DE2722485A1 - Electronic determn. for heating costs - enables temp. differences to be obtained for each specified volume of water flowing through consumer unit - Google Patents

Abstract

Control heating costs are calculated for each heating unit in a central heating system. A device checks for each unit the temp. difference voltage between heat inlet and outlet. These difference voltages are transmitted to a central station, where they are added and stored for each consumer unit. A display device is provided in the central station. Each consumer uni thas a flowmeter whic makes possible the delivery of temp. difference voltages after a certain volume of water has flowed through. The temp. difference measuring device and the flowmeter are connected through a control circuit to a collecting line common to all consumer units and the central station. The temp. difference voltages are cylically interrogated by the central station and transmitted to it.

Description

system for the electronic determination of heating

and hot water costs per unit of consumption, the invention relates to a system for the electronic determination of heating and hot water costs per consumption initiation according to the preamble of claim 1.

Such a system is known from I) T-OS 2 214 294. ei this System, a separate line is required from each consumer unit to the control center.

In addition, the determination of the relative lioiskoaton is imprecise, there only the radiator temperatures and not the ambient temperatures are taken into account will.

It is the object of the invention, based on this reference, specify a system for the electronic determination of licensing and hot water costs, <Jas gets by with a single manifold and that the display of the host in currency units.

The task is given in the characterizing part of claim 1 Means solved, whereby it should be pointed out that it is, for example, from the DT-OS 2 316 718 is known, the relative or absolute amount of heat by measuring the and return temperature depending on a predetermined flow rate determine. Advantageous further developments are given in the subclaims.

The invention will now be explained in more detail with reference to the drawings, for example Explained it show: Fig. 1 is a schematic representation of the system, 2 shows the control circuits and the display device provided for each consumption unit the control center Fig. 4 a pulse diagram In Fig. 1 is a schematic of the line and hot water supply system of an apartment building with n consumption units (Apartments) shown. In each apartment is a flow meter Dl to Example of a pinwheel meter, arranged in the return of the total heating circuit of the apartment. There is a TV temperature sensor in the flow of the heating circuit and a T temperature sensor in the return TR provided. Dl, TV and TR are an electronic control circuit Al on a collecting line SL1 connected.

A flow meter D2, a temperature sensor TW and a control circuit A2 are available. As below is explained, the metering values reach a control center via the collecting line SL1. After processing the measured values in the control center, this gives the actual operating costs in currency units via the same bus line SL1 to operating cost display devices B back to each apartment. There is also a flow meter in the control center D3 for the cold water connection of the heat exchanger, a temperature sensor TK for the Cold water temperature and a flow meter D4 for heating oil available.

Fig. 2 shows the parts of the system assigned to an apartment. Except the already mentioned temperature and flow meters, these are a control circuit Al for measuring the amount of heat given off by the heating circuit, a control circuit A2 for measuring the hot water consumption and the operating cost display device B.

These three parts are connected to the collecting line SL1.

The collecting line consists of a clock line, a data line, an address line and a voltage supply line that carries + 10V. as Earth line (CV) is used by the heating system's line system.

The sensors for the temperature and the flow rate are connected to the Control circuits A1 and A2 connected.

) he impeller meters D1 and D2 streak once with each revolution the water volume contact WK and thereby set flip-flops FF1. The two temperature sensors TV and TR supply voltages proportional to the flow and return temperature. A differential amplifier uses this to generate the one proportional to the temperature difference Voltage aUT In the hot water circuit, the input of the differential amplifier for the Return temperature set to 0V # 0 ° C.

Each control circuit contains an address flip-flop FF2.

By connecting 2n sensors in series, they all form address flip-flops a 2n-stage shift register, the stages of which are distributed to the control circuits are.

The control center (Fig. 3) shifts through this n-stage shift register a logic "0" and thereby addresses the control circuits in the sequence their spatial arrangement.

is a control circuit by the logical "0" ao data input of their Address flip-flops? F2 marked and has the impeller counter set the flip-flop FF1, then the clock switches via an analog switch Temperature differential voltage # UT on the data line and then resets FF1. Does it turn Impeller counter not, then FF1 is not set.

A control circuit addressed by the control center can be used in this Case, do not release tension. (0V on the data line) If a system contains 2n sensors, where the maximum speed of an impeller meter is in revolutions / s, then the query rate of the sensors must be greater than 2nm tiz, so that no information get lost.

In addition to the 2n sensors, there are also n operating cost display devices on the collecting line connected, the clock frequency must be greater than 26nm Hz.

The central unit receives a unit flow rate via the data line (for example 1 cm³) the temperature difference between the heating flow and return, or the temperature of the hot water related to OOC.

It is known that the amount of heat consumed can be determined by numerical integration. This amount of heat W is: Here p is the constant amount of water that corresponds to one revolution of the impeller meter and # UT is the temperature differential voltage between the heating flow and return or between the hot water and the cold water connection on the boiler. This relationship shows that the amount of heat withdrawn from any consumption unit can be determined in the control center by converting all associated UT values from analog to digital and adding them up.

> The operating costs calculated from the relative amounts of heat in the control center are via the collecting line SL1 to the operating cost display devices B in transferred to the apartments. The operating cost display devices contain tubes instead of an address flip-flop, a 24-bit address shift register SR1. The operating cost display devices remain addressed over 24 clocks. during these 24 clocks the Centralize the 6-digit operating costs in BCD code to the operating cost display devices. This method ensures a minimum of effort in the control circuits and the operating cost indicators, however, requires the central office to inform is the order in which the control circuits and operating cost indicators are arranged on the collecting line SL1.

A typical pulse diagram for the bus line SL1 is shown in FIG shown. 4 shows how the control circuits A1 and A2 are queried and then another 24-bit shift register SR2 in the associated The operating cost display device is loaded with 24 bit (NRZ format).

The actual operating costs display is with the shift register SR2 connected, on which the current status of the operating costs can therefore always be read. The same processes then run for the other consumption units.

The center is shown in Fig.3. The essential components the control center are a digital processor, a memory for fixed values, a memory for measured values, a power supply (possibly with an emergency power supply) and input and Output devices.

These assemblies exchange data with one another via a second collecting line SL2, which in turn directly or via an analog / digital converter with the first Collector line SL1 is connected.

The entire program flow in the headquarters is from the digital Processor controlled. Each consumption unit has exactly one in the test value memory Location.

The following information is stored in this memory location during installation Burned in once.

- Area of the consumption unit - Arrangement of control circuits and the operating cost display device on the SL1 collecting line - and if necessary, the number of capacity and hot water sensors.

The read-only memory also contains a memory location for the Total area of all consumption units.

The measured value memory also has one for each consumption unit Location. This storage point / consumption unit provides space for the relative Heat consumption in the heating circuit and for the relative heat consumption in the hot water circuit.

The measured value memory also has a memory location for the Sum of the relative heat extraction of all consumption units in the hot water circuit (# WW) and a storage location for the sum of the relative heat extraction of all consumption units in the heating circuit (# WH).

The entire control now works as follows. By a key switch the control center is brought to the starting position. Then runs into the processor Start program, which clears the measured value memory, sends a logical one to the address line "1" creates and opens the clock line 106 clocks (corresponds to about 1a ) gives.

The start program then also creates the logical "1" the data line and puts another 10 clocks on the clock line.

This measure has the consequence that all control circuits are switched off and all operating cost display devices are set to zero in a defined manner. Above The input will now be the fuel costs and, if already known, the host entered for maintenance and servicing When entering the fuel costs two alternatives are provided. if heating oil is used as fuel, then can the price / liter of heating oil can be entered. Together with the amount of heating oil that has flowed through n4 the processor can calculate the fuel costs itself.

Are other substances used or should the flow meter be used? D4 can be saved, then instead of the fuel costs, an estimated value for the sosten / heating unit can be entered in the central unit. The calculation of the pro rata operating costs then occur over the year on the basis of this estimated Worth. If the actual fuel costs are entered at the end of the heating season, then the head office automatically corrects the pro rata operating costs. This correction is naso less, the more accurate the estimated value was.

After the start program, the actual work program begins. That The first step in the work program retrieves the characteristics of the consumption unit 1 the read-only memory (address t} in the processor. Correspondingly this The processor queries the control circuits of the system via the bus SL1 Consumption unit 1. If the characteristics say, for example, that the first consumption unit one sensor for the heating, one for the hot water and an operating cost display device in the given order (usual case), then the following happens away.

The processor applies a logical "O" to the address line and returns a clock on the clock line. By this measure, the control circuit A1 the consumption unit 1 is addressed and the measured value # UT via the analog / digital converter given to the processor.

l) then the processor addresses memory location 1 in the measured value memory, fetches the stored heating consumption from there, adds the digitized one to this Measured value aUT and writes the total back to the measured value memory under address 1. The measured value aUT is also used as a storage location for the sum of the relative heat extraction of all heating consumption units (£ # WH) added up by a further cycle the clock line and a logic "" 1 "on the address line is then the hot water control circuit A2 is addressed. Their measured value # UT is also digitized, converted to the actual cold water temperature and transferred to storage location 1 ( relative heat extraction in the hot water circuit of consumption unit 1) added. This MeßwertUT is also added to the total storage location #WW.

In the next step, the processor calculates the proportional operating and maintenance costs of the consumption unit 1 and transmits them to the operating cost display device.

The proportional total costs K of a consumption unit are calculated according to the relationship Fuel costs. Water costs (boiler) area + - maintenance costs total area here is: WH: heat extraction in the heating circuit of a consumption unit 2: heat extraction in the heating circuit of all consumption units WW: heat extraction in the hot water circuit of a consumption unit # WW: heat extraction in the hot water circuit of all consumption units.

For all other consumption units, the cost recording takes place after exactly the same program sequence.

In addition to or instead of the display in the control center, a printing unit connected directly to the cost accounting for each consumption unit expressive L e r s e i t e

Claims (6)

Claims 1. System for the electronic determination of investment costs per consumption unit in a central unit of a collective heating system, in which a Device for each consumption unit to determine the temperature differential voltage between heating flow and heating return, means for transferring the temperature difference values to the control center, means for adding up and storing the temperature differential voltages Per consumption unit and a display device are provided in the control center, characterized in that a flow meter per unit of consumption in a manner known per se is provided, the delivery of each after a certain amount of water has passed through the temperature difference voltages enables the device to determine the temperature differential voltage and the flow meter via a control circuit connected to a common line for all consumption units and the control center and that the temperature differential voltages of the consumer units from the control center can be queried cyclically and transmitted to the control center. 2. System according to claim 1, characterized in that each consumption unit In addition, a device for the flow rate-dependent measurement of the temperature difference voltage of the hot water, with a voltage corresponding to the temperature OOC as a reference value is used and that the temperature differential voltages across the common manifold are transmitted to the head office using the time multiple procedure and there, after conversion to the actual cold water temperature to the heating temperature differential voltages the same consumption unit can be added. 3. System according to claim 1 or 2, characterized in that in the Central a microprocessor, an Elagabeeinrichtung for the fuel costs Memory for fixed values and a memory for measured values are provided, which are among each other are connected via a second manifold that this directly or via a Analog / digital converter is connected to the first bus and that the microprocessor per unit of consumption from the fuel costs and the temperature differential voltages Cyclically calculated currency units taking into account the total consumption and these at a display device provided in each consumption unit transmits via the manifold. 4. System according to claim 3, characterized in that the microprocessor Maintenance and repair costs that can be entered according to the area of the consumption units divided, added to the pro rata operating costs and the sum to each in transmits each consumption unit provided display device via the bus. 5. System according to claim 3, characterized. that the first manifold next to the power supply lines for the control circuits and display devices of the consumption units a clock line, an address line and a data line and that the addressing of the control circuits and the display devices via a shift register distributed across the and the data output at the same time the addressing takes place. 6. System according to claim 1,2,3, characterized in that the microprocessor the efficiency of the heating system from the fuel consumption and the total heat extraction calculated.