over its circumference of the second part area. The first part area is arranged along a plain and the second part area is arranged along both sides of the first part areas. The areas limiting the flow areas comprise ribs or profiles for improving the heat transmission. The storage medium is formed by a body with steady external area. The body is formed as single-piece solid body and the flow areas are formed by flow channels (9) or flow slits in the solid body. The body is formed by form bodies with flow channels. The form bodies form flow gap through arrangement in mutual interval. The flow area comprises a meandering process. The form body possesses a distinct longitudinal direction and is arranged to each other under formation of flow gap in lateral interval. The plains adjoining the form bodies are laid over cross. The body consists of concrete, fireclay, stones, ceramics or solid salts. The body is formed by bulk material and forms intermediate area in the bulk material of the flow area. The bulk material consists of mineral material having uniforms grains. The bulk material consists of slag, metals or solid salts in processing temperature. The bulk material exists in fluid-traversed gabions. The body has solid additives in processing temperature for increasing thermal conductivity. The body is formed by a container that is filled with a fluid in processing temperature of the storage medium. The container is filled with fluid sulfur, fluid salt or thermo-oil. The process medium is formed from oil, water, steam or damp air. The tubes of the tube line systems are put over a part of its length in loop. The tubes of the tube guide systems comprise ribs or profiles at its external side for improving the heat transmission. The inlet and outlet of the tube guide systems are arranged at an upper side of the storage medium so that the tube guide system is removed towards the side of the device. The first part area of the fluid is flow throughable in vertical direction. The fluid and the process medium of the first part area flow in opposite directions. A forced or natural convection of the fluids is provided within the device. A circular flow of the fluid is present between the first and second part areas. In the first part area, a further tube guide system is arranged. The tube guide system is determined for loading the storage medium with thermal energy. The device is surrounded by a thermal insulation.

Description

The The invention relates to a device and an arrangement for buffering thermal energy according to the characteristics the independent one claims 1 and 35.

in view of worldwide dwindling primary raw materials as resources for energy generation gain regenerative and alternative Concepts more and more important. An example is the use of solar energy in solar thermal power plants or the use of waste heat industrial Called manufacturing processes. Because these alternative forms of energy however, to the sun's radiation or to certain industrial ones Processes are coupled, their availability at any time not guaranteed. Their practical usability thus depends heavily on the possibility which temporarily store accumulating energy and at a later time Time to provide. The storage of thermal energy is therefore of central importance in the development and implementation of alternative concepts for energy production to.

Known Thermal energy storage systems essentially comprise a heat source, for example, a solar collector or an internal combustion engine, a heat storage with a thermally loading and unloading storage medium, and at least a heat cycle for Loading and unloading of the heat accumulator, in which a working medium from the heat source to the heat storage or from the heat storage to the heat demand place flows.

For the effectiveness of the whole system, the storage medium is of central importance. This must essentially meet two requirements, namely on the one hand have a high thermal storage capacity, that is one the greatest possible ability own, absorb thermal energy per unit weight and volume to be able to and on the other hand are characterized by a high thermal conductivity, that is, the heat must be preferably can distribute quickly in the storage medium.

When Storage medium are already liquids known that meet the two criteria mentioned above. For the low temperature range to about 100 ° Water as a storage medium, since it is available at low cost and is characterized by its high thermal storage capacity. However, the disadvantage is the rapid increase of the vapor pressure at temperatures near 100 ° C, which requires expensive pressure vessels become. For this reason, liquids are used for higher temperature ranges with a higher one Used boiling point, such as heat transfer oils or molten salts, which but a significant increase the investment costs is connected. By circulation of the liquid storage medium results in a convective heat transfer, the cause is for fast and even and discharge of the storage medium.

Next liquid storage are already solid storage known, for example mineral bulk materials, But also steel, cast, fireclay or the like can exist. metals are suitable due to their high specific gravity and high Thermal conductivity good as a storage medium, however, cause high investment costs. On the other hand, the others are distinguished Although materials from a high storage capacity, but require because of their limited thermal conductivity relatively much Time for that Loading and unloading, so that their use is only partially possible.

In front In this background, the invention is based on the object heat storage with one as possible high thermal storage capacity and high loading and unloading capacity indicating both reliable and economic storage thermal energy allowed.

These The object is achieved by a device having the features of the patent claim 1 and a system having the features of claim 35.

advantageous embodiments emerge from the dependent claims.

The Invention builds on the recognition that solids as a storage medium due to their simple structure resulting from their solid structure Handling and their high thermal storage capacity in principle to Caching of thermal energy are suitable, however, this suitability because of their poorer thermal conductivity in the Comparison to liquids limited is.

In order to compensate for this disadvantage of fixed storage media, the invention provides that the storage medium is traversed by a multiplicity of flow spaces through which a fluid subjected to thermal energy flows. In this way it is achieved that the storage medium is uniformly charged or discharged over its entire volume with thermal energy. The Wärmeleitverhalten of the storage medium plays only a minor role, since the zurückzulegenden heat conduction paths between the flow spaces are only short. In this way, the invention succeeds in the demand for high thermal conductivity and dissolve the use of a fixed storage medium.

According to the invention becomes the heat transport into the interior of the storage medium carried by a fluid, the in a loading or unloading cycle from a first section flows to a second portion of the device, wherein in the first portion a heat exchange with a guided within a piping system working medium takes place and the second portion has the storage medium.

Around one as possible efficient heat transfer From the working fluid to reach the fluid is, according to a advantageous embodiment the invention provides that working fluid and fluid in countercurrent flow.

Around flow losses in the loading and unloading cycle as possible to keep low, the invention provides, by constructive measures the distance from the first portion to the second portion as possible short, for example by giving these areas as possible are arranged immediately adjacent to each other.

In this sense it is possible that the first portion arranged along an axis and from the second subarea is surrounded. So arise at the axial Ends of the device radially directed flow paths from the first portion to the second subarea, or vice versa, for uniform flow conditions to care. Such an embodiment is especially for Single memory interesting.

A in addition alternative possibility the memory training provides, the first section along to arrange a level, wherein the second portion at least extends along one side of the first portion, preferably along both sides. In this way, heat storage can be achieved predetermined storage capacities in any length getting produced. Such embodiments The invention is particularly suitable for the production of modular construction Storage facilities, wherein such individual memories sandwich in planparalleler Location can be arranged side by side, for parallel loading or Discharging with thermal energy or in series to the serial Loading and unloading.

When Storage medium becomes a body with a fixed outer surface preferred. These include initially solid bodies, the is called Body, in the operating state of the device through and a solid state of aggregation exhibit. This concludes However, not storage media made up where the solid outer shell only a container represents that with a liquid filled is. This embodiment The invention has the advantage that within the liquid by convection an effective heat transfer is possible, with the advantage of the storage medium extremely fast and evenly or to be able to unload. This allows the mutual distance of the flow spaces to choose larger, resulting in the constructive Overall effort in the production of a memory according to the invention reduced.

When Storage medium suitable solid body can be diverse nature. So can the solid body one piece be formed, so consist of a monolith. advantageously, becomes such a solid body poured in the course of its production directly on site in its intended form. As a preferred building material, for example, concrete can be used in which the flow spaces through Inserting hollow sections or the like can be produced. Of the Concrete construction material has the advantage that it is available everywhere and at low cost and thus also be able to produce complex shapes. By using suitable aggregates, cements, additives, admixtures and admixtures of additives, it is also possible the concrete and thus the storage medium to the respective requirements adapt.

A alternative way of producing the storage medium from solid, is in the juxtaposition a variety of moldings next to each other and / or one above the other. moldings have the advantage that the factory prefabricated and as a result Warehousing within the shortest possible time Time in large numbers available can be made. By the factory production is achieved a consistently high quality of the moldings, so that even a storage medium made from it Whole volume possesses uniform properties. By the lower one Weight and volume compared to a one-piece solid body shaped body both in the production of the storage medium as well as in the execution better handle and allow maintenance and repair work about that addition, at the end of the useful life of the memory a hassle dismantling of the solid body. It is even possible the individual shaped bodies after their disassembly in another heat storage to use again.

to Creation of flow spaces one of moldings produced storage medium, it is possible according to the invention that every molding has continuous flow channels. at appropriate joining together several moldings the flow channels are aligned one above the other lying moldings and thus form a continuous flow space.

It is possible, too, the moldings with or without flow channels such to bring in a relative position to each other, that the flow spaces through give the distance between the moldings. For example, by mutually protruding into a room plates a meandering current of Fluids are achieved. By the extension thus achieved of the flow path Also, the contact time between fluid and storage medium is extended with the result that a more efficient heat transfer is possible.

It is also conceivable, the individual shaped body by choosing a suitable Length-width ratio with a pronounced Longitudinal extension manufacture. The moldings can then layer by layer on top of each other be stacked, wherein the individual shaped body of a layer under formation of flow gaps are arranged axially parallel and at a lateral distance from each other and the moldings two adjacent layers over Cross are laid. Such an embodiment impresses with the Simplicity of their manufacture and the possibility of choosing the mutual distances the flow space to enlarge or to downsize. At the same time leads Such a design of the flow space to a homogenization of Fluid flow, so that the solid body is charged or discharged uniformly with thermal energy.

All In general, by choosing a suitable position of the solid body to each other a fluidic Optimization carried out such that the formed by the solid bodies Storage medium evenly from the fluid is flowed through. For this it may be necessary that the solid bodies are no longer parallel or are arranged at right angles to each other.

A another possibility the production of the solid body consists in the use of bulk material within a container or as gabion can be present. The interstices within the bulk material result a communicating management system and form in this way the Flow spaces for the fluid. By choice of bulk material with appropriate shape and size can influence on the geometry of the flow spaces. bulk also has the advantage that a solid body by way of Aufschüttens in very simple way can be made and its Dismantling and recycling at the end of its useful life is possible.

When Material for the solid bodies are all substances that have good thermal conductivity and their thermal storage capacity is as large as possible based on the volume or weight. That is, that Material for The storage medium must be able to use as much thermal energy as possible absorb or release and the thermal conductivity must be sufficient to the existing thermal energy as possible be able to quickly enter or exit the storage medium.

This Above all, metals meet demand, however, in the production a device according to the invention cause high investment costs. Also suitable and made From an economic point of view, therefore, are preferable according to the invention natural or artificial mineral substances, such as concrete, fireclay, rock, Ceramics, salt and the like. To the thermal conductivity to increase some materials, the invention provides in a particular embodiment, in the Material of the solid body additions to increase the thermal conductivity to give. These are, for example, graphite, bauxite, alumina, Metals, sodium chloride or potassium chloride.

According to the invention the working medium is gaseous and / or liquid before and can for example by a heat transfer oil, water, steam or Be formed air. The working medium is within a piping system guided, that runs through the first section. To improve an intimate Exchange of thermal energy between the working fluid and the Fluid see advantageous embodiments invention, the surface the piping, over which the heat exchange takes place, provided with ribs or profilings, allowing for the heat transfer an enlarged surface for disposal stands. In this sense, the piping system in the first part be placed in loops, so that the working medium the first subarea flows through several times. By the increase thus achieved the length of stay of the working medium in the first subarea is a better heat exchange possible with the fluid.

to simplified assembly and disassembly, but also to repair and For maintenance purposes, it proves to be advantageous, the piping system so train that intake and drain on a common page lie. this makes possible the insertion of the prefabricated pipeline system from this Page, without further work being necessary on site.

According to one further advantageous embodiment flows through the invention the fluid the first portion substantially vertical to a natural convection allow the fluid within the device or in the case of a Forced convection the forces from the natural Convection as drive for to support the loading and unloading cycle.

Another advantageous embodiment The invention provides for the use of flow guiding devices for the steering and / or regulation of the fluid flow. Since the fluid within the device always follows the flow path with the least resistance, there is a risk that within the storage medium zones are formed, which are more fluid flowing through and therefore more intense loaded with thermal energy than others. The resulting nonuniform loading of the storage medium over the storage volume prevents full utilization of the existing storage capacity. By Strömungsleiteinrichtungen constructive local differences in flow resistance can be compensated, so that even in areas with higher flow resistance sufficient flow is ensured.

A other objectives pursue flow control devices, which serve to load or unload the storage medium successively, allowing portions of the storage medium sequentially to the maximum memory be used. The advantage of such an embodiment is that already at a very early age Time the full energy performance of a particular subarea can be retrieved.

A Another advantageous embodiment of the Invention provides, the storage medium additionally and directly with thermal To apply energy. This is done according to the invention by introduction a fluid that comes directly from an industrial process, for example, in the form of hotter Exhaust gases of an internal combustion engine or fluids from a cooling process, into the flow spaces of the Storage medium. Conversely, it is also possible to use the storage medium directly discharged by passing the fluid through the thermally loaded storage medium guided and further without the interposition of a heat exchange circuit a heat consumer is forwarded.

A in turn another embodiment The invention has two separate piping systems on, in each of which a working medium flows. So can the first piping system for Loading the storage medium serve and an optimized working medium have. The second piping system, however, is for the unloading process the storage medium determined and its working medium for this Task optimized.

The Invention will be described below with reference to several in the drawing embodiments explained in more detail, wherein Additional characteristics and benefits are described. To facilitate understanding be for same or equivalent features of different embodiments of the embodiment same reference numerals used.

It shows

1 a longitudinal section through a first embodiment of a device according to the invention in a schematic representation,

2 a longitudinal section through a first embodiment of a storage medium of a device according to the invention,

3 a top view of the in 2 illustrated storage medium,

4 a longitudinal section through a second embodiment of a storage medium of a device according to the invention,

5 a top view of the in 4 illustrated storage medium,

6 a longitudinal section through a second embodiment of a device according to the invention,

7 a cross section through the in 6 illustrated device,

8th an oblique view of a third embodiment of a device according to the invention,

9 an oblique view of a fourth embodiment of a device according to the invention,

10 a longitudinal section through a fifth embodiment of a device according to the invention,

11 an oblique view of a sixth embodiment of a device according to the invention,

12 a longitudinal section through a seventh embodiment of a device according to the invention,

13 a longitudinal section through an eighth embodiment of a device according to the invention,

14 a longitudinal section through a ninth embodiment of a device according to the invention,

15 a cross section through the in 14 illustrated device,

16a and b each have a longitudinal section by a tenth embodiment of the invention in different operating states,

17a and b each show a longitudinal section through an eleventh embodiment of the invention in different operating states,

18 a longitudinal section through a system of several devices connected in series according to the invention,

19 and 20 in each case a longitudinal section through a system of a plurality of devices according to the invention connected in parallel,

21 a plan view of a system with a plurality of parallel connected inventive devices, and

22 a schematic representation of a twelfth embodiment of the invention with direct loading of the storage medium.

1 shows a schematic representation of a vertical section through a first embodiment of the invention, based on the principle of the invention is explained. The device comprises a housing 1 whose pages 2 . 3 , Lid 4 and soil 5 enclose a substantially gas-tight space. Inside the case 1 the space is divided into a first, centered between the sides 2 and 3 located in a central portion A and in a second from the first portion A to each of the side walls 2 and 3 extending portion B.

The second section B serves to receive a storage medium 6 which adjoins directly in the transverse direction to the first portion A and the longitudinal direction to form free zones 7 and 8th in the clear distance to the lid 4 and soil 5 ends. The storage medium 6 is of a variety of vertically extending, paraxial flow spaces in the form of flow channels 9 interspersed.

In the first section A you can see several pipes 10 that parallels the free zone 7 to the free zone 8th extend. The pipelines 10 are part of a piping system 11 to which also the supply line 12 heard in the area of the zone 7 to the ends of the pipes 10 connects and the derivative 13 that are in the area of the zone 8th forms a corresponding connection. The piping system 11 is part of a cycle in which a heat source and a heat consumer, such as a steam turbine, are integrated. The arrows 14 symbolize the working medium, the gaseous or liquid heat transfer medium piping system 11 flows through. Otherwise, the case 1 and thus the first portion A, the second portion B, the flow channels 9 as well as the free zones 7 and 8th one by the arrows 15 typed fluid filled.

For loading the storage medium 6 with thermal energy becomes the working medium 14 in the circulation passed by a heat source. The heat source can be formed, for example, by solar collectors, the one within the piping system 11 heat flowing heat transfer oil to about 400 ° C. About the supply line 11 enters the thus loaded with thermal energy working medium 14 to the pipelines 10 that it is from the zone 7 to the zone 8th , So from top to bottom, lead through the first portion A of the device according to the invention, wherein it emits a part of the thermal energy.

At the end of the pipes 10 becomes the working medium 14 in the derivation 13 collected and led back to the heat source for reloading.

The fluid 15 flows inside the housing 1 also in the circulation and initially passes the first portion A, where by the contact with the of the working medium 14 heated pipes 10 a heat transfer from the warmer working medium 14 to the colder fluid 15 takes place. So heated up, the fluid gets 15 after flowing through the free zone 7 into the flow channels 9 of the storage medium 6 , In this way, the fluid transports 15 thermal energy from the working medium 14 inside the storage medium 6 and gives them when flowing through the flow channels 9 to the storage medium 6 which is gradually charged with thermal energy. After exiting the flow channels 9 the fluid flows 15 over the free zone 8th back to the first subarea A.

The unloading process is carried out in the reverse manner, being in the circulation of the working medium 14 a consumer is interposed, for example a steam turbine. The circulated fluid 15 is from the thermally loaded storage medium 6 heats and transports the thermal energy in the first section A, where a heat exchange with the working fluid 14 takes place. The working medium 14 then brings the thermal energy to the point of consumption.

This basic principle also lies below the 2 to 21 described embodiments of the invention based.

The 2 to 5 show embodiments of the invention in which the storage medium formed by a solid body 6 from shaped bodies 16 consists. The 2 and 3 show moldings 16 in the form of cuboids, at For example, cement-bonded materials, clay, fireclay, ceramics or salts such as NaCl or KCl can be made. Every molding 16 is in the vertical direction of mutually parallel flow channels 17 traversed, which in the present case have circular cross-section, however, to increase the heat transfer surface also have other cross-section or with in the flow channel 17 can be provided projecting webs. For a storage medium 6 Concrete can be the flow channels 9 For example, have a diameter of about 2 cm. Neighboring flow channels 9 can be arranged in a triangle at a uniform distance between 3 cm and 20 cm, preferably between 6 cm and 8 cm.

For the production of the storage medium 6 is a variety of moldings 16 layer by layer side by side and superimposed together, wherein molded body 16 adjacent layers are arranged with offset of the vertical joints. In this case, a relative position of the shaped body 16 complied with each other, in which the flow channels 17 adjacent shaped body 16 aligned. In this way, the flow channels form 17 the individual molded body 16 continuous flow spaces that the storage medium 6 fully enforce.

In the in the 4 and 5 illustrated embodiment of the storage medium 6 own the individual moldings 16 each have a pronounced longitudinal direction, so have rod-shaped or bar-shaped and can both with and without flow channels 17 be prepared. These shaped bodies 16 are inside the storage medium 6 stacked in several layers, the moldings 16 each layer are arranged parallel and spaced from each other. In this way arise between the individual moldings 16 a layer of flow 18 , The moldings 16 two vertically adjacent planes are placed crosswise, so that the flow column 18 to cross each other from one level to another.

The flow space of one of such moldings 16 formed storage medium 6 is composed of a plurality of mutually parallel flow gaps 18 whose longitudinal extension direction changes from one plane to the next, preferably by about 90 °. Due to the resulting intersecting arrangement arise from the transition from one level to the next punctual openings 19 entering the flow column 18 the next level. The flow spaces resulting in this way cause a transverse distribution of the fluid varying from level to level 15 in the individual flow columns 18 , resulting in a uniform admission of the storage medium 6 with total thermal energy leads.

The 6 and 7 disclose an embodiment of the invention with a cylindrical housing 1 , the front side through the lid 4 and soil 5 is closed. The housing 1 has circular cross-section and can for example consist of a precast concrete part.

Inside the housing is a one-piece solid body 20 as a storage medium 6 , The solid body 20 can be prefabricated and in the course of the production of the heat storage as a finished part in the housing 1 be used. Alternatively, a preparation of the solid body 20 possible on site, for example by concreting.

The solid body 20 has the shape of a thick-walled hollow cylinder, wherein the cylinder wall of the second portion B and the cavity enclosed by the cylinder wall along the cylinder longitudinal axis corresponds to the first portion A By maintaining an axial distance to the lid 4 and soil 5 turn, free zones arise 7 and 8th inside the case 1 ,

For the formation of the flow space, the solid body 20 a plurality of axially parallel flow channels 17 on that the free zone 7 with the free zone 8th connect. How out 7 can be seen, are the flow channels 17 Radiant on circumference circles of different radii. This results in the interior of the solid body 20 towards a larger cross-sectional density of flow channels 17 than in the outer peripheral area of the solid body 20 the case is. Such a solid body 20 reaches therefore in the interior, the first portion A facing area first its maximum storage capacity. If it is desired to achieve a uniform charge over the cross section of the solid body, it is conceivable that the cross section or the number or the density of the flow channels 17 in the outer peripheral regions to increase, there to a more intense flow with fluid 15 to reach. For a storage medium 6 Concrete can be the flow channels 17 For example, have a diameter of about 2 cm.

Another arrangement, not shown, of the flow channels 17 looks in front of the arranged on two adjacent circumferential circuits flow channels 17 with an angular offset to each other, so that a flow channel 17 of the first circumferential circle in the radial direction in the middle between two flow channels 17 the second circumferential circle lies. This results in a cross-sectional respectively triangular arrangement of the flow channels 17 with uniform intervals in the Trap of concrete as material for the storage medium 6 For example, between 3 cm and 20 cm, preferably between 6 cm and 8 cm, can lie.

The extending along the cylinder longitudinal axis first portion A is of axially parallel pipes 10 permeated, in which the working medium 14 flows through the portion A several times. The pipes are loaded 10 via the common supply line 12 , The return of the working medium 14 to a heat source or a heat consumer via the derivative 13 in this embodiment of the invention on the same side of the storage medium 6 is arranged like the supply line 12 , So can the piping system 11 with the lid removed 4 with that of the pipes 10 formed part of this page are introduced axially into the first portion A, thereby simplifying assembly and disassembly of the device quite significantly. The functioning of the in the 6 and 7 illustrated embodiment otherwise corresponds to the 1 described.

Another embodiment of the invention is in 8th shown. This has a cuboid housing 1 whose outside is of an in 8th only partially indicated thermal insulation 21 is surrounded. In order to better illustrate the internal structure of the device, a transparent and partially broken representation is selected.

The interior of the housing 1 is in turn divided into a first extending in a plane portion A and second portion B. The second portion B is of two plate-shaped monolithic solid bodies 20 is formed, which lie plane-parallel in the lateral distance and include the first portion A sandwiched. The upper front side 22 and lower end 23 of the solid body 20 but do not run parallel to the lid 4 or soil 5 of the housing 1 but form a slope, with the axial distance to the housing 1 increasing towards the mid-plane. In this way, free zones arise 7 and 8th which have a triangular cross-section. This embodiment takes into account the fact that the fluid flow 15 in terms of volume to the housing sides 2 and 3 decreases and is produced by reducing the flow cross-sections, a uniform flow. The two solid bodies 20 are in turn of a variety of axially parallel flow channels 9 traversed, with their ends in the open zone 7 or free zone 8th lead. For a storage medium 6 Concrete can be the flow channels 9 For example, have a diameter of about 2 cm. Neighboring flow channels 9 can be arranged in a triangle at a uniform distance between 3 cm and 20 cm, preferably between 6 cm and 8 cm.

The solid bodies 20 may alternatively to a monolithic training of moldings 16 be formed, as for example under the 2 to 5 have already been described.

The space between solids 20 corresponds to the first subarea A. There you see a supply line 12 placed in a pipeline laid in horizontal loops 10 passes and that as derivative 13 out of the case 1 leads. The horizontal sections of the pipeline 10 have the outer circumference circumferential ribs 24 to increase the contact area with the fluid 15 to allow a better heat exchange.

Also at the in 8th The device shown is the under 1 realized functional principle realized.

In the 9 embodiment of the invention shown corresponds in large parts of the 8th described, so that what is said there applies. Significant differences arise from the resolved design of the storage medium 6 , The storage medium 6 consists of plate-shaped moldings 16 small thickness, which are arranged plane-parallel and spaced apart in the second portion B. The flow spaces for the fluid 15 are by the clearance of the moldings 16 formed, that is, the fluid 15 flows through the storage medium 6 between the plate-shaped moldings 16 , For moldings 16 made of concrete, the plate thickness, for example, between 2 cm and 10 cm, preferably between 3 cm and 5 cm, and the mutual distance of the plate-shaped moldings 16 between 1 cm and 2 cm.

Another difference concerns the first subarea A. The piping system running there 11 comprises a plurality of pipes arranged at a predetermined distance axially parallel to one another 10 , which at one end over the common acting as a distributor supply line 12 with the working medium 14 be supplied and at the opposite end in the acting as a collector derivative 13 lead. Every pipeline 10 has several longitudinal ribs 25 preferably at uniform angular intervals axially along the circumference of the pipelines 10 run.

10 is a longitudinal section through an embodiment of the invention again, in which the housing 1 and the storage medium 6 cylindrical shape similar to the embodiments according to 6 and 7 or also a sandwich-type construction according to the embodiments according to 8th and 9 can own. The peculiarity of this embodiment is that the second section B is bounded by inner walls 26 and the pages 2 . 3 , In the space between the walls 26 and the pages 2 and 3 protrude in horizontally extending, axially staggered planes annular disk-shaped or plate-shaped moldings 16 , alternately on the inner walls in the vertical direction 26 or the pages 2 and 3 are fixed, in such a way that on the inner wall 26 attached moldings 16 comb-like while maintaining an all-round distance in the spaces between the moldings 16 the pages 2 and 3 protrude into it. By maintaining a clear distance both in the vertical direction to adjacent moldings 16 as well as in perpendicular direction to the inner wall 26 or to the sides 2 and 3 This results in a meandering flow space, the fluid 15 when loading or unloading the storage medium 6 flows through. The piping system 11 corresponds in the case of a cylindrical device under the 6 and 7 so that reference is made to the local part of the description. In the case of a sandwich construction, a piping system according to the 8th and 9 Find use.

While in the previously described embodiments of the invention, the storage medium 6 formed by an overall rigid body disclosed 11 an embodiment in which bulk material 27 for storing the thermal energy is used. For this purpose baskets run 28 along the sides 2 and 3 and thus form the second subarea B. The underside 29 and top 30 the baskets 28 Run towards the center with increasing distance to the lid 4 or soil 5 , causing the free zones 7 and 8th arise. The bottom 29 is provided with a plurality of openings which the inlet and outlet of the fluid 15 enable. The top 30 may be trained or remain open. The baskets 28 are each with bulk material 27 filled, which can be diverse nature. For example, come mineral or metallic materials in question. The communicating cavities between the individual bulk material elements result in a coherent flow space, the fluid 15 uses for flow.

To form the first portion A hold the baskets 28 a mutual distance, which of the piping system 11 is interspersed. To improve the heat transfer from the pipeline 10 of the pipe power system 11 on the fluid 15 points the pipeline 10 a variety of tube circumference circumferential ribs 31 on.

A with regard to the heat distribution in the storage medium 6 particularly advantageous embodiment of the invention shows 12 in a schematic representation. The arranged in the second portion B storage medium 6 is made of hollow plate-shaped or hollow cylindrical containers 33 formed, for example, from the front side sealed tubes. The containers 33 are advantageously formed thin-walled and consist of a thermally highly conductive material such as metal and are filled with a liquid at operating temperature material such as sulfur, molten salt or thermal oil. The flow space results from the distances of the containers 33 among themselves. The housing 1 with the first subarea A and the zones 7 and 8th as well as the piping system 11 largely corresponds to the under 1 What is said so that reference is made to this part of the description.

In a storage medium formed in this way 6 By far the largest volume fraction consists of liquid, so that the heat distribution within the storage medium 6 by convection can be done, what by the arrows 34 is indicated. Such an embodiment of the invention can therefore provide the stored energy very quickly or be loaded therewith.

The 13 . 14 and 15 concern measures to control and control the fluid flow 15 inside the case 1 , Ideally, by appropriate structural design of the sections A and B, a natural convection of the fluid 15 one.

If natural convection is not sufficient as a driving force for the circulation flow, the embodiment according to FIG 13 before, the pressure conditions within the housing 1 by one or more suction and / or pressure blower 35 to influence. These can be within the free zone 7 and or 8th be arranged or open suction or discharge lines in these areas. 13 shows this measure in connection with an embodiment according to 1 , which does not exclude that suction and / or pressure blower 35 can also be used in combination with the other embodiments.

The 14 and 15 show an embodiment of the invention in the longitudinal and cross-section, in which the fluid 15 For loading and unloading concentrated in any part of the storage medium 6 while the rest area is inactive. For this purpose, a dazzling annular disc 36 with sector-shaped opening 37 ( 15 ), which is the top or bottom of the storage medium 6 covered. By a rotatable mounting of the annular disc 36 is it possible the opening 37 to adjust, leaving a fluid flow 15 only in the one from the opening 37 shared part of the storage medium 6 gets underway, with the result of a partial loading or unloading. By slow continuous or stepwise rotation of the annular disc 36 in this way becomes the storage medium 6 gradually filled or discharged, each with the maximum possible amount of heat.

The 14 and 15 show an implementation of this idea in conjunction with a cylindrical housing 1 and a rotating annular disc 36 , Likewise, in sandwiched embodiments of the invention, a linearly displaceable element with an opening could be used.

The 16a and Figure b shows an embodiment of the invention with two separate heat circulations for the working fluid 14 , You can see a first piping system 11 ' , which is the working medium charged with thermal energy 14 to the storage medium 6 passes. There is a heat exchange with the fluid 15 instead, that in turn is the storage medium 6 loads. This operating state is in 16a shown.

16b indicates the operating state of the discharge, including a second piping system 11 '' with a working medium 14 ' filled, in its kind of working medium 14 of the loading cycle can differ. When unloading the memory is in the storage medium 6 existing thermal energy through the fluid 15 to the piping system 11 '' and thus the working medium 14 ' given.

From the 17a and b shows that a device according to the invention can also be charged or discharged directly with thermal energy. 17a shows the Beladekreislauf, in which a thermally energetic fluid 15 ' directly and without the interposition of a piping system or working medium to the storage medium 6 to be led. The fluid 15 ' consists for example of the exhaust gases of a combustion process or the liquid of a cooling circuit, the residual heat for heating the storage medium 6 can be used. The fluid 15 ' can also be heated directly in a thermal plant such as a solar panel.

Like the in 22 shown variant shows the fluid 15 ' also by heat exchange with a guided in a primary heat cycle working medium 14 be heated. This is the fluid 15 ' passed in countercurrent to the heat transfer medium, for example by a pipe-in-pipe section as a heat exchanger 41 , As a heat source in the primary heat cycle, for example, a solar collector 42 serve. The fluid heated in the heat exchanger 15 ' is then in a further heat cycle directly to the storage medium 6 given up.

In 17b the discharge of such a heat storage is shown, in which the fluid 15 ' It uses the thermal energy from the storage medium 6 into the piping system 11 for further use.

The direct introduction of a fluid into a device according to the invention can also be combined with the previously described embodiments of the invention, that is, the storage medium 6 In these cases, it is not just the fluid that has been introduced directly 15 ' loaded with heat, but also via a piping system 11 , which is a correspondingly hot working medium 14 leads.

The 18 to 21 show plants which are composed of two or more of the inventive devices described above. 18 discloses an arrangement of two devices according to the invention, of the working medium 14 be flowed through in succession. This is achieved by the process 13 the initially flowed through device in the inlet 12 the subsequent device opens. In such an arrangement, the first through-flow of individual devices are first loaded with the full thermal energy, so that there at a relatively early time, the maximum temperature is reached and therefore can be retrieved correspondingly early again.

Of these, the differences in the 19 and 20 illustrated embodiments by a parallel connection of the individual devices according to the invention, via a common, acting as a distributor supply line 12 with working medium 14 be supplied. From the supply line 12 each branch pipes 10 into the first subarea A of each device. On the opposite side of the working medium 6 the pipes open 10 in a common, acting as a manifold derivation 13 , While in 19 the supply line 12 and derivative 13 inside the case 1 run, shows 20 an embodiment in which the supply line 12 and derivative 13 outside the case 1 are guided.

In 21 is a cell-like structure to see, with the cells of each one of the 1 to 17 described apparatus are formed, which are arranged to form the system in rows next to each other. About large-volume distribution lines 38 , from which supply lines 12 lead to the individual first sections A, who which charges and charges the cells with thermal energy in the manner previously described. About the derivatives 13 and the manifolds 39 becomes the working medium 14 led back again. In this way results in a parallel connection all to the same distribution line 38 or manifold 39 connected cells.

A combined series / parallel connection of the cells is possible, for example by the working medium 14 a manifold 39 into a distribution line 38 is initiated. This variant is determined by the in 21 dashed line 40 indicated.

It It is understood that the invention is not limited to the specific feature combinations the individual embodiments limited is, but also combinations of in different embodiments disclosed features, provided they are to the purpose connect the invention.

Claims (36)

Device for buffering thermal energy - having a first portion (A) of at least one piping system ( 11 . 11 ' ), in which a working medium ( 14 . 14 ' ) flows to the supply and removal of the thermal energy, - with a second portion (B), in which a thermally loading and unloading storage medium ( 6 ) and - with a fluid ( 15 ) for the transmission of thermal energy between piping system ( 11 . 11 ' ) and storage medium ( 6 ) during loading or unloading of the storage medium ( 6 ) flows through the first portion (A) and the second portion (B) of the device, - wherein the storage medium ( 6 ) Flow spaces ( 9 . 17 . 18 ) for the passage of the fluid ( 15 ) having. Device according to claim 1, characterized in that that the first portion (A) and the second portion (B) within the device are arranged immediately adjacent to each other. Device according to Claim 1 or 2, characterized the first subarea (A) is arranged along an axis and over its circumference is enclosed by the second portion (B). Device according to Claim 1 or 2, characterized the first subarea (A) is arranged along a plane and the second portion (B) substantially plane-parallel along one side of the first portion (A), preferably along both Pages of the first portion (A) is arranged. Device according to one of claims 1 to 4, characterized in that the flow spaces ( 9 . 17 . 18 ) bounding surfaces ribs ( 24 . 31 ) or profilings to improve the heat transfer. Device according to one of claims 1 to 5, characterized in that the storage medium ( 6 ) is formed by at least one body with a fixed outer surface. Apparatus according to claim 6, characterized in that the body as a one-piece solid body ( 20 ) is formed and the flow spaces of flow channels ( 9 ) or flow slots in the solid body ( 20 ) are formed. Apparatus according to claim 6, characterized in that the body of a plurality of juxtaposed molded body ( 16 ) with flow channels ( 17 ) is formed, and the flow channels ( 17 ) of the individual shaped bodies ( 16 ) resulting in the flow spaces. Apparatus according to claim 6 or 8, characterized in that the body of a plurality of moldings ( 16 ) formed by arrangement at a mutual distance flow gaps ( 18 ), which together make up the flow space. Device according to claim 9, characterized in that that the flow spaces one meandering Have history. Device according to claim 9, characterized in that the shaped bodies ( 16 ) have a pronounced longitudinal direction and in layers to form flow gaps ( 18 ) are arranged at a lateral distance from one another, wherein the shaped bodies ( 16 ) of adjacent levels are crossed. Device according to one of claims 6 to 11, characterized that the body concrete, fireclay, stone, ceramics or a solid salt. Apparatus according to claim 6, characterized in that the body of bulk material ( 27 ) is formed and the spaces in the bulk material ( 27 ) form the flow spaces. Apparatus according to claim 13, characterized in that the bulk material ( 27 ) consists of mineral material. Device according to claim 14, characterized in that that the mineral material has a uniform grain size. Apparatus according to claim 13, characterized in that the bulk material ( 27 ) consists of slags, metals or solid salts at operating temperature. Device according to one of claims 13 to 16, characterized in that the bulk material ( 27 ) in one or more fluid-flowed gabions ( 28 ) is present. Device according to one of claims 6 to 17, characterized that the body solid additives at operating temperature to increase the thermal conductivity graphite, bauxite, alumina, metals, Sodium chloride, potassium chloride or other substances with a thermal conductivity of more than 3 W / (m · K). Apparatus according to claim 6, characterized in that the body of at least one container ( 33 ) formed at operating temperature of the storage medium ( 6 ) is filled with a liquid. Device according to claim 19, characterized in that the container ( 33 ) is filled with liquid sulfur, liquid salt or thermal oil. Device according to one of claims 1 to 20, characterized in that the working medium ( 14 . 14 ' ) is formed of gas and / or liquid, preferably of oil, water, steam or moist air. Device according to one of claims 1 to 21, characterized in that the tubes ( 10 ) of the pipeline system ( 11 . 11 ' ) are placed in loops at least over part of their length. Device according to one of claims 1 to 22, characterized in that the tubes ( 10 ) of the pipeline system ( 11 . 11 ' ) on its outside ribs ( 24 . 31 ) or profilings to improve the heat transfer. Device according to one of claims 1 to 23, characterized in that feed ( 12 ) and expiration ( 13 ) of the piping system ( 11 . 11 ' ) on one side of the storage medium ( 6 ) are arranged, preferably on the upper side, so that the piping system ( 11 . 11 ' ) is removable to this side of the device. Device according to one of claims 1 to 24, characterized in that the first portion (A) of the fluid ( 15 ) is flowed through substantially vertically. Device according to one of claims 1 to 25, characterized in that fluid ( 15 ) and working medium ( 14 . 14 ' ) flow through the first portion (A) in opposite directions. Device according to one of claims 1 to 26, characterized by forced convection of the fluid ( 15 ) within the device. Device according to one of claims 1 to 26, characterized by a natural convection of the fluid ( 15 ) within the device. Device according to one of claims 1 to 28, characterized by a circulation flow of the fluid ( 15 ) between the first portion (A) and the second portion (B). Device according to one of claims 1 to 29, characterized by flow guiding devices for guiding and / or regulating the fluid flow ( 15 ). Device according to one of claims 1 to 30, characterized in that the fluid ( 15 ) of a sulfur melt, molten salt, liquid salt, nitrate salt, chlorides, air, helium, hydrogen, a hydrogen-helium mixture or steam or a heat transfer oil is formed. Device according to one of claims 1 to 31, characterized in that the device next to the piping system ( 11 . 11 ' ) with working medium ( 14 . 14 ' ) further means for direct loading or unloading of the storage medium ( 6 ) with thermal energy. Device according to one of claims 1 to 32, characterized in that in the first subarea (A) another piping system ( 11 ' ), wherein the one piping system ( 11 ) for loading the storage medium ( 6 ) is determined with thermal energy and the further piping system ( 11 ' ) for unloading. Device according to one of claims 1 to 33, characterized in that the device of a thermal insulation ( 21 ) is surrounded. Plant for temporary storage of thermal energy with at least two devices according to one of claims 1 to 34th Plant according to claim 35, characterized in that the at least two devices for loading and / or unloading the storage medium ( 6 ) are connected in series or in parallel with each other.