CS220625B1 - Regulatory wiring of solar collector network with heat accumulator - Google Patents

Abstract

The invention relates to the use of solar energy. The invention solves the problem of using solar energy, transmitted from the collector to the heat exchanger and to the thermal accumulator with a circuit for further heating and heating. The essence of the invention lies in the fact that another input pipe branch is connected to the solar circuit, opening into the thermal accumulator and provided with another electromagnetic valve, electrically conductively connected to the regulator, to which another temperature sensor is connected, with which the thermal accumulator is provided, the output pipe branch of which is connected to the discharge pipe branch of the solar system. The invention can be used in the field of energy when using solar energy or another non-stationary heat source.

Description

The invention relates to a control circuit of a solar collector network with a thermal accumulator.

A number of connections are known for regulating the temperature and circulation of the heat transfer medium in solar collector networks. It is also known to use heat accumulators of a heat transfer medium which can be used for various other heating purposes.

An exemplary known control circuit for a solar collector network with a thermal accumulator is formed by an exchanger connected to the collector of the heat transfer medium branch pipe and the heat transfer medium supply pipe that are interconnected by a transverse pipe branch between its heat exchanger access and collector connection and meizi by exiting the exchanger and connecting it to the collector. The transverse duct is provided with a first solenoid valve electrically conductively connected to the controller. In addition, a second solenoid valve is connected in parallel to the regulator in the inlet pipe branch at its inlet to the exchanger equipped with cold water inlet and hot water outlet, the first thermometer sensor assigned to the collector, the second thermometer sensor assigned to the exchanger, and a circulation pump in parallel with the safety vessel connected to the drain pipe between its connection to the collector and its further connection to the cross-pipe.

This known control connection of the solar collector network is advantageously connected to the heat accumulator according to the invention, which consists in that an inlet conduit opening to the heat accumulator and having a third solenoid valve electrically conductively connected is connected to a further connection of the transverse pipe to the supply pipe. to a controller to which a fourth thermometer sensor is connected, which is provided with a heat accumulator, the outlet pipe of which is connected in a further connection of the cross pipe to the outlet pipe.

The heat accumulator can advantageously be provided with an inlet connection and an outlet connection for the heat transfer medium pipe circuit, which can be used, for example, for additional water heating, room heating or the like.

The control circuit according to the invention combines a number of advantages. These advantages are that it is simple, allows only one regulator to be used, while the circulation of the heat transfer medium is perfectly optimized so that both the heat exchanger and the heat accumulator are always supplied at a temperature higher than either the temperature of the water passing through the heat exchanger, or a preselected constant temperature of the heat accumulator. For this reason, when the temperature of the heat transfer medium on the collector drops, undesirable cooling of the water in the exchanger and the temperature of the heat transfer medium in the heat accumulator cannot occur.

A diagram of an example of a specific embodiment of the control circuit according to the invention is shown in the drawing.

It is apparent from the drawing that the collector 11 is connected to the inlet pipe 23 by its connection 24 and is connected to the outlet pipe 12 by its connection 26. The inlet pipe 23 is connected at its other end to the inlet 21 of the exchanger 16 the inlet conduit 23 has a further connection 25 between its two ends, to which a transverse conduit 17 is connected with a gray one end, the other end of which forms a further connection 27 to the conduit 12 between the two ends thereof . The exchanger 16 is provided with a cold water inlet 15 and a hot water outlet 19 leading to the appliance 20, eg a bathtub, wash basin, etc.

A first solenoid valve 13 is inserted between the two ends of the transverse pipeline 17. A second solenoid valve 18 is connected to the inlet pipeline 23 at its inlet 21 to the exchanger 16. The outlet pipeline 12 is connected between its connection 26 to the collector 11 and a further connection 27 of the transverse conduit 17 to the supply conduit 23 is connected to an inlet conduit 10 connected to the heat accumulator 29 and provided with a third between its two ends The outlet pipe 14 of the heat accumulator 29 is connected to a further connection 27 of the inlet pipe 17 to the outlet pipe 12. The heat accumulator 29 is provided with an inlet connection 7 and an outlet connection 8, to which a duct circuit 30 is connected. , for example The first thermometer sensor 1 is assigned to the heat exchanger 18, the third thermometer sensor 3 is assigned to the supply pipe 23 between its connection 24 to the collector 11 and its further connection 25 to the transverse. The first thermometer sensor 1, the second thermometer sensor 2, the third thermometer sensor 3, the fourth thermometer sensor 4, the first solenoid valve 13, the second solenoid valve 18, the third solenoid valve 28 and The circulation pump 5 is connected in parallel with its electrically conductive channels to the regulator 9.

A function of an exemplary embodiment of the control circuit is that the heat transfer medium receives its temperature mode in the collector 11. Through the connection 24, the heat transfer medium is introduced into the inlet duct 23, which is fed to the exchanger 16, where heat is transferred from the heat transfer medium to the cold water supplied to the exchanger 16 through the cold water inlet 15. The hot water in the exchanger 16 is discharged, if necessary, by draining 19 hot water to the consumer 20. After passing the heat transfer medium through the exchanger 16, the heat transfer medium is introduced into the drain pipe 12 and returned to the collector 11. If the heat transfer fluid in the collector 11 reaches a lower temperature than the water temperature in the exchanger 16, which value can be preset and set on the regulator 9, then the heat transfer fluid is fed from the inlet duct 23 via the cross duct 17 directly to the duct. This prevents the cooling of the water in the exchanger 16. This change in the flow rate of the heat transfer medium is controlled by the regulator 9 by opening independently of the first solenoid valve 13 and the second solenoid valve 18 and by starting the circulation pump 5. The heat transfer medium is also introduced via the supply pipe 23 and the inlet pipe 10 into the heat accumulator 29. The preset value required for the temperature can be set again on the regulator 9. and by comparing this selected temperature value to the actual temperature measured by the fourth temperature sensor 4 as a function of the temperatures measured by the first temperature sensor 1, the second temperature sensor 2 and the third temperature sensor 3, the third solenoid valve 28 is controlled by the regulator 9. , whereby the temperature of the heat-carrying medium in the thermal accumulator 29 cannot be cooled by the flowing heat-carrying medium with a lower thermal value than the selected temperature value.

Assuming that the pre-selected, and the controller 9 adjusts the temperature of the heat transfer medium as the heat exchanger 16 as the heat accumulator 29 to a constant value, such as T _k = 50 ° C, the first temperature sensor is · 1 detects continuously variable temperature T at the collector 11, the second thermometer sensor 2 continuously monitors the variable temperature T2 in the exchanger 16, the third thermometer sensor 3 continuously monitors the variable temperature T3 in the inlet duct 23 between its connection 21 to the collector 11 and its further connection 25 to the transverse duct 17 and the fourth thermometer 4, continuously senses the variable temperature T4 in the thermal accumulator 29, then the regulator 9 controls the flow of the heat transfer medium with the first solenoid valve 13, the second solenoid valve and the third solenoid valve 28 as follows: - the regulator 9 receives simultaneously the temperature values

Ti> T2, T3> T2, T2 <T _k, then the controller 9 closes the first electromagnetic valve 13 opens the second electromagnetic valve 18, uizavře third electromagnetic valve 28 and indicating the operation of circulation pump 5, then the heat transfer medium flows through the flow pipe 23 to exchanger 18 and after passing through exchanger 16 while heating the water therein, the heat transfer medium returns to the collector 11 without, however, cooling the heat transfer medium in the heat accumulator 29;

The controller 9 receives the temperature values simultaneously

T1, T2, T3 and T2, T2 <T _k ,.

then the regulator 9 opens the first solenoid valve 13, closes the second solenoid valve 18, closes the third solenoid valve 28 and starts the circulation pump 5, whereupon the heat transfer medium flows through the supply line 23 and the transverse line 17 into the drain line 12 and back to the collector 11, so that the water in the exchanger 16 cannot be cooled, nor the heat transfer medium in the heat accumulator 29 can be cooled;

The controller 9 receives the temperature values simultaneously

Tl and T2, T3> T2, T2 <T _k, then the controller 9 closes the first electromagnetic valve 13, opens the second solenoid valve 18 closes the third electromagnetic valve 28 and indicating the operation of circulation pump 5, then the heat transfer medium flows through the flow pipe 23 to the heat exchanger 16 and after passing through the exchanger 16 while heating the water therein, the heat transfer medium returns to the collector 11 without, however, cooling the heat transfer medium in the heat accumulator 29;

The controller 9 receives the temperature values simultaneously

Those T2, T3, T2, T2 <T _k, then the controller 9 closes the first electromagnetic valve 13, the second solenoid valve 18 and the third electromagnetic valve 28, and disables operation of circulation pump 5 so that it stops the circulation of heat transfer fluid to neodhazovalo water in exchanger 16 and, to prevent the temperature of the heat transfer medium in the heat accumulator 29 from dropping;

The controller 9 receives the temperature values simultaneously

Ti> T4, T3> T4, T2> T _k, T 4 <T _k, then the controller 9 closes the first electromagnetic valve 13 and the second solenoid valve 18 opens the third electromagnetic valve 28 and indicating the operation of circulation pump 5, then the heat transfer medium flows through inlet pipe 23 and inlet pipe 10 into the heat accumulator 29, thereby increasing the temperature of the heat transfer medium in the heat accumulator 29, from which the heat transfer medium then flows through the outlet pipe 10 and the outlet pipe 12 back to the collector 11. an exchanger 18 with a heat transfer medium;

The controller 9 receives the temperature values simultaneously

Ti> T4, T3 = T4, T2> T _k, T 4 <T _k, then the controller 9 opens the first electromagnetic valve 13 and closes both the second solenoid valve 18 and the third electromagnetic valve 28 and indicating the operation of circulation pump 5, then the heat transfer the medium flows through the supply line 23, the transverse line 17 and the discharge line 12 back to the collector 11 without cooling the water in the exchanger 16 and the heat transfer medium in the heat accumulator 29;

The controller 9 receives the temperature values simultaneously

Ti> T2, T3> T2, T2> T _to T4> T _k, then the controller 9 closes the first electromagnetic valve 13, opens the second solenoid valve 18 closes the third electromagnetic valve 28 and indicating the operation of circulation pump 5, then the heat transfer medium flows a supply line 12 to the collector 11 without cooling the heat transfer medium in the heat accumulator 29;

The controller 9 receives the temperature values simultaneously

Ti> T2, T3 and T2, T2> T _to T4> T _k, then the controller 9 opens the first electromagnetic valve 13 and closes both the second solenoid valve 18 and the third electromagnetic valve 28 and activated greements circulation pump 5, then the heat transfer the medium flows through the inlet duct 23, the cross duct 17 and the outlet duct 12 back to the collector 11 without cooling the water in the exchanger 16 and cooling the heat transfer medium in the heat accumulator 29;

The controller 9 receives the temperature values simultaneously

Τι T4, T3> T4, T2> T _to T4 <Tk, then the controller 9 closes both the first electromagnetic valve 13 and the second electromagnetic valve 18 opens the third electromagnetic valve 28 and indicating the operation of circulation pump 5, then the heat transfer medium flows the inlet pipe 23 and the inlet pipe 10 into the heat accumulator 29, in which the temperature of the heat transfer medium rises, and then the heat transfer medium returns through the outlet pipe 14 and the outlet pipe 12 to the collector 11 without cooling the water in the exchanger 16 ;

The controller 9 receives the temperature values simultaneously

Those with T4, T3 and T4, T2> Tc, Ta <T _k, then the controller 9 closes both the first electromagnetic valve 13 and the second solenoid valve 18 and the third electromagnetic valve 28, and disables operation of circulation pump 5, so that the heat transfer medium stops flowing and can neither cool the water in the exchanger 16 nor the heat transfer medium in the thermal accumulator 29;

The controller 9 receives the temperature values simultaneously

Those T2, T3> T2, T2> T _to T4> T _k, then the controller 9 closes the first electromagnetic valve 13, opens the second solenoid valve 18 closes the third electromagnetic valve 28 and indicating the operation of circulation pump 5, then the heat transfer medium flows from the collector 11 through the inlet duct 23 to the exchanger 16 where it heats the water and the oldkuid flows through the outlet duct 12 to the collector 11 without cooling the hot-axle medium in the heat accumulator 29;

The controller 9 receives the temperature values simultaneously

Those T2, T3, T2, T2> T _to T4> T _k, then the controller 9 closes both the first electromagnetic valve 13, Taik second electromagnetic valve 18 and the third electromagnetic valve 28, and disables operation of circulation pump 5, so that the heat transfer medium stops flow and cannot cool either the water in the exchanger 18 or the heat transfer medium in the heat accumulator 29.

The heat transfer medium from the heat accumulator 29 can be advantageously used in a duct circuit 30, by means of which additional water or hot water storage tanks, such as floor or wall heating, can be heated.

The control circuit according to the invention can be used most advantageously for circuits using solar heat transferred from the collector

229625 ru for heat exchanger and heat accumulator with circuit for further heating and heating. Regulatory connection can be used in industrial construction, also in construction of family houses etc.

Claims (2)

1. Regulatory connection of a solar collector network with a heat accumulator consisting of a heat exchanger connected to the collector of a heat transfer medium discharge line and a heat transfer medium supply line which are interconnected by a heat transfer medium transverse branch connected to a supply line between its inlet to the exchanger and to the collector and drain pipe between its exchanger outlet and its Ike collector connection and which is provided with a first solenoid valve electrically conductively connected to a controller to which a second solenoid valve connected in the supply pipe branch is connected electrically conductively at its entrance to the exchanger, equipped with cold water inlet and hot water outlet, first thermometer sensor assigned to the collector, second thermometer sensor assigned to the exchanger, third thermometer a sensor associated with the supply pipe between its connection to the torch collector and its further connection to the transverse pipe and the circulation pump in parallel with the safety vessel connected to the drain pipe between its connection to the collector and its further connection to the transverse pipe, in that the inlet pipe (10) connected to the heat accumulator (29) and provided with a third solenoid valve (28) electrically conductively connected to the regulator (10) is connected to a further connection (25) of the cross pipe (17) to the inlet pipe (23). 9), to which a fourth thermometer sensor (4) is electrically conductively connected, which is provided with a thermal accumulator (29), the outlet conduit (14) of which is connected in a further connection (27) of the transverse conduit (17) to the outlet conduit (12). Control circuit according to claim 1, characterized in that the thermal accumulator (29) is provided with an inlet connection (7) with an outlet connection (8) for the heat transfer medium pipe (30).