DE102005008646B3 - Solar plant for hot water and heating has regulating valve in outward line of solar circuit - Google Patents

Abstract

The solar plant has a regulating valve (19) in the outward line (6) of the solar circuit, which controls the heated fluid, depending on the collector temperature, the temperature in the solar circuit, the heat requirement in at least one heating circuit, the operating state of the heating apparatus (9) and/or the charge state of the hot water store (1), which itself depends on the heat exchanger (5).

Description

The Invention relates to a solar system for water heating and Heating support after the preamble of claim 1.

solar systems for water heating consist essentially of a hot water tank, to the one Hot water pipe is connected. This one has a special one Solar storage normally a heating coil as a heat exchanger for the over one Solar circuit introduced solar heat in the lower area as well another heat exchanger in the upper area for the so-called recharging by a heater. This will only the upper Area of the hot water tank warmed to one below as possible keep low temperature for feeding solar heat. For one Great Efficiency of the solar system, it is of course important in principle that primarily the solar heat supply is used to heat the hot water tank. A recharge through the heater should therefore, if possible only in a few cases respectively.

Known solar systems for heating support work with so-called buffer tanks. These are storage tanks for heating water with an integrated hot water tank with a smaller volume, essentially in the upper tank area. The DE 100 54 628 A1 shows such a buffer memory. The solar heat is supplied via a heat exchanger in the hot water tank, ie in the drinking water part. The supply and return lines of the heater or the heating circuits are connected to the surrounding area with heating water. Thus, the solar heat is always discharged in these systems via the buffer memory for heating support. Due to the relatively large water content creates a corresponding inertia to heat the contents of the buffer memory. On the other hand, only a slight increase in temperature in the buffer memory can be achieved if only little solar heat is available. This problem occurs especially in the winter or in low sunlight. So, especially when there is usually a need for heating support.

Of the Invention is therefore the object of a solar system for Hot water preparation and heating support, especially with regard to on the operation in low sunlight, to optimize.

According to the invention this is solved with the features of claim 1. Advantageous developments are the dependent claims refer to.

The Solar system is characterized in that in the flow line of the solar circuit a control valve is installed, which the solar heated heat transfer medium dependent on from the collector temperature, from the temperature in the solar circuit, from heat demand in at least one heating circuit, the operating state of the heater and / or from State of charge of the hot water tank, in whole or in part, over the Heat exchanger in lower portion of the hot water tank and / or primary side via a heat exchangers for heating support passes. This is the heat exchanger for heating support on the secondary side with a preferably fast-opening Three-way valve to the return line of the heater connected. As a result, the heating medium is preheated and the temperature in the return always directly from the heater detected.

Preferably There is a thermal in the supply line of the solar circuit Three-way valve used, which works without auxiliary power. The temperature sensor of the thermal three-way valve detects the temperature in the Belonging to the solar cycle, primary side Return line of the Heat exchanger.

The solar heat will be given priority over the heat exchanger for the heating support to disposal posed. The built-in the supply line of the solar circuit three-way thermal valve has an adjustable trip temperature threshold, at the time of it completely open is. Already below this threshold, it begins slowly proportional to Temperature rise to open so that a part of the volume flow or the solar heat through the heat exchanger enters the lower area of the hot water tank. It lies the adjustment range at the thermal three-way valve approximately between 40 ° C and 70 ° C.

The built in the flow line of the solar circuit thermal Three-way valve has in an advantageous embodiment an adjustable switching function for summer and winter operation, the lower Trigger temperature threshold preferably at about 40 ° C the summer mode and the upper trip temperature threshold with preferably about 70 ° C is assigned to winter operation.

For a ready-to-connect unit all necessary for the solar system according to the invention control technical elements are summarized. These include in particular the built in the flow line of the solar circuit thermal three-way valve, the heat exchanger, the at least one secondary-side, preferably fast-opening three-way valve, the control device, the pump in the solar circuit and display and control devices.

With an additional temperature sensor in the return line of the solar circuit becomes the return temperature recorded in the area of the pump to the speed of the pump in the solar circuit or to regulate the volume flow exactly adapted.

With the invention is a solar system for water heating and Heating support to available which in particular with regard to operating times at relatively low Solar radiation, especially when there is a need for heating support, optimal use of solar heat allows. The system reacts quickly, recycles the solar heat generated immediately, comes with significantly smaller hot water storage volume than conventional system, and is very compact. The heating water and hot water temperatures are completely different from each other decoupled. It is omitted according to the invention, a relative great To warm water volume in at least one buffer in times when the sun is not shining, so this when sizing the heater no longer needs to be considered. Also for retrofitting a existing system, the system of the invention is very good, because changes concern only the solar station as a ready-to-connect unit.

The Drawing represents an embodiment of Invention is and shows a flowchart in a single figure with the essential components of a solar system according to the invention.

The solar system for water heating and heating support consists of a hot water tank 1 with a connection 2 for hot water extraction, with one connection 3 for cold water supply, with temperature sensors 4 . 4 ' for detecting the hot water temperature, a heat exchanger 5 for heating the hot water tank 1 in the lower area with solar heat from a solar circuit with a supply line 6 and a return line 7 , a heat exchanger 8th for heating the hot water tank 1 with heat from a heater 9 with a heating circuit, consisting of a supply line 10 and a return line 11 over a heat consumer 12 , at least one temperature sensor 13 for detecting the temperature in the return line 11 of the heating circuit, a temperature sensor 14 for detecting the collector temperature in the solar collector 15 , a control device 16 as well as pumps 17 . 18 in every cycle.

In the supply line 6 of the solar circuit is a thermal three-way valve 19 built-in. This directs the solar heated heat transfer medium from the supply line 6 , depending on the current system operating condition, in whole or in part via the heat exchanger 5 in the lower part of the hot water tank 1 and / or primary side via a heat exchanger 20 for heating support. A thermal three-way valve 19 assigned temperature sensor 21 recorded on the primary side, the return temperature in the connecting line 22 between the heat exchanger 20 and the return line 7 , Furthermore, there is a to the control device 16 connected temperature sensor 23 in the flow line on the primary side of the heat exchanger 20 ,

The temperature sensor 23 records the available temperature in the solar circuit. This changes permanently, depending on the clouds in the sky. The measured temperature difference between the temperature sensors 13 and 23 is decisive for the control of the solar heat input by the control device 16 namely, the fast opening or closing three-way valve 24 in the return line 11 of the heater 9 , which is the secondary-side connection of the heat exchanger 20 represents. In the reverse case is also a quick closing of the three-way valve 24 in the return line 11 of the heater 9 important. For example, it must be avoided in case of sudden lack of sunlight, that the return water on the secondary side via the heat exchanger 20 flows. Otherwise, energy losses would occur, because then possibly the heating circuit gives off heat to the solar circuit.

This connection is located upstream of another three-way valve 25 , Its function is well known, because it serves to switch the flow between normal heating via the heat consumer 12 and the return line 11 or hot water preparation via the heat exchanger 8th in the upper area of the hot water tank 1 , for example on request based on the measured values on a temperature sensor 4 . 4 ' , Thus, the three-way valve 25 always continuous to the return line 11 switched to the heating medium before entering the heater 9 preheat. Is sufficient solar heat over the heat exchanger 20 available, so in the heater 9 Integrated temperature sensor also cause no burner start. Is the specified temperature for the heater based on the heat demand 9 higher, the burner starts and ensures a corresponding additional heating of the heating medium.

If, for example, in the morning, the solar energy only after a hot water withdrawal to Ver is available, has the hot water tank 1 already on the recharging by switching on the heater 9 reaches its setpoint temperature in the upper range again. The morning sun initially brings low temperatures, which, however, are sufficient in a well-balanced heating system to the heating circuit on the heat consumer 12 to provide energy during most of the year. The available solar energy is immediately used effectively.

If the temperature rises after the heat exchanger 20 to values above 70 ° C, so for example when the heating circuit on the heat consumer 12 only small amounts of heat decrease, then opens the thermal three-way valve 19 proportional and gives the flow to the hot water tank 1 free. The existing solar heat surplus can then the hot water tank 1 from bottom to top to 95 ° C to warm and thus form a supply of hot water. This will happen especially during the transitional period and in the summer.

It also shows the importance of a variable trip temperature threshold for the thermal three-way valve 19 on the one hand because of the optimal adaptation to the prevailing operating and plant conditions and on the other hand with regard to the comfort and energy saving needs of plant users. With the switching function according to the invention for summer and winter operation, this setting is simple and understandable.

With the additional temperature sensor 26 in the return line 7 of the solar circuit becomes the return temperature in the area of the pump 18 detected. After these measurements, the speed of the pump 18 regulated, for example, to adjust the temperatures in the solar circuit run on the volume flow exactly the current solar input on the one hand and the heat demand on the other side.

The three-way valve 27 in the supply line 10 the heating circuit prevents, for example, its unwanted heating with registered solar energy in summer and in the transitional period.

Claims (8)

Solar system for hot water and heating support, consisting of at least one hot water tank with temperature sensors for detecting the hot water temperature, a heat exchanger for heating the hot water tank in the lower area with solar heat from a solar circuit with a flow and return line, a heat exchanger for heating the hot water tank with heat from a heater with at least one heating circuit with a supply and return line via a heat consumer, at least one temperature sensor for detecting a temperature in the heating circuit, a temperature sensor for detecting the collector temperature, a control device and in each case one pump in each circuit, characterized in that in the flow line ( 6 ) of the solar circuit, a control valve ( 19 ) is installed, which the solar heated heat transfer medium as a function of the collector temperature, the temperature in the solar circuit, the heat demand in at least one heating circuit, the operating state of the heater ( 9 ) and / or the state of charge of the hot water storage tank ( 1 ), in whole or in part, via the heat exchanger ( 5 ) in the lower part of the hot water tank ( 1 ) or primary side via a heat exchanger ( 20 ) leads to the heating support. Solar installation according to claim 1, characterized in that the heat exchanger ( 20 ) for heating support on the secondary side with a three-way valve ( 24 ) to the return line ( 11 ) of the heater ( 9 ) connected. Solar installation according to claim 1 or 2, characterized in that in the flow line ( 6 ) of the solar circuit built-in control valve ( 19 ) is a thermal three-way valve, and that the temperature sensor ( 21 ) of the three-way thermal valve ( 19 ) the temperature in the solar circuit belonging, primary-side return line ( 22 ) of the heat exchanger ( 20 ) detected. Solar installation according to one of claims 1 to 3, characterized in that the solar heat primarily via the heat exchanger ( 20 ) is provided for the heating support. Solar installation according to one of claims 1 to 4, characterized in that in the flow line ( 6 ) of the solar circuit built-in thermal three-way valve ( 19 ) has an adjustable trip temperature threshold, wherein the adjustment range is about 40 ° C to 70 ° C. Solar installation according to one of claims 1 to 5, characterized in that in the flow line ( 6 ) of the solar circuit built-in thermal three-way valve ( 19 ) has an adjustable switching function for summer operation and winter operation, wherein the lower triggering temperature threshold is associated with preferably about 40 ° C the summer mode and the upper trip temperature threshold, preferably about 70 ° C winter operation. Solar system according to one of claims 1 to 6, characterized in that in the flow line ( 6 ) of the solar circuit built-in thermal three-way valve ( 19 ), the heat exchanger ( 20 ), which has at least one secondary-side three-way valve ( 24 ), the control device ( 16 ), the pump ( 18 ) are summarized in the solar circuit and display and control devices to a ready-to-connect unit. Solar installation according to one of claims 1 to 7, characterized in that a further temperature sensor ( 26 ) in the return line ( 7 ) of the solar circuit, preferably in the region of the pump ( 18 ), and essentially measured values for the regulation of the rotational speed of the pump ( 18 ).