DD233634A1 - CONTROL OF SOLAR COLLECTOR PLANTS - Google Patents

Abstract

The invention relates to a method for controlling solar collector systems for heat storage. This object is achieved according to the invention in that the electronic temperature difference control receives its measured values in each case from two measuring errors connected in parallel. The pairs of measuring pairs are arranged so that they measure the temperature difference between the solar collector and the storage tank when the system is at a standstill and give the signal for starting up the system. After start-up of the system, a self-sustaining continuous transition to the temperature difference measurement of the pair of measuring fins takes place between solar collector inlet and outlet, while the abovementioned temperature difference automatically becomes ineffective. A possible field of application is the control of the heating of heat storage for object heating or water heating.

Description

Field of application of the invention

The solution according to the invention is particularly suitable for heat supply systems whose heat accumulator receives the energy via a heat transfer medium to which the energy is supplied by a heat source of changing temperature, preferably by a solar collector system. The application area concerns all objects for which an object heating or a hot water preparation is to be realized.

Characteristic of the known technical solutions

The patent WP2412610163 deals with the specific problems of controlling solar panels, which are such that when the system is at rest other temperatures than when the circulating pump. For switching on the circulation pump, a temperature difference between a radiation measuring point on the solar collector and a hot water temperature measuring point in the lower area of the memory is used. Since the radiation measuring point largely represents an instantaneous idling temperature at the collector, a decrease is expected after commissioning. With an adjustable time delay, however, this power-on pulse will be present for a limited time. During start-up of the collector system, steady-state temperature conditions begin to set and positive difference between the flow and return temperatures characterize z. B. a heat absorption by the hot water tank. This temperature difference is also compared via an electronic circuit and as long as the difference is positive, the circulation pump remains in operation. Although this control realizes the additional heat gain for the solar collector system, but it must also be installed to achieve this effect, an electronic circuit board and an electronic timer relay.

Object of the invention

The application of the control according to the invention extends the scope of the necessary electronic components. Furthermore, the interaction of the temperature difference measurement for the startup of the solar collector system and for ongoing operation is designed continuously and increases the reliability of the controller.

Explanation of the essence of the invention

The application of the inventive solution allows the temperature difference measurement for the commissioning of the solar collector system and temperature difference measurement for ongoing operation can be performed with an electronic circuit and continue the interaction of the two temperature difference measurements continuously without switching threshold of an electronic switch. The most essential features of the invention are that in each case parallel to the sensor in the primary flow line and the primary return line, a further sensor is switched, ensures the temperature difference in cooperation with the control unit startup. The parallel sensor to the measuring point in the Pirmärvorlaufleitung is attached directly to the inlet nozzle of the solar collector and the parallel probe to the measuring point in the primary return line at the outlet nozzle of the heating coil from the heat exchanger or heat storage. The sensor at the inlet nozzle of the solar collector and the outlet nozzle of the heating coil are mounted so that they measure the local solar collector temperature or heat storage temperature at standstill of the system and measure the temperature of the heat transfer medium in the primary return line with sufficient accuracy when operating the circulating pump in the primary circuit.

embodiment

The solar collector system shown in Figure 1 with the heat storage 2 uses the solar radiation 8 on the solar collector 1. Above the solar collector 1, the primary return line 6 is connected, which opens into the upper terminal of the heating coil 7 of the heat accumulator 2. The cold water inlet 11 is led out into the lower part as hot water outlet 10. The primary return line 9 leads from outlet nozzle of the heating coil 7 to the inlet nozzle of the solar collector 1. Darin involved is the circulation pump 3 with the motor 4. The sensor 12 is to determine the temperature of the solar collector 1 at standstill of the system at the inlet nozzle of the primary return line 9 in the solar collector. 1 appropriate. The location of both sensors is to be designed so that they measure the local temperature in the solar collector 1 and in the memory 2 during the standstill of the solar collector system. When operating the system, both measuring points should measure the temperature of the heat carrier in the primary return line 9 and register the same temperatures. The measuring points 13 and 14 are respectively installed in the primary return line 9 and in the primary flow line 6. They are installed so that they are not affected by a solar collector warming at standstill of the system and are exposed to the same ambient temperature. The electronic control unit 5 turns on the motor 4 der Umwälzpumpe 3 with a positive temperature difference between the warm probes 12/14 and the cold probes 13/15. At standstill of the system, the sensor 13 and 14 have the same temperature and a positive temperature can only be triggered by heating the solar panel 1 or cooling of the memory 2. After start-up of the circulation pump 3, a temperature compensation takes place at the sensors 12 and 15 and the sensors take the temperature of the heat carrier in Primärkreislaufan. As long as the temperature difference between the sensors 14 and 13 is positive, the lower heat cycle, the resumption of heat radiation by the solar collector, the heat transfer and

Claims (2)

Erfindungsahspruch: 1. Control of solar collector systems with heat storage (2) and control unit (5), the circulation pump (3) in response to the temperature difference between the solar collector (1) and memory (2) on or off, characterized in that the sensor ( 12) and the sensor (14) and the sensor (13) and the sensor (15) are connected in parallel and the summarily measured temperature difference for generating the on or off pulse for the circulating pump (3) via the control unit (5) processed becomes. 2. Control of solar collector systems according to item 1, characterized in that the sensor 12 in the immediate vicinity of the inlet nozzle of the solar collector 1 and the sensor 15 in the immediate vicinity of the outlet nozzle of the heating coil 7 are mounted so that they during operation of the circulating pump (3) Temperature of the heat carrier in the primary circuit and at standstill each measure the local temperature of the memory (2) and the solar collector (1). For this 1 page drawing Field of application of the invention The solution according to the invention is particularly suitable for heat supply systems whose heat accumulator receives the energy via a heat transfer medium to which the energy is supplied by a heat source of changing temperature, preferably by a solar collector system. The application area concerns all objects for which an object heating or a hot water preparation is to be realized. Characteristic of the known technical solutions The patent WP2412610163 deals with the specific problems of controlling solar panels, which are such that when the system is at rest other temperatures than when the circulating pump. For switching on the circulation pump, a temperature difference between a radiation measuring point on the solar collector and a hot water temperature measuring point in the lower area of the memory is used. Since the radiation measuring point largely represents an instantaneous idling temperature at the collector, a decrease is expected after commissioning. With an adjustable time delay, however, this power-on pulse will be present for a limited time. During start-up of the collector system, steady-state temperature conditions begin to set and positive difference between the flow and return temperatures characterize z. B. a heat absorption by the hot water tank. This temperature difference is also compared via an electronic circuit and as long as the difference is positive, the circulation pump remains in operation. Although this control realizes the additional heat gain for the solar collector system, but it must also be installed to achieve this effect, an electronic circuit board and an electronic timer relay. Object of the invention The application of the control according to the invention extends the scope of the necessary electronic components. Furthermore, the interaction of the temperature difference measurement for the startup of the solar collector system and for ongoing operation is designed continuously and increases the reliability of the controller. Explanation of the essence of the invention The application of the inventive solution allows the temperature difference measurement for the commissioning of the solar collector system and temperature difference measurement for ongoing operation can be performed with an electronic circuit and continue the interaction of the two temperature difference measurements continuously without switching threshold of an electronic switch. The most essential features of the invention are that in each case parallel to the sensor in the primary flow line and the primary return line, a further sensor is switched, ensures the temperature difference in cooperation with the control unit startup. The parallel sensor to the measuring point in the Pirmärvorlaufleitung is attached directly to the inlet nozzle of the solar collector and the parallel probe to the measuring point in the primary return line at the outlet nozzle of the heating coil from the heat exchanger or heat storage. The sensor at the inlet nozzle of the solar collector and the outlet nozzle of the heating coil are mounted so that they measure the local solar collector temperature or heat storage temperature at standstill of the system and measure the temperature of the heat transfer medium in the primary return line with sufficient accuracy when operating the circulating pump in the primary circuit. embodiment The solar collector system shown in Figure 1 with the heat storage 2 uses the solar radiation 8 on the solar collector 1. Above the solar collector 1, the primary return line 6 is connected, which opens into the upper terminal of the heating coil 7 of the heat accumulator 2. The cold water inlet 11 is led out into the lower part as hot water outlet 10. The primary return line 9 leads the outlet nozzle of the heating coil 7 to the inlet nozzle of the solar collector 1. Darin involved is the circulation pump 3 with the motor 4. The sensor 12 is to determine the temperature of the solar collector 1 at standstill of the system at the inlet nozzle of the primary return line 9 in the solar collector 1 attached. The location of both sensors is to be designed so that they measure the local temperature in the solar collector 1 and in the memory 2 during the standstill of the solar collector system. When operating the system, both measuring points should measure the temperature of the heat carrier in the primary return line 9 and register the same temperatures. The measuring points 13 and 14 are respectively installed in the primary return line 9 and in the primary flow line 6. They are installed so that they are not affected by a solar collector warming at standstill of the system and are exposed to the same ambient temperature. The electronic control unit 5 switches at a positive temperature difference between the warm probes 12/14 and the cold sensors 13/15 the motor 4 of the circulation pump 3 a. At standstill of the system, the sensor 13 and 14 have the same temperature and a positive temperature can only be triggered by heating the solar panel 1 or cooling of the memory 2. After start-up of the circulation pump 3, a temperature compensation takes place at the sensors 12 and 15 and the sensors assume the temperature of the heat carrier in the primary circuit. As long as the temperature difference between the sensors 14 and 13 is positive, the lower heat cycle, the resumption of heat radiation by the solar collector, the heat transfer and