DE202012011625U1 - Hot water tank for process water with solar module - Google Patents

Abstract

Hot water tank for service water, comprising a housing (1), an insulating layer (2) for thermal insulation, a storage enclosure (3) enclosing the storage interior (4), and a cold water line (7) and a hot water pipe (8) to or from the storage interior (4), characterized in that the outside of the storage enclosure (3) of the hot water tank with a planar heating means (6) is heat-conductively coated, and that at least one photovoltaic module (10) the heating means (6) via an electrical line (5) with electrical Energy supplied for heat production.

Description

The present invention relates to a hot water tank for service water, in which a arranged on the outside of the storage shell of the hot water tank planar heating means is connected to a solar module for heat generation.

Warm or heating water accumulators with a heatable chamber have been part of hot water systems in buildings for many years. In today's residential complexes is usually a separation of the heating system from the hot water device instead. For example, the function of the boiler can be taken over a hydraulic separation of the heating circuit and storage circuit via a heat exchanger. However, the use of such hot or Heizwasserspeicher requires a high energy input to keep the water at target temperature. In part, this latent heat storage used, as used for example in the DE 10 2012 002 952 A1 or the DE 10 2011 001 273 A1 are described.

In addition, solutions are known in which the hot or Heizwasserdruckspeicher is designed as a single or battery storage and in which the heat exchanger at any time of the day an equal amount of heat energy is supplied. In the interior of the separated chamber may be mounted on its outer wall mounted one or more heating elements, such as an electric radiator.

A buffer tank for hot water is in the DE 20 2011 003 667 U1 described. In one embodiment, it is provided that a feed opening and a discharge opening are connected to a solar device. In this case, the solar device should be coupled into a circuit whose liquid solar medium is guided without contact with the liquid medium in the inner volume of the buffer in a arranged in the volume of the buffer heat exchanger of the solar device. In this way, a thermal energy transfer should take place.

In the DE 10 2011 052 452 A1 a hot water storage is described in which in an inspection opening at least one electrical resistance heating element is used, which is connected to the power supply via an electrical line to a photovoltaic system. A heating of the memory contents by the photovoltaic system is not provided in this embodiment.

The known solutions try on the one hand to increase the efficiency of a hot water tank, on the other hand, however, to improve energy efficiency and heat conduction.

In electrically operated hot water tanks, however, there is still a high energy demand for the production of hot water and maintenance of the respective target temperature. The operation of inverters is energy-consuming. In view of the ever increasing electricity costs, such solutions are still satisfactory.

Against this background, it is an object of the present invention to provide a modified hot water tank for service water, in which a continuous and latent energy supply for heating the storage contents over long periods takes place.

This object is achieved by a hot water tank with the features of claim 1. Preferred embodiments can be found in the subclaims again.

The hot water storage according to the invention comprises a housing with a subsequent insulation layer for thermal insulation. A storage enclosure or a boiler encloses the storage interior, in which the liquid medium, for. B. hot water is stored. In addition, the hot water tank has a conventional cold water supply and hot water discharge to or from the storage interior. According to the invention, it is provided that the outer side of the storage envelope of the hot water storage tank is coated in a heat-conducting manner with a planar heating means and that at least one photovoltaic module supplies the heating means with electrical energy for generating heat via an electrical line. Thus, the invention fulfills two key points: on the one hand, the memory core is not equipped with a heating element (eg heating cartridge) or an electric heater, but with a flat heating medium, which due to the large surface area and areal radiation provides good heat transfer with low heat losses ensures. On the other hand, the planar heating means receive the energy required for heating via the connected photovoltaic modules.

Preferably, the heating means is a heating foil. Depending on the embodiment, however, heating tapes or heating mats can also be used to cover the storage envelope of the hot water storage tank. In this case, the outside of the storage enclosure can be completely surrounded by the heating medium. Depending on the type of hot water tank, however, a partial sheathing of the outside of the storage enclosure with the heating means may be sufficient.

To provide the required voltage, preferably two or more photovoltaic modules are connected in series.

Through the use of photovoltaic modules and the DC voltage used is a continuous energy delivery to the heating medium of the hot water tank. Depending on the number of photovoltaic modules used, a sufficient supply of energy is ensured even in cloudy conditions. At low temperatures, the photovoltaic modules are particularly efficient.

For higher energy requirements, a hybrid can also be provided in addition, in which the hot water tank is supplied via a heat exchanger or a heating cartridge.

Furthermore, in a preferred embodiment, a control unit may be interposed between the at least one photovoltaic module and the heating means for voltage control.

In comparison to systems in which inverters are used which are extremely power-intensive, the system according to the invention can be operated with continuous power output in the low-voltage range. Typical inrush currents, which are associated with a high energy loss, are avoided. The system according to the invention can be operated autonomously, which represents a decisive advantage in energy saving. Existing plants can be retrofitted with a photovoltaic module according to the invention, which is connected to the heating means. This allows a cost-effective solar hot water supply in buildings.

Furthermore, no pipelines are necessary, as they are common in thermal solar systems. Since only the power supply of the heating medium must be ensured by the photovoltaic modules, a cost-effective installation in a new building or as part of a retrofit is possible.

The PV modules can be placed exactly on the heating elements, eliminating the need for complex control technology.

Photovoltaic modules are superior to conventional thermal modules, especially at low temperatures or in cloudy conditions, as their efficiency is increased.

The hot water storage according to the invention can be designed both for stationary operation as well as for portable or mobile operation. For example, it would be possible to use a hot water tank with appropriately equipped photovoltaic modules as part of a camping equipment. Autonomous operation via photovoltaic modules enables continuous heat output and provision of hot water.

The present invention can not only be used to maintain the temperature of process water, but is basically suitable for all liquid media. In one embodiment, the device according to the invention therefore comprises a hydraulic fluid or an oil as the medium.

The invention will be explained in more detail in the following drawings.

In the 1 an inventive hot water tank is shown. This consists of a housing 1 , an insulation layer 2 for thermal insulation and a storage enclosure 3 that the storage interior 4 encloses. At the bottom are a cold water supply 7 and a hot water drainage 8th to recognize. The outside of the storage case 3 of the hot water tank is with a flat heating medium 6 coated thermally conductive. In the embodiment shown, only a part of the casing can be seen. The heating medium 6 is via an electrical line 5 with a photovoltaic module 10 connected. This supplies the heating medium 6 with electrical energy for heat generation.

As a heating medium 6 For example, heating foils with an operating voltage of 12 or 24 V at 20 W power can be used. These heating foils are then two or more photovoltaic modules 10 connected. In addition, the use of heating mats or heating tapes is possible. Optionally, depending on the embodiment, a voltage control may be necessary. Such a voltage control takes over, for example, a control unit 11 ,

To ensure the function of the hot water tank can be heated in the usual way, for example by a heating element 9 standing in the store interior 4 is guided.

Through a serial or parallel wiring of the photovoltaic modules 10 is a simple adaptation of the performance of the surface heating medium 6 to the performance of the photovoltaic modules 10 possible. For example, four series-connected heating foils, each with 12 V from a photovoltaic module 10 or several photovoltaic modules connected in parallel 10 be operated with 48V. The heating foils warm up to about 75 ° C at maximum photovoltaic module output. Specially designed heating foils, heating tapes or heating mats can also be operated at higher temperatures.

In the embodiment shown, for example, with a total power of 0.1 kW hours in a period of 10 hours under optimal conditions, a heating power of 1 kW can be achieved.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102012002952 A1 [0002]
• DE 102011001273 A1 [0002]
• DE 202011003667 U1 [0004]
• DE 102011052452 A1 [0005]

Claims (11)

Hot water storage tank for service water, comprising a housing ( 1 ), an insulation layer ( 2 ) for thermal insulation, a storage enclosure ( 3 ), the memory interior ( 4 ) and a cold water line ( 7 ) and a hot water pipe ( 8th ) to or from the storage interior ( 4 ), characterized in that the outside of the storage envelope ( 3 ) of the hot water storage tank with a flat heating medium ( 6 ) is coated thermally conductive, and that at least one photovoltaic module ( 10 ) the heating means ( 6 ) via an electrical line ( 5 ) supplied with electrical energy for heat generation. Hot water storage tank according to claim 1, characterized in that the heating means ( 6 ) with two or more photovoltaic modules ( 10 ) connected is. Hot water tank according to claim 1 or 2, characterized in that it is in the heating means ( 6 ) is a heating foil. Hot water tank according to claim 1 or 2, characterized in that it is in the heating means ( 6 ) is a heating tape. Hot water tank according to claim 1 or 2, characterized in that it is in the heating means ( 6 ) is a heating mat. Hot water tank according to one of claims 1 to 5, characterized in that the outside of the storage envelope ( 3 ) only partially with the heating means ( 6 ) is sheathed. Hot water tank according to one of claims 1 to 5, characterized in that the outside of the storage envelope ( 3 ) completely with the heating medium ( 6 ) is sheathed. Hot water tank according to one of claims 1 to 7, characterized in that between the at least one photovoltaic module ( 10 ) and the heating means ( 6 ) is interposed a control unit for voltage control. Hot water tank according to one of claims 1 to 8, characterized in that the device is designed for stationary operation. Hot water tank according to one of claims 1 to 8, characterized in that the device is designed for portable or mobile operation. Hot water tank according to one of claims 1 to 10, characterized in that the device for maintaining the temperature of another liquid medium is designed as water such as hydraulic fluid or oil.

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