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    • 13. 发明公开
    • Böschungsbauwerk und Verwendung einer geschlossenen Rohrleitung in einem Böschungsbauwerk oder Erdkörper
    • 倾斜结构和使用一封闭管中的倾斜结构或土体
    • EP2505720A2
    • 2012-10-03
    • EP12160478.9
    • 2012-03-21
    • Herold, Andreas
    • Herold, Andreas
    • E02D29/02F24J3/08
    • E02D29/0241E02D17/202F24T10/10Y02E10/12
    • Die Erfindung betrifft ein Böschungsbauwerk oder einen Erdkörper und eine Verwendung einer geschlossenen Rohrleitung.
      Das Böschungsbauwerk oder der Erdkörper umfasst mehrere im Wesentlichen horizontal übereinander angeordnete Erdstofflagen (1) und zwischen Erdstofflagen (1) angeordnete Bewehrungselemente (2), wobei eine geschlossene Rohrleitung (3) auf einem Bewehrungselement (2) aus Geokunststoff, insbesondere aus polymerem Geokunststoff, verlegt und/oder mit diesem verbunden ist, wobei im Bereich der Bewehrungselemente (2) jeweils eine geschlossene Rohrleitung (3) angeordnet ist, die als Element einer Geothermieanlage verwendbar ist, wobei die Rohrleitung (3) derart zugfest ist, dass sie als horizontale Bewehrung verwendbar ist, wobei die Rohrleitung (3) derart mäanderförmig innerhalb einer Erdstofflage (1) angeordnet ist, dass eine Anzahl von ersten, im Wesentlichen geraden ersten Rohrleitungsabschnitten (3.1) im Wesentlichen rechtwinklig zum luftseitigen Rand dieser Erdstofflage (1) verläuft.
    • 路基结构或土体包括多个接地材料层(1)被水平地布置在另一个之上,并增强元件(2),它们是接地材料层之间布置。 一个封闭的管道(3)设有一个由土工合成材料,特别是聚合物的土工合成材料的增强元件上。 闭合管道在加强元件的面积,所有这些是适用于地热系统的元件排列,管道被施加为水平加强。 流水线地球材料层的内部布置。
    • 18. 发明授权
    • ERDWÄRMESPEICHER MIT DAMPFSPERRE UND VERFAHREN ZUR VERDAMPFUNGSWÄRMENUTZUNG IM ERDWÄRMESPEICHER
    • 可以扩展的在地热使用内存汽锁和方法地热储存
    • EP2198209B1
    • 2011-02-02
    • EP08803753.6
    • 2008-09-05
    • Österwitz, Karl-HeinzSchmidt, Bernhard
    • Österwitz, Karl-HeinzSchmidt, Bernhard
    • F24J3/08F28D20/00
    • F28D20/0052F24T10/10Y02E10/12Y02E60/142Y02E70/30
    • The invention relates to a solar geothermal accumulator for household energy consumption, embodied as an unsaturated fluid-containing heat accumulator mass comprising at least one first partial system for entry and, at a defined distance, at least one second partial system for removal of heat energy, the partial systems being disposed with the corresponding partial systems entering and removing the heat in a storage space forming the solar geothermal accumulator and being open below and partially gas-tight. According to the invention, at least one bell-like upper seal and one circumferential side gas-tight seal (60O, 60S) of the storage space (40) of the solar geothermal accumulator (80) is made such that heat (10) can be fed into the storage medium comprising the unsaturated fluid of the solar geothermal accumulator (80) by the at least one first system, said heat causing the heating of the heat accumulator mass and the fluid within the solar geothermal accumulator (80) at substantially constant normal air pressure, and leading to evaporation of the fluid, whereby an amount of heat can be stored in the solar geothermal accumulator within the bell-like seal (60O, 60S) by means of the corresponding specific heat capacity / evaporation enthalpy of the liquid and gaseous fluid, said heat being removed by means of the at least one second system (20) by condensing the fluid and cooling the heat accumulator mass of the solar geothermal accumulator (80) and the fluid (80) present in the solar geothermal accumulator in order to utilize the heat in a central home energy system, wherein a humidification system (70) is disposed at least in the area of the upper seal (60O) and is intended to allow the heat storage capacity of the heat accumulator mass of the solar geothermal accumulator (80) in an optimal range for home energy usage by feeding in the fluid. An associated method ensures that heat (10) is supplied to the heat accumulator mass of the solar geothermal accumulator (80) comprising unsaturated fluid by the at least one first system, said heat heating the heat accumulator mass and the fluid within the solar geothermal accumulator (80) at substantially constant normal air pressure, and leading to evaporation of the fluid, whereby an amount of heat can be stored in the solar geothermal accumulator by means of the corresponding specific heat capacity / evaporation enthalpy of the liquid and gaseous fluid, said heat being removed by means of the at least one second system (20) by condensing the fluid and cooling the heat accumulator mass of the solar geothermal accumulator (80) and the fluid (80) present in the solar geothermal accumulator in order to utilize the heat in a central home energy system, wherein the heat storage capacity of the heat accumulator mass of the solar geothermal accumulator (80) is controlled and regulated in that fluid is fed into the solar geothermal accumulator (80) by means of a humidification system (70) in order to maintain the central home energy system in an optimal operating range, as a function of the physical boundary conditions acting on the solar geothermal accumulator (80).