DE19705040A1 - Solar water heater control method - Google Patents

Abstract

The method involves recording the temperature of the water flowing to the solar collector (1). When a prescribed difference between the temperature of the water flowing in and out of the collector is recorded, the water flowing into the solar collector is fed directly to a primary heat exchanger (35). This heat exchange is heated by a burner (36). When a prescribed higher positive difference in these temperatures is exceeded, all the water is directed through the collector.

Description

The invention relates to a method for controlling a water heater according to the preamble of claim 1.

In such processes, water flows continuously through the solar collector. Here However, there is the disadvantage that there is also a lack of sunlight Cooling of the water in the area of the solar collector can come.

The aim of the invention is to avoid this disadvantage and to initiate a method mentioned type to propose, in which a cooling off from the heat consumer running water is avoided.

According to the invention, this is achieved in a method of the type mentioned at the outset by characteristic features of claim 1 achieved.

The proposed measures ensure that the heat consumer draining water depending on the temperature difference between that of the son Nenkollektor incoming and the water flowing out of this partially or to Entirely via the solar collector or directly to the primary heat exchanger. This prevents that if the temperature difference is too small or a negative one Temperature difference, d. H. that the water flowing to the solar collector due to a the absence of solar radiation has a higher temperature than that of the sun  water flowing out of the collector, flows through the solar collector, causing it to drain cooling of the water comes.

In addition, the proposed measures also make it possible to split them up the flow rate through the solar collector decrease, so that there is a greater heating of the water in the solar panel comes and therefore the radiated heat can be better utilized.

Due to the features of claim 2, there is the possibility of a very precise to fit the distribution of the water flowing out of the heat consumer over the Solar collector and a direct inflow to the primary heat exchanger bypassing of the solar collector to the respective conditions.

Another object of the invention is to provide a water heater for carrying out the invention to propose the method according to the invention.

In a water heater in which a primary heat applied by a burner exchanger with a heat consumer via a flow line and the heat consumer is connected via a return line to a solar collector, which on the outflow side a circulation pump is connected to the primary heat exchanger and in the flow line and downstream of the solar collector are arranged temperature sensors a controller provided with a setpoint generator for the flow temperature is connected sen, the characterizing features of claim 3 are therefore proposed.

The proposed measures result in a very simple structure, one Detection of the temperature of the water flowing out of the heat consumer and a easy control of the distribution of this water flow via the bypass line and Solar panel are possible. It is further up due to the proposed measures  simple way possible, the water flows according to the respective circumstances, in particular to control the respective temperature distribution.

The features of claim 4 result in a very gentle operation of the order switching or mixing valves, only with changes in temperature distribution in the area of the water flowing out of the heat consumer and the heat water flowing into the consumer and what flows out of the solar collector sers energy to control the switching or mixing valve.

The features of claim 5 give the advantage of a very simple training the drive of the changeover or mixing valve.

In a water heater according to the invention, in which the heat consumer by a Heating system is formed, results from the characteristic features of the Anspru ches 6 the advantage of a simple control also depending on a detection a flow through the hot water pipe.

In the embodiment according to the features of claim 7, there is the advantage that the buffer memory can be charged for a long time and therefore ent results in a low number of operations for the burner. The latter also applies to the Features of claim 8 or 9.

The invention will now be explained in more detail with reference to the drawing. Here, Figs. 1 to 5 show various embodiments of inventive water heater and Fig. 6 is a slide program of the valve position of the switching or mixing valve depending on the temperature difference across the solar collector.

The same reference numerals mean the same details in all figures.  

In the embodiment according to FIG. 1, a solar collector 1 is connected via a collector return line 24 , a return line 28 adjoining this and a heating return line 22 adjoining this, to a heat consumer formed by a heating system 4 , which in turn is connected via a heating flow line 21 and a flow line 26 connected to it is connected to a primary heat exchanger 35 of a heat generator 2 .

The solar collector 1 is connected via a collector feed line 25 to a mixing valve 5 , which is connected via a bypass line 23 to the return line 28 and a connecting line 68 to a circulating pump 3 , which in turn has a primary heat exchanger return line 27 the primary heat exchanger 35 is connected. This primary heat exchanger 35 is acted upon by a burner 36 , which can be supplied with gas via a gas line 31 and a gas valve 18 . This gas valve 18 is provided with a drive 19 which is connected to a controller 60 via a control line 51 . This controller 60 is also connected via a control line 52 to a drive 20 of the circulation pump 3 . A drive of the changeover or mixer valve 5 is also connected to the controller 60 via a control line 53 .

On the controller 60 are still setpoint generator 48 for specifying a target temperature of the heating system 4 and a target value transmitter 50 for specifying the target flow temperature is connected. Furthermore, a temperature sensor 42 is arranged in the flow line 26 and is connected to the controller 60 via a signal line 62 . In addition, there is also a temperature sensor 41 which is arranged at the highest point of the solar collector 1 and is connected to the control 60 via a signal line 61 , a room temperature sensor 44 which is arranged in the return line 28 and via a signal line 64 with the control 60 is connected and a temperature sensor 43 is provided which is connected to the controller 60 via a signal line 63 . Furthermore, an outside temperature sensor 46 is connected to the controller 60 via a signal line 66 .

If the temperature falls below a predetermined temperature in the area of the temperature sensor 43 , the circulation pump 3 is started by the controller 60 . If there is a temperature above the desired flow temperature at the outlet of the solar collector 1 , or such a temperature is detected by the temperature sensor 41 , the switchover or mixing valve 5 blocks the bypass line 23 . In order not to exceed the intended flow target temperature, which is detected by the temperature sensor 42 , the speed of the motor 20 of the circulating pump 3 is increased accordingly by the controller 60 and thus the residence time of the water in the solar collector 1 is reduced.

If the temperature in the area of the outlet of the solar collector 1 drops below the desired flow temperature due to reduced solar radiation, the switchover or mixing valve 5 opens the bypass line 23 partially or intermittently. As a result, the flow velocity in the solar collector 1 is reduced, so that the time of the water in the solar collector 1 increases and the water flowing out of this reaches a higher temperature. At the same time, the burner 36 is started and the water in the primary heat exchanger 35 is brought to the intended target flow temperature.

In this case, depending on the temperature difference between the temperatures of the temperature sensors 44 and 41, the extent of the flow through the bypass line 23 is set accordingly, as can be seen from FIG. 6. If there is a positive temperature difference between the temperature detected by the temperature sensor 41 and the temperature detected by the temperature sensor 44 of more than 2 K, the bypass line 23 is closed, and there is an exclusive flow through the solar collector 1 . If the temperature difference drops further, the bypass line is opened more and more and, in the absence of a positive temperature difference, the bypass line 23 is fully open and the flow through the solar collector 1 is omitted.

Reaches the temperature in the area of the temperature sensor 44 a certain predetermined temperature, this is a signal that there is no heat requirement in the heating system area and the burner 36 is stopped by closing the gas valve 18 and the circulation pump 3 is also turned off.

The embodiment of FIG. 2 differs from that of FIG. 1 in that the flow line 26 is connected to a changeover valve 6, which is connected via a control line 54 to the controller 60 . On the further changeover valve 6 , the heating flow line 21 and a heat exchanger flow line 29 are connected, which is connected to a process water heat exchanger 7, which is connected to the return line 28 via a heat exchanger return line 30 . The secondary branch 69 of the heat exchanger 7 is connected to a cold water connection 16 , which is provided with a flow sensor 38 , and to a process water line 17 , in which a tap 37 is arranged. The flow sensor 38 is connected to the controller 60 via a signal line 55 .

The process water heat exchanger 7 can also be replaced by a storage water heater. Then the changeover of the changeover valve 6 does not take place at the start of a tap but when the temperature falls below a target temperature in the memory.

The heating operation takes place in the embodiment according to FIG. 2 in the same way as in the embodiment according to FIG. 1.

If the tap 37 is opened, the flow sensor 38 detects the corresponding current, and the controller 60 effects a changeover of the changeover valve 6 via a drive 72 in such a way that the path from the feed line 26 to the heat exchanger before the run line 29 is released is and the way to the heating flow line 21 is blocked. At the same time, the controller 60 sets the setpoint for the flow temperature to a maximum value of z. B. 78 to 86 ° C.

If the tap 37 is closed, this is detected by the flow sensor 38 and the changeover valve 6 is reversed so that the path from the return line 26 to the heating flow line 21 is released. If there is no heat request from the heating system 4 , the circulation pump 3 and the burner 36 are stopped. If there is a demand for heat, the heating system 4 is supplied in the manner described with reference to FIG. 1.

The embodiment according to FIG. 3 differs from that according to FIG. 2 in that the flow line 26 is not connected to a three-way valve 6 , but to a buffer store 8 in which a heat exchanger 9 is arranged. This heat exchanger 9 is connected to the heating flow line 21 and the heating return line 22 , a further circulation pump 10 being arranged in the latter, the drive 11 of which is connected to the control 60 via a control line 56 .

A temperature sensor 45 is arranged in the lower area of the buffer memory 8 and is connected to the control system via a signal line 65 .

The supply of heat to the heating system 4 takes place in such a way that the circulation pump 10 is started when there is a heat request and heat is thereby removed from the buffer store 8 . The buffer store 8 is heated up in the manner in which the heat supply for supplying the heating system 4 was explained with reference to FIG. 1. The heating of the buffer store 8 is started when the temperature sensor 45 detects a temperature below a predetermined target temperature.

The heating medium flowing through the heating system 4 is not heated directly in the solar collector 1 or in the primary heat exchanger 35 , but is coupled out via the buffer store 8 or the heat exchanger 9 . If the room temperature sensor 43 falls below a temperature specified by means of the setpoint value transmitter 48 , the circulation pump 10 is started up. The heating water flows through the heating system 4 , the heating flow line 21 , the heating return line 22 and the heat exchanger 9 , where it is heated.

The charging of the buffer memory 8 takes place when the target temperature in the area of the temperature sensor 45 in the buffer memory 8 falls below the predetermined temperature specified by the outside temperature sensor 46 and the target value transmitter 50 . In this case, the circulation pump 3 is also put into operation.

The position of the three-way valve 5 takes place in dependence on the temperature sensors 44 and 41 determined temperatures, as has already been explained with reference to FIG. 1.

The target flow temperature at the temperature sensor 42 and the target switch-off temperature in the region of the temperature sensor 45 should be about 5 to 10K above the temperature sensor 46 and the target value transmitter 50 predetermined value. If the temperature falls below this target temperature in the area of the temperature sensor 42 , the primary heat exchanger 36 is put into operation, if this temperature is reached in the area of the temperature sensor 45 , the circulation pump 3 and possibly also the primary heat exchanger 36 become out of operation set.

Since the heating flow temperature can at most reach the temperature prevailing in the buffer store 8 , this circuit causes a fluctuation in the flow temperature in the area of the heating flow line 21 . This can be largely avoided by installing a mixer with a bypass line and a temperature sensor, as provided for in FIG. 4.

The hot water can be heated analogously to the embodiment according to FIG. 2 according to the flow or storage principle. For this purpose, a three-way valve must be installed between the temperature sensor 42 and the buffer store 8 . The heat exchanger return line 30 then opens behind the buffer memory 8 in the return line 28 .

The embodiment of FIG. 4 differs from that in that the flow line 26 is connected to a heat exchanger 14 which is arranged in a buffer memory 8 at. The inside of the buffer memory 8 is connected to the heating flow line 21 and to the heating return line 22 . In this case, a three-way valve 70 and a temperature sensor 47 are arranged in the heating flow line, which are connected to the controller 60 via a control line 58 or a signal line 67 . The three-way valve 70 is connected to a bypass line 40 which is connected to the heating return line 22 .

Next, the interior of the buffer memory 8 is connected via a heat exchanger feed line 33 and a heat exchanger return line 32 to a process water heat exchanger 12 , with a circulation pump 13 being arranged in the heat exchanger return line 32 , the drive 39 of which is connected via a control line 57 to the Controller 60 is connected. The secondary branch 69 of the domestic water heat exchanger 12 is connected in the same way as explained with reference to FIG. 2.

In this embodiment, the volume of the buffer store 8 is not switched on in the circuit of the heat generator 2 or the solar collector 1 , but in the heating circuit. Since the hot water temperature in the illustrated embodiment depends on the temperature in the buffer memory 8 , the target temperature at the temperature sensor 45 should therefore not be a function of the outside temperature sensor 46 and target value transmitter 50 , but via the target value generator 49 , which is arranged on the controller 60 .

The buffer store 8 is charged when the temperature falls below the target temperature in the area of the temperature sensor 45 , the circulation pump 3 being put into operation. As already explained with reference to FIG. 1, the three-way valve 5 is set as a function of the temperatures detected by the temperature sensors 41 and 44 . If the temperature falls below the target flow temperature in the area of the temperature sensor 42 , which is predetermined by the target value transmitter 50 , the primary heat exchanger 36 goes into operation. The heating process is ended when the temperature sensor 45 detects the switch-off temperature, which is approximately 5 to 10K above the target temperature, the circulation pump 3 and possibly the primary heat exchanger 36 being stopped.

The heating system 4 is supplied with heat when the room temperature sensor detects a temperature below that specified by the target value transmitter 48 . In this case, the circulation pump 10 is started by the controller 60 and delivers water from the buffer store 8 via the heating system 4 .

Since the temperature in the buffer tank can possibly be significantly higher than the desired flow temperature specified by the outside temperature sensor 46 and the desired value transmitter 50 due to the hot water preparation, the three-way valve 70 or a mixer is arranged in the heating flow line 21 which the bypass line 40 is connected. Thus, the flow temperature for the heating system 4 wherein the flow temperature of the heating system 4 is detected by the temperature sensor 47 entspre be adjusted accordingly. The three-way valve or the mixer 70 is controlled accordingly by the controller 60 and releases the flow through the bypass line the more the temperature of the buffer memory 8 is above the desired flow temperature. The desired flow temperature of the heating system 4 is predetermined by the outside temperature sensor 46 and the desired value transmitter 50 .

If the target temperature is reached at the room temperature sensor 43 , the circulation pump 10 is stopped by the controller 60 .

The tap 37 is opened for hot water preparation, the flow caused thereby being recognized by the flow sensor 38 . To provide the required heat, the circulation pump 13 is put into operation by the controller 60 and conveys water from the buffer store 8 via the heat exchanger feed line 33 , the process water heat exchanger 12 and the heat exchanger return line 32 , the process water being heated via the secondary branch 69 becomes.

Alternatively, it would also be possible, analogous to the embodiment according to FIG. 2, to provide a three-way valve 6 in the flow line 26 between the temperature sensor 42 and the heat exchanger 14 arranged in the buffer memory 8 and to connect a continuous heat exchanger or a domestic hot water tank to it. The Wärmetau shear return line 32 then opens behind the heat exchanger 14 in front of the temperature sensor 44 in the return line 28th

The embodiment according to FIG. 5 differs from that according to FIG. 4 only in that instead of the buffer storage 8 , a domestic water storage 15 is provided which, in addition to the heat exchanger 14, also has a further heat exchanger 9 , on which, as already with reference to FIG Fig. 3 is described, the heating flow line 21 and the heating return line 22 are connected. Here, a cold water connection 16 and a hot water line 17 , in which a tap 37 is arranged, connected to the hot water storage 15 . The remaining structure of the heating circuit is the same, as explained with reference to FIG. 4.

In this embodiment, the hot water tank 15 is heated via the heat exchanger 14 by the solar collector 1 and or or by the primary heat exchanger 36 . From this, the heat is coupled out via the heat exchanger 9 . The control of the charging of the domestic hot water tank is carried out analogously to the charging of the buffer tank 8 according to FIG. 4. The removal of domestic water is in the embodiment according to FIG. 5 independent of a heating process.

The control of the heating circuit is carried out analog to the embodiment according to FIG. 4, but with the difference that, according to FIG. 5, the heating water is not taken directly from the memory 8 , but rather flows through the heat exchanger 9 and is thereby heated.

Claims (9)

1. Method for controlling a water heater with a primary heat exchanger ( 35 ) acted upon by a burner ( 36 ) and a solar collector ( 1 ) hydraulically connected in series therewith, in which the water flowing into the primary heat exchanger ( 35 ) in the solar collector ( 1 ) is at least preheated, the water flowing away from a heat consumer being fed to the solar collector ( 1 ) and the temperature of the water flowing out of the solar collector ( 1 ) being detected and the burner ( 36 ) being started when the temperature of the solar collector ( 1 ) Abflie ßenden water below the target temperature of the primary heat exchanger ( 35 ) flowing water, characterized in that the temperature of the solar collector ( 1 ) incoming water is detected and at Unterschrei th a certain difference between the temperature the water flowing out of the solar collector ( 1 ) and the water to flow this latter d irect the primary heat exchanger ( 35 ) is supplied and if a certain higher positive difference of these temperatures is exceeded, the entire water is passed through the solar collector ( 1 ). 2. The method according to claim 1, characterized in that the admixture of the solar collector ( 1 ) flowing in or outflowing water from the heat consumer to the solar collector ( 1 ) outflowing water depending on the temperature increase of the water above the solar collector ( 1 ) continuously between 0% and is varied 100%. 3. Water heater for performing the method according to claim 1 or 2, wherein a acted upon by a burner (36) the primary heat exchanger (35) with a heat consumer (4) via a feed line (26) and the heat consumer (4) via a return line ( 28 ) is connected to a solar collector ( 1 ), which is connected to the primary heat exchanger ( 35 ) on the outflow side via a circulation pump ( 3 ) and in the flow line ( 26 ) and outflow side of the solar collector ( 1 ) temperature sensor ( 42 , 41 ) are arranged which are connected to a controller ( 60 ) provided with a setpoint value transmitter ( 50 ) for the flow temperature, characterized in that in the return line ( 28 ) there is a further temperature sensor ( 44 ) connected to the controller ( 60 ) ) is arranged and the return line ( 28 ) is connected via a bypass line ( 23 ) to a three-way valve ( 5 ), the other connections of which are connected to the outflow side de s solar collector ( 1 ) and the circulation pump ( 3 ) is connected and its drive is connected to the controller ( 60 ) via a control line ( 53 ). 4. Water heater according to claim 3, characterized in that the three-way valve ( 5 ) has a continuously adjustable drive. 5. Water heater according to claim 3, characterized in that the three-way valve ( 5 ) is designed as a changeover valve and the drive of the three-way valve ( 5 ) can be controlled intermittently. 6. Water heater according to one of claims 3 to 5, in which the heat consumer is formed by a heating system ( 4 ), characterized in that a further three-way valve ( 6 ) is arranged in the flow line ( 26 ), on which a hy draulically parallel to the heating system ( 4 ) switched bypass line device ( 29 , 30 ) is switched on, in which a hot water heat exchanger ( 7 ) is arranged, the drive of the further three-way valve ( 6 ) via a control line ( 54 ) with the controller ( 60 ) is connected, which is connected via a signal line ( 55 ) to a sensor ( 38 ) detecting the flow in a process water line ( 17 ). 7. Water heater according to one of claims 3 to 5, characterized in that between the heat consumer by a heating system ( 4 ) formed and the primary heat exchanger ( 35 ), a buffer store ( 8 ) is interposed, in which a with the heating system ( 4 ) connected heat exchanger ( 9 ) is arranged. 8. Water heater according to one of claims 3 to 5, characterized in that the flow line ( 26 ) with a in egg nem memory ( 8 ) arranged heat exchanger ( 14 ) is the unit, to which memory ( 8 ) a heating flow and a heating return line ( 21 , 22 ), and a process water heat exchanger ( 12 ) is connected. 9. Water heater according to claim 8, characterized in that the flow line ( 26 ) with a in a domestic water storage ( 15 ) arranged heat exchanger ( 14 ) is connected, in which a further heat exchanger ( 9 ) is arranged, which with the heating system ( 4th ) connected is.