DE3644966A1 - Arrangement for measuring hot water consumption in hot water heating systems - Google Patents

Abstract

An arrangement for measuring water consumption in a hot water heating system (10) exhibiting a heating device (15) and a plurality of heaters (radiators) (11) connected via pipelines (13, 14), has thermostatic switches (18, 18') which are provided on the heaters (11) and of which each is provided with a sensor (19) for detecting its closed or opened state. In order to be able to measure the consumption of heat more accurately, it is provided that the thermostatic switches (18) are constructed as flow-regulating valves and the sensors (19) as odometers (pedometers), that the radiators (11) are respectively provided on the feed and return sides with a temperature sensor (28, 29), and that the temperature sensors (28, 29) and the odometers (19) are connected to a multiplication circuit (31). <IMAGE>

Description

The present invention relates to an arrangement for heat consumption measurement on a hot water heater System according to the preamble of claim 1.

Known arrangements for measuring heat consumption on warm Water heating systems use on the individual heater devices to be fastened, the one Contain tubes that are filled with a liquid which is integrated according to the one over time Heat emission evaporates, the evaporated liquid  a measure of the heat consumption of the heating in question body is. The evaporation tubes in these pre directions have to be changed annually, what is relatively expensive. In addition, they are inaccurate.

The object of the present invention is therefore a Arrangement for heat consumption measurement on a hot water To create a heating system of the type mentioned at the beginning, with which the heat consumption is measured in a more precise manner which can be changed all the time without being replaced can be in operation.

To solve this problem with an arrangement Measurement of heat consumption in a hot water heating system of the type mentioned in the characterizing part of claim 1 specified features provided.

This allows the heat consumption of each individual radiator can be determined in a simple and precise manner since the Heat consumption is proportional to the product of the Difference between the displays of the two temperature sensors and the hot water proportional to the measured value of the odometer flow through the thermostatic valve can be calculated. By the formation of the thermostatic valve as a flow control valve  can open any position of the thermostatic valve constant hot water flow regardless of pressure fluctuations in the piping system can be assigned. About that in addition, this arrangement is essentially maintenance free because none of their elements are replaced regularly must become.

With the features of claim 2, it is also possible the total heat consumption of several radiators or one Group of radiators to capture what a significant Simplification when determining heat consumption an apartment or the like.

With the features of claim 3 is a convenient un indirect optical detection of each heat consumption Radiator or the entire housing unit or the like. possible.

Further details of the invention are as follows To see description in which the invention based on the in the embodiments shown in the drawing is described and explained. It shows

Fig. 1 is a provided with a plurality disposed in individual rooms radiators arrangement present in a schematic representation for controlling a hot water heating system according to one embodiment and in dot-dash lines shown attachment according to another embodiment of the invention,

Fig. 2 in longitudinal section a thermostatic valve, as for example, in the illustrated in Fig. 1 according to the first embodiment, arrangement is used,

Fig. 3 shows a longitudinal section through a thermostatic valve, as eg. In which the inventive arrangement is used in Fig. 1 the second embodiment shown,

Fig. 4 in a cut, partially broken view of a variant of the thermostatic valve according to FIGS

Fig. 5 in a sectional, partially broken view of a variant of the thermostat valve of FIG. 3.

Referring to FIG. 1 of a hot water heating system are in an arrangement for controlling a plurality of 10 (eg. N) hot-water radiator 11/1, 11/2, 11/3 provided, etc., individually or in combination in individual rooms 12 / 1, 12/2, 12/3 etc. are arranged. The radiators 11/1 to 11 / n are connected to one another and, in a schematically illustrated manner, to a heating device 15 of the hot water heating system 10 by a common flow line 13 and a common return line 14 . The term heating device is understood here to mean, for example, a boiler with an oil burner, a gas boiler with a gas burner, or a water tank or instantaneous heater with an electrical heating device. In Fig. 1, reference numeral 16 denotes an oil or gas burner. The flow line 13 and the return line 14 are connected to one another and to the heating device 15 via a mixer 17 which is adjustable in a manner known per se.

On each radiator 11/1 to 11 / n of each room 12/1 to 12 / n , a thermostatic valve 18 or 18 ' or 20 or 20' is provided, which with a sensor 19 or 19 ' for detecting the closing or The opening state of the thermostatic valve is provided, which will be explained with reference to FIGS. 2 to 5.

Are the thermostatic valves 20 or 20 ' attached to the radiators 11/1 to 11 / n , the sensors 19' of which can only detect the closed or open position of the thermostatic valve 20, 20 ' , as shown in broken lines in FIG. 1 , The sensor 19 ' via an AND circuit 21 with an on / off switch 22 of the heater 15 , so here the burner 16 of the hot water heating system 10 connected. On the other hand, if the thermostatic valves 18 or 18 'are attached to the radiators 11/1 to 11 / n , the sensors 19 of which, apart from the closed state, can also detect different opening states of the thermostatic valve 18' , are, as shown in Fig. 1 in solid lines, the Sensor 19 is connected via a summation circuit 26 and a control circuit 27 to the heating device 15 , for example the burner 16 and / or to the mixer 19 .

Both the flow side and the return side are provided in the area of each radiator 11/1 to 11 / n temperature sensors 28 and 29 , which are connected to a multiplication circuit 31 , to which the output of the sensor 19 and 19 'of the thermostatic valve 18 and 18 respectively ' Or 20 or 20' is guided and which is connected to a measured value display 32 . All multiplication circuits 31/1 to 31 / n are connected to a superordinate summation circuit 33 , which can also be coupled to a measured value display 34 . The multiplication circuits 31/1 to 31 / n form the difference from the display of the temperature sensor 28 in the flow and that of the temperature sensor 29 in the return and multiply by this difference the measured value of the sensor 19 of the thermostatic valve 18 and 18 'designed as a travel meter. In this way, the output of the multiplier circuit 31/1 to 31 / n results in a size proportional to the heat consumption of the radiator 11/1 to 11 / n in question , which is fed to the measured value display or the heat consumption measuring device 32 with constant addition of the individual products. Furthermore, the superordinate multiplication circuit 33 forms the sum of all the quantities supplied by the sum circuits 31/1 to 31 / n . This possibility of measuring the heat consumption on the individual radiator and / or overall is, as can be seen, only possible with the sensor in the form of the travel meter 19 .

Fig. 2 shows the thermostatic valve 18 , the sensor 19 is designed as a travel meter. The thermostatic valve 18 has a valve housing 36 which is provided with pipe connections 37 and 38 and a connection 39 arranged perpendicularly thereto for flange-mounting a thermostatic attachment 41 by means of a screw connection 42 . The thermostatic attachment 41 has a housing 52 , on the internal thread 51 of which a rotary knob 43 can be screwed and thus axially moved, within which a room temperature-dependent expansion body 44 is arranged, which is connected to a plunger 46 which is reciprocated by the medium in the expansion body is movable and can act on a guided in an insert 45 in the valve housing 36 pin 47 in the axial direction of a valve plunger 48 which is axially guided in the valve housing 36th The expansion body tappet 46 provided with an index edge 49 is surrounded by the sensor 19 held in a stationary manner in the thermostat attachment 41 , which is designed as a travel meter in such a way that it can detect the movement of the index edge 49 of the expansion body tappet 46 analogously and can transmit it as a measurement signal. For example, the sensor 19 can be of an inductive or capacitive type. With the help of this sensor 19 , both the closed position and continuously any open position of the thermostatic valve 18 can be detected.

The thermostatic valve 18 is also designed in the manner of a flow control valve. For this purpose, the valve lifter 48 is provided with an axial recess 56 which is connected at its upper end to the input connection 37 via a plurality of radial bores 57 and is provided at its lower end with a plurality of radial bores 58 . These lower bores 58 can be connected to the outlet or outflow connection 38 via a plurality of radial slots or a circumferential slot 63 , which are or are provided in a partition or intermediate wall 61 of the valve housing 36 which accommodates the valve tappet 48 in an axially movable manner. These circumferential slots 63 are arranged such that they are more or less aligned with the bores 58 in the opened state of the valve tappet 48 . As the pressure in the inlet 37 increases, the pressure difference in the valve increases, so that the valve tappet 48 , the upper end of which is connected to the inlet chamber 37 and the lower end of which is connected to the outflow chamber 38 , counteracts a compression spring 64 moved down and narrowed the flow cross-section between the bores 58 in the valve tappet and the slots 63 in the intermediate wall 61 , where a constant flow is achieved even with increased inlet pressure.

The temperature sensor 28 is received in the outflow connection 38 in the underside of the valve housing 36 .

Fig. 4 shows a variant 18 'of this thermostatic valve, which is used to provide already installed known thermostatic valves with the sensor or travel meter 19 . For this purpose, an adapter body 66 is provided, which can be connected at one end to the connection 39 of the valve housing 36 and at the other end to the lower end of the top housing 52 . The adapter body 66 has an intermediate bolt 67 which is received in an axially movable manner and which is brought into operative connection at one end with the pin 47 in the valve housing 36 and at the other end with the expansion body tappet 46 in the attachment housing 52 . In the adapter body 66 , the sensor 19 is also included, which detects the respective position of the index edge 49 'of the intermediate bolt 47 .

When using a thermostatic valve 18 or 18 ' with such a travel meter 19 according to FIG. 2 or 4, regulation of the heating device 15 according to FIG. 1 is possible in the following way: The emitted by the individual sensors 19 of the radiators 11/1 to 11 / n Measured values are supplied to the summation circuit 26 , the output of which controls the control circuit 27 in such a way that the output of the heating device 15 or the burner 16 is changed in a size proportional to this value. The output variable of the control circuit 27 can also be used to adjust the mixer 17 in such a way that there is a proportional change in the mixture of flow and return. Only when the sum of the measured values from the sensors 19 goes to zero or is zero, is the heating device 16 switched off.

Fig. 3 shows the thermostatic valve 20 with the sensor 19 ' in the form of a microswitch which is arranged in a radial bore 71 of the top housing 52' of the thermostatic valve 20 . The microswitch 19 ' is operatively connected to a plunger 46' which, for example, has a conical shape and which switches from the closed position to a certain minimal opening position or vice versa when the valve plunger is transitioned. According to Fig. 5 is in a corresponding manner in existing thermostatic valves 20 'which are to be converted according to the invention, the adapter body 66' is provided a radial bore 72 'is received and in a corresponding manner with an intermediate pin 67' in which the sensor or micro-switch 19 is conical shape in operative connection.

The control of the heating device 15 with the help of such thermostatic valves 20 or 20 ' is carried out in the following way: The microswitch 19' of the thermostatic valves 20, 20 'of the individual radiators 11/1 to 11 / n , as shown in dash-dotted lines in Fig. 1 is fed to the AND circuit 21 , which only passes on a signal when all the microswitches 19 ' indicate the closed position of the thermostatic valve 18' . This output signal of the AND circuit 21 is then fed to the on / off switch 22 , which then switches off the heating device 15 or the burner 16 . This is a purely two-point control, in which the burner 16 is switched on in a correspondingly opposite manner when one of the thermostatic valves 18 ' opens because of a heat requirement requested by the room.

It goes without saying that when using the thermostatic valves 18 ' used with the microswitch 19' , the temperature sensors 28 and 29 can also be omitted, since a measurement of heat consumption cannot take place because of the undefined opening states. It is also understood that in this case the valve housing 36 'can also be formed in a simple manner instead of in the form of the flow control valve.

In the drawing, a radiator 11/1 to 11 / n is shown for each room 12/1 to 12 / n, each representing a control component. However, it is also possible to combine several radiators in one room to form a single control component or to combine several radiators in several rooms in groups to form a control component.

Claims (3)

1. Arrangement for heat consumption measurement on a heating device ( 15 ) and several pipes ( 13, 14 ) connected radiators ( 11 ) having a hot water heating system ( 10 ), with the radiators ( 11 ) provided thermostatic valves ( 18, 18 ' ) , each of which is provided with a sensor ( 19 ) for detecting its closed or open state, characterized in that the thermostatic valves ( 18 ) are designed as flow control valves and the sensors ( 19 ) are designed as travel meters that the radiators ( 11 ) on the supply and return sides are each provided with a temperature sensor ( 28, 29 ) and that the temperature sensors ( 28, 29 ) and the travel meters ( 19 ) are connected to a multiplication circuit ( 31 ). 2. Arrangement according to claim 1, characterized in that the multiplication circuit ( 31 ) of each radiator ( 11 ) is connected to an addition circuit ( 33 ). 3. Arrangement according to claim 1 or 2, characterized in that the multiplication circuit ( 31 ) and / or the addition circuit ( 33 ) are connected to a measured value display ( 32, 34 ).