DE29601542U1 - Transfer station for the storage and use of solar heat and / or other low-temperature heat - Google Patents

Description

01.96 -1- 24.01.96

Description

The present invention relates to thermal systems in which heat supplies from "fluctuating" heat sources, which typically vary in temperature and power, are fed to a useful application with a temperature and heat output regulated as required after short, medium or long-term heat storage. Typical fluctuating heat sources are the heat supply from solar collectors, but also the waste heat supply from machines and systems, including combined heat and power systems. Examples of useful applications for these heat supplies are the heating of domestic water and the heating of buildings. If the temperature and/or power of the fluctuating heat sources are not sufficient to cover the useful heat requirement, the heat from a fuel-fired heat generator or an electric heater is usually used for additional heating. The aim of the thermal systems described is to replace fossil fuels as far as possible and to save energy costs associated with this. while simultaneously reducing environmental impact.

Systems of the type and purpose described have been individually planned, built and operated for specific applications for years with varying degrees of success. The difficulties that frequently arise affect both the technical function and the economic result; the reasons for this are described below.

The state of the art is characterized by the fact that - usually by a planning office - the system configuration is developed and the necessary technical components, such as heat exchangers, valves and fittings, pumps, control/regulation, etc. must be individually selected, tendered and procured. As a rule, various trades such as plumbing, heating construction, electrics/electronics must be planned. The construction of these systems takes place

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according to implementation plans for the individual trades and is carried out by hand on the construction site, usually over a longer period of time. The technical components are installed on walls or auxiliary scaffolding.

The planning and manufacturing method described has serious, fundamental disadvantages. The task, which is usually set in the same way, is handled completely differently by each individual, which leads to very different technical and functional system concepts and configurations. The technical function therefore depends exclusively on the level of knowledge, experience and skill of the planner. The expected system benefit is uncertain for the client. Since acceptance tests for a guaranteed heat supply have to be carried out over a long period of time, which is very complex, the energy and economic benefit is rarely evaluated. The trust of potential clients is correspondingly low. Another difficulty is the technical coordination, authority and responsibility for the various trades. If there are difficulties with the system, disputes often arise. Due to their individual structure, commissioning the systems requires a longer observation and adjustment period for all expected operating conditions. .The most serious shortcoming of this state of the art is the associated high costs, which make practically all systems of this type uneconomical.

With the present invention, the described deficiencies are eliminated by standardizing a system configuration that includes all functions and is delivered to the construction site as a compact transfer station ready for connection. Approaches to such a compact, prefabricated station are available on the market for small, thermal solar systems for domestic water heating, where on the one hand a solar collector and on the other hand a conventional domestic water storage tank with an internal heat exchanger for heating the domestic water are to be connected. This configuration is suitable for systems with a higher output with

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correspondingly large or very large heat storage cannot be meaningfully transferred.

A special feature of the present invention is that, in addition to connecting the heat source, the heat utilization system and the after-heating with connecting pipes, only the heat storage unit as a container without any fittings for heat transfer or temperature-appropriate heat stratification needs to be connected to the compact heat transfer station in order to obtain an operational system. This storage container can be operated with any static pressure, i.e. with atmospheric pressure, negative or positive pressure. The storage volume can be designed as a single-container or multi-container design, as a basin storage unit or as a natural or artificial aquifer storage unit, depending on requirements. Heat storage units of this type are, according to the invention, loaded from above with the storage fluid, the temperature of which is constantly regulated to a selectable target temperature by the heat transfer station. This approach offers several advantages at the same time: with each loading process, the temperature stratification in the storage tank is renewed, whereby storage fluid with the desired target temperature for heat use is available at the earliest possible time and the capacity of the heat storage tank is used to the maximum when fully loaded. This means that the system can be operated with a minimum of reheating and a maximum of storage capacity.

According to the invention, the compact heat transfer station contains all the mechanical and electrical/electronic components required for heat transfer between the fluid circuits, for controlling and regulating heat transfer, as well as for system operation and system safety, including the sequence program in an assembly enclosed in a housing. After the heat transfer station has been set up, assembly is limited to the connecting pipes. Only a few sensors need to be installed and connected outside the heat transfer station.

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The invention is shown by way of example and described in more detail with reference to Fig. 1.

Fig. 1 shows a schematic of the compact heat transfer station 1, divided into the modules loading la, unloading Ib, reheating Ic and control/regulation Id for a better overview and ease of assembly and maintenance. The module loading la has connections 3, 4 for the heat source and connections 5, 6 for the storage tank loading. The unloading Ib module has connections 7, 8 for the storage tank unloading and connections 9, 10 for the heat utilization system. The reheating Ic module has connections 11, 12 for the reheating boiler and connections 13, 14 for the reheating of the upper storage standby section 2a. The heat storage tank 2 is shown schematically as a container with the connections 5, 6 corresponding to the heat transfer station for the storage tank loading, the connections 7, 8 for the storage tank unloading and the connections 13, 14 for the reheating of the upper storage standby section 2a. With the completion of the connecting pipes and the filling of the liquid circuits, the system is ready for operation. If required, the heat transfer station can be equipped with additional connections for expansion vessels and filling/emptying containers for the individual circuits. To operate this exemplary configuration Fig.l, only an external temperature sensor 15 is required to control the reheating of the upper storage standby section 2a.

Fig. 2 shows an example of an extended variant of the compact heat transfer station 1. This extension only affects the loading modules la and control/regulation Id, which is why the other connections are not labeled in Fig. 2. Here too, the storage tank is primarily loaded with a regulated target temperature from above via connection 5. However, with fluctuating heat sources, it can happen that the desired target temperature is not reached. In this case, the storage fluid with a lower temperature is layered via one or more lower storage connections 5a, whereby the target temperature to be regulated is measured in each case with a temperature sensor 16 arranged in the storage fluid at these connection points 5a. The hydraulic switching

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between connections 5 and 5a is carried out by a changeover valve located inside the loading module la and controlled by the control/regulation module Id.

Analogous to the zone loading of a storage tank or several storage tanks connected in series described in Fig. 2, the heat transfer station 1 can be designed as a further variant with a zone discharge via corresponding storage connections and the discharge module Ib.

This variant is described as an example in Fig. 3, whereby the names of the other, irrelevant connections are omitted. If the operating state occurs that the storage fluid temperature at the location of the temperature sensor 17 is already sufficient to achieve the required fluid temperature at the useful heat connection 10, the heat storage unit is discharged with priority via a discharge connection 8a arranged in the area of the temperature sensor 17. This operating state occurs, for example, when the useful heat temperature is reduced or when the heat storage unit is fully loaded. The hydraulic switching between the connections 8 and 8a takes place via a switching valve arranged inside the discharge module Ib and controlled by the control/regulation module Id.

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Reference symbol

1 compact heat transfer station

2 heat storage tanks

2a Heat storage - standby part

3.4 hydraulic connections for the heat source

5.6 hydraulic connections for storage charging

5 a hydraulic connection for storage zone loading

7.8. hydraulic connections for storage discharge

8a hydraulic connection for storage zone discharge

9, 10 hydraulic connections for the heat utilization system

11,12 hydraulic connections for the after-heating

13, 14 hydraulic connections for storage tank reheating

15 external temperature sensor for controlling the storage tank reheating

16 external temperature sensors for controlling the local storage zone loading

17 external temperature sensor for controlling the storage zone discharge

Claims (11)

01.96 -1- 24.01.96 ■rahsprüi —jgateayahsprfiche 1. Transfer station for the storage and use of solar heat and/or other low-temperature heat, whereby a storage fluid circuit with heat storage is interposed between the external fluid circuit with the heat source and the internal fluid circuit with the heat utilization, characterized in that all mechanical and electrical/electronic components required for the heat transfer between the fluid circuits, for the control and regulation of the heat transfer, as well as for the system operation and system safety are arranged in a central assembly enclosed by a housing, so that in order to produce the functional system, only the heat source, the external storage container and the heat utilization system with connecting pipes need to be connected. 2. Heat transfer station according to claim L, characterized in that the heat of the heat source supplied with variable temperature and power is converted by the transfer station into heat with a regulated storage fluid target temperature for charging the storage tank. 3. Heat transfer station according to claims 1 and 2, characterized in that the hydraulic separation of the heat source circuit and the heat utilization circuit from the heat storage circuit means that the heat storage can be operated with any static pressure - i.e. with atmospheric air pressure, negative or positive pressure. 4. Heat transfer station according to patent claims 1 to 3, characterized in that the storage fluid with a constantly regulated target temperature is layered into the storage tank from above and, in the case of a series connection of several storage tanks, from above. 01.96 . -2- 24.01.96 5. Heat transfer station according to claims 1 to 4, characterized in that when the heat source temperature is reduced, an intermediate feed is made at a reduced and regulated target temperature into the lower zone of the storage tank or, analogously, when several storage tanks are connected in series, into one of the downstream storage tanks. 6. Heat transfer station according to claims 1 to 5, characterized in that the transfer station contains a device including a control for feeding reheating heat into the storage circuit. This device is activated when the fluctuating heat source can only partially cover the heat requirement. 7. Heat transfer station according to patent claims 1 to 6, characterized in that when useful heat is required, the storage fluid is taken from the uppermost zone of the storage tank or the storage tank series connection and is converted into heat with a regulated target temperature in the useful heat circuit. 8. Heat transfer station according to patent claims 1 to 7, characterized in that when the useful heat temperature is reduced, an intermediate withdrawal of storage fluid takes place from the lower zone of the storage tank or the storage tank series connection and is converted into heat with a regulated target temperature in the useful heat circuit. 9. Heat transfer station according to patent claims 1 to 8, characterized in that plate heat exchangers are preferably used inside the station for loading, unloading and reheating, whereby the heat output adjustment is achieved with the same structure and the same positioning of the heat exchanger connections only by a variable number of plates of the plate heat exchangers. 01.96 -3- 24.01.96 05 10. Heat transfer station according to claims 1 to 9, characterized in that the transfer station is protected against uncontrolled heat losses to the environment by an insulating housing. 11. Heat transfer station according to claim 10, characterized in that 10 components which are not exposed to the increased temperature in the insulating housing may be arranged outside the insulating housing or protrude into the cooling environment through suitable cutouts in the insulating housing.