The invention relates to a method for operating a tank for holding a liquid in a sanitary installation in a rail vehicle.
In rail vehicles, various tanks are used as components of the sanitary installation. Specifically, these are, for example, a fresh-water tank, a wastewater tank and a gray-water tank. All of these tanks should be protected from frost damage when the rail vehicle is operated in winter. In this connection, it is necessary to comply with regulations, for example International Union of Railways guidelines, which demand that the sanitary installations should remain operational within certain limits at outside temperatures below freezing, without suffering frost damage.
For this purpose, in known methods, in the case of correspondingly low outside temperatures, the tanks are heated with heating means which are installed in or on the thermally insulated fresh-water, gray-water or wastewater tank, in order to prevent the tanks from freezing. Connected pipelines are closed off and drained if they contain fresh water or gray water.
Such an operating method for tanks in sanitary installations involves a fair amount of outlay, since additional components, namely the heating means, have to be provided in order to avoid frost damage to the tanks.
On this basis, it is the object of the invention to further develop a method for operating a tank of the type mentioned at the beginning such as to allow less outlay with regard to the tank installation while the necessary frost protection is provided.
This object is achieved by a method for operating a tank for holding a liquid in a sanitary installation in a rail vehicle, in which
The method is based on the fact that the tank is operated differently depending on whether the degree of filling falls below or exceeds the predetermined degree of filling. It is taken into account in step b) that a well-filled tank allows a certain formation of ice without suffering frost damage. By contrast, tanks with a low degree of filling are likely to suffer frost damage much more quickly, and so in this case method step c) or d) is carried out.
The predetermined degree of filling is selected specifically for the tank in question, which is operated according to this method, such that said degree of filling ensures that the tank is frost-proof for a relevant outside temperature range which may depend on the use conditions of the rail vehicle or can be taken from regulations, for example International Union of Railways guidelines, for a sufficiently long period of time, which typically lasts several dozen hours.
Specifically, the predetermined degree of filling is selected in a manner specific to the tank and dependent on the tank size and tank insulation and dependent on a relevant outside temperature range. It is conceivable for the predetermined degree of filling to be determined first of all empirically for a particular tank, with the value determined in this way being used in the method presented here for operating a tank.
Generally, substantially independently of the type of tank, the predetermined degree of filling may be between 5% and 60%.
Following step b), c) or d), if the tank is a fresh-water tank, the tank may be refilled in order to continue operation.
A different procedure should be adopted for wastewater tanks and gray-water tanks; in this case, following step b), in order to continue operation, the tank may be filled up, for example to at least 90%, via a flushing connection, and subsequently be emptied.
In the case of a wastewater tank or gray-water tank which was emptied after step c), operation can be continued.
An exemplary embodiment of the invention is explained in more detail in the following text with reference to the drawing. The single FIGURE shows a graph illustrating non-damaging formation of ice for an exemplary tank having a volume of 400 liters and a predetermined degree of filling x=25%.
In the graph illustrated in the FIGURE, the temperature is indicated on the Y-axis in arbitrary units and the time is indicated on the X-axis, likewise in arbitrary units. A dashed line shows the temperature profile for a rail vehicle as a whole, in which the tank in question here is installed, while a dotted line represents a cooling curve for tank contents.
It is apparent that the cooling curve for the rail vehicle as a whole drops heavily early on and then remains constant at a distance from the freezing point 0° C. By contrast, the temperature of the tank contents drops less steeply to the freezing point and then remains there. Ice begins to form in the tank after the freezing point has been reached, and this typically lasts for several hours. After this cooling phase, there starts a phase in which the melting enthalpy within the tank is output, and this contributes to non-damaging ice formation occurring for a sufficiently long period of time, which is typically several dozen hours. The time period for which no frost damage to the tank should be expected depends substantially on the insulation of a tank, the time profile of the ambient temperature and the filling of a tank (filling level and medium).
Within the meaning of an operating method for ensuring frost protection for the tank, the degree of filling of 25% assumed here for the heat calculation illustrated is a degree of filling which is equal to or above a predetermined degree of filling, at which ice formation is allowed over a period of time predetermined for the tank.
In this case, the degree of filling of any desired tanks can be either sensed automatically or set manually. If the degree of filling falls below the degree of filling predetermined for the tank, possibly even after step d) has been carried out, the tank is emptied as per step c).
The method presented makes it possible for a component, namely the tank heating means, of a water installation in the rail vehicle to be dispensed without further components being added. The degree of filling of a fresh-water tank is usually measured anyway, and in the case of a wastewater or gray-water tank, the degree of filling has to be determined if appropriate in some other way.
In addition to the reduction in costs for additional heating components, advantages are also achieved with regard to energy consumption, demands on the on-board power supply, water quality (if the heating means was installed in the tank), replacement parts and maintenance.
Number | Date | Country | Kind |
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10 2009 024 653 | Jun 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/057643 | 6/1/2010 | WO | 00 | 12/12/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/142577 | 12/16/2010 | WO | A |
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