DE3130538C2 - Electronic heat cost allocator for a number of apartments - Google Patents

Abstract

A measuring arrangement for measuring and displaying the proportional amounts of heat given off by the radiators in a given number of apartments in a house or a block of flats has at least one radiator temperature sensor in the form of at least one temperature-dependent resistor for each of a given number of radiators in an apartment, with all temperature-dependent resistors are connected in series in each case to form an output signal that is dependent on the radiator temperatures. At least two measuring circuits with the series connection of the temperature-dependent resistors are provided for each apartment. The measuring device also has switching means which each sequentially switch on a constant current source serving for the power supply to the respective associated measuring circuits of an apartment, these switching means being actuated by a central measuring and control device, with the aid of which the proportion of heat actually consumed in each apartment is calculated and is displayed digitally on a subsequent central display device for each individual apartment and overall for the entire apartment block. A microprocessor, which also processes the reference signals of a reference circuit, is used to obtain the display signals.

Description

60

The invention relates to an electronic heating cost allocator for a number of apartments according to the preamble of claim I.

A measuring arrangement of this type is essentially already known from DE-OS 29 25 116. In particular (.5 is a circuit arrangement for the electronic detection of radiators in this publication Apartment during a freely selectable period of time describes the amount of heat given off to the Temperature sensors connected in series and attached to radiators and at least one room temperature sensor The series connection of the radiator temperature sensors forms one branch of the bridge a Wheatstone bridge, during the the series-connected room temperature sensors form the other branch of the bridge. With this well-known Circuit arrangements serve as radiator temperature sensors, temperature-dependent resistors, especially NTC resistors with a practically linear temperature dependence

In addition, the supply voltage of the Wheatstone is in the mentioned, known measuring arrangement Bridge only delivering pulse generator and eir at discrete, equidistant points in time. from the Pulse generator triggered sample and hold circuit provided that the bridge diagonal voltage during saves the time between two pulses while the output voltage continues of the scanning and Hall circle in a pulse train with one of the output voltage proportional Frcqucn / converting voltage-frequency converter is provided is. Finally, the resulting impulses are sent via a display indicating the amount of heat consumed Integrated counter. In addition, a central display unit can also be provided by means of which the individual apartments in a block of flats, the total amount of heat consumed is displayed.

For the fairest possible allocation of heating costs within a larger apartment unit, residential building, Block of flats or the like on the individual apartments It is essential that the amount of heat given off by the radiators in each apartment is accurate can be determined and safely recorded.

It is known to use radiator sensors that measure the amount of heat given off by a radiator the base of the mean radiator temperature. From this measured variable, taking into account the Nominal output of the radiator a measure for the proportional heat consumption can be derived. It must It must be ensured that no manipulations are carried out unnoticed by the apartment owners can.

From DK-OS 29 12 522 there is a circuit arrangement for determining the electrical consumption of individual heat consumers, in particular radiators and / or Hot water taps are known to have a heat source are supplied with a compact housing, which is in direct contact with the radiator or heat transfer medium is arranged. From DE-OS 29 12 522, in particular, the geometric arrangement described by switching elements that are located in the compact housing.

The invention is based on the object of providing an electronic heat cost allocator of the initially mentioned specified type, which offers greater functional reliability and security against manipulation and which in can be easily installed.

This task is achieved according to the invention with an electronic heating cost allocator of the type defined at the outset solved with the means of the characterizing part of claim I.

Advantageous further developments and refinements result from the dependent claims in connection with the description.

The invention is based on the attached drawings, in which Auslührungshci.spiclu and Schal-

tungsdctails are shown, explained in more detail shows

Fig. Ϊ́ a block diagram of the measuring arrangement according to the invention,

2 shows a circuit arrangement with two measuring circuits for radiator temperature measurement for an apartment, as in the measuring arrangement according to FIG. 1 each of apartments is used, and

3a shows a first exemplary embodiment of a switching example for a * temperature-dependent resistance circuit of an apartment unit as well as a reference circuit,

3b shows a second exemplary embodiment analogously Fig. 3a, and

Fig. 4 is a timing diagram of the measurements.

As can be seen from Fig. 1, for a given number of, e.g. B. ten apartments W, to W _w , for the sake of simplicity only the first apartment W ₁ and the last apartment W _{10 are} shown schematically, each provided circuit arrangements Z ₁ to Z. _b for I lci / body temperature measurement or room temperature measurement. Such a circuit arrangement Z ₁ is shown in detail in FIG. 2 for an apartment W, with z. B. six radiators shown. This circuit arrangement Z \ has two measuring circuits M ₁ and M ₂ , both of which are connected in parallel. Each of these measuring circuits Λ /, or M ₂ consists essentially of a series connection of temperature-dependent resistance circuits Z ₁ , (i = 1 to 10 - apartments; j = I to 6 - radiators per apartment -), with PTC or. NTC resistors, whereby the resistance circuits can be designed as radiator temperature sensors.

Two each in the parallel measuring circles M ₁ and M? lying temperature-dependent resistance circuits z. B. 29 and 30 are attached to a radiator. The same also applies to the other temperature-dependent resistances of the measuring circuits M 1 and M 1, which are parallel to one another and are connected as a two-pole with an input pole 25 and an output pole 26.

On the input side, each measuring circuit M _t or M _{2 has} a temperature-dependent circuit Z ₁ , a pair of diodes 27, 28.

Finally, the circuit arrangements Z ₁ each have a third measuring circuit My , which lies between the input pole 25 and the output pole 26, each of these third measuring circuits Λ / j having a capacitor 41 unc ^{1 is used} to monitor the circuit arrangement against manipulation, as further is explained in more detail below.

If it is initially said that the temperature-dependent resistance circuits of the Oeiden measuring circuits Λ /, and Mi each serve as a body temperature sensor, it is also possible, according to a modification of this circuit arrangement, that ζ. B. the one measuring circuit M \ is only used to record the radiator temperature, while the other measuring circuit Mi is used to generate an output signal proportional to an average room temperature, with temperature-dependent resistors (PTC, NTC) placed in series in each room of the apartment W ₁ .

In any case, the circuit arrangement Z ₁ , ie the two measuring circuits Λ / · and / VZ 2 and possibly also the third measuring circuit M ₃ , is used for power supply, a _{constant current source 2 connected} to a schematically illustrated central bus 1, which is assigned to these measuring circuits Constant current source 2 or a pulse generator supplies a square-wave ^{alternating current /, +} , / f of a predetermined first frequency /, which is routed via lead L _x to input terminal 25 of circuit arrangement Z \ and via lead L ₂ from output terminal 26 to central bus 1, the circuit arrangement Z] is connected to the leads L \ and L ₂ via terminals A _x , B _x (see FIG. 2).

In Fig. 1, a modified circuit arrangement is shown in dashed lines, with a constant current source 2, which supplies _{constant currents Z 1} ⁺ and I ₂ *. In this case, a switch 7 is necessary at the output of the central bus 1.

An output measuring line 3 branches off from the terminal B _x and leads to an operational amplifier 8, which is explained in detail below with reference to FIG.

The measuring device now also has a switching center; for sequential switching on ier Konstantstromquellc 2 aul the associated circuit order Zi to ZiO, which is arranged in each of the apartments W _x to Wi ₀ , whereby the individual circuit arrangements Zi to Ziu can be queried one after the other.

Di. "Control of this sequential connection is described in more detail below.

A common central measuring and control device 15 is provided for all apartments W _x to W _{10, which contains the following components in detail:}

The already mentioned operational amplifier 8, a multiplexer 9, an analog-to-digital converter 10, a Microprocessor 11 and possibly a driver 12 door a connected or connectable cassette recorder 14. Furthermore, when operating a Konsianiiifoiiiquciic 2, which only gives positive sirömc, a changeover switch 7 may be provided.

The microprocessor 11 is coupled via a line 18 to an input 19 of a timer 13, which on the other hand is connected to the central bus 1 via a line 17.

Furthermore, the central measuring and control device 15 is followed by a display device 16 for digitally displaying the total amount of heat given off by the radiators of each apartment W ₁ to W _10.

The display device 16 has a counter 43 for each apartment, it being possible for this counter to be designed as an electromechanical counter with number wheels or as an electronic counter with a digital LCD display. Finally, a totalizer 44 is also provided, which adds up the total heat quantity of all apartments W ₁ to W _xo.

In detail, a line transmitted the measurement results leads from an output 20 of the microprocessor U to the input 22 of the display device 16, which, as mentioned, has a number of heat meters 43 corresponding to the number of apartments W] to W _w as well as a totalizer 44 which is used for Display of the total amount of heat given off by all radiators in the apartment block. As mentioned, a driver 12 can be provided on the microprocessor 11, which via an output 21 with an input 2? a cassette recorder 14 is connected, which is used to store the total amount of heat given off by the radiators of each apartment, wherein such a storage can be provided in addition to the display device 16 or to replace it.

As mentioned, for example the measuring circuit M _{2 of} the circuit arrangement Z shown in FIG. 2 can be used to generate a reference signal proportional to the average room temperature.

In the event that both measuring circuits M \ and Mi are each installed in a radiator temperature sensor, the result is:

15th

Z, - £ FTC, Z _n = I] NTC.

In the event that the second measuring circuit is housed in a room temperature sensor, results the following system of equations:

25th

JO

Σ NTC.

The series connection of the circuit arrangement Z | A reference circuit Zq with a reference resistor R _{0 is} assigned to Zio of the ten apartments, the function of which will be explained in more detail later.

The operation of the measuring device according to the invention is such, wherein initially provided it follows that a room temperature of _R d = imaginary, assumed 20 ⁰ C = constant proportional to the reference signal is supplied by the reference circuit Zogeliefert and the operational amplifier. 8

The overall power supply of the circuit arrangements Z \ to Z ₁₀ installed in the individual apartments W ¹ to W 1 J ₀ for recording the hay body temperature with bipole currents / * and / _; ⁺ is carried out by the power source 2. It is assumed here that, for example, a total of six radiator sensors (temperature-dependent circuits Zy) are present in each of the apartments W \ to W \ (, the temperature-dependent resistors attached there corresponding to the circuit arrangement Zi in shown in FIG If the current source 2 is now connected to the circuit arrangement Z \ in accordance with the sequential switching operation, for example, this is fed with a square-wave alternating current, the diodes 27 and 28 present on the input side in each measuring circuit M ₁ and M _2, each in series with the temperature-dependent resistors of each measuring circuit, serve as valves, in such a way that the diode 27 is switched through by the respective positive and the diode 28 by the respective negative half-wave of this square-wave alternating current, as shown in FIG. 3 will be explained in more detail later, which a predetermined frequency / b it sits. This frequency / becomes what is not shown in detail. generated by the timer 13 controlled by the microprocessor 11, the frequency / of the square-wave alternating current feeding the two measuring circuits Mi and Mi being preferably selected so that this frequency / is outside the spectrum of technical frequencies licgl. As a result, it is possible to reduce the interference of such frequencies towards zero as desired.

On the other hand, the timer 13 can be designed to generate a further frequency / which is greater than the frequency /, this frequency / 'serving to feed the third measuring circuit KU with the capacitor 41. With this third measuring circuit A /, the measuring lines of the respective series connection with the temperature-dependent resistors can be monitored with regard to any manipulations, for example with regard to the connection of a series resistor in these measuring lines. The frequency / used for such monitoring purposes is preferably chosen so that the reactance of the capacitor 41 located in the third measuring line M \ is very small.

When the circuit arrangement Z \ is in operation, namely by being fed with the square- wave alternating current , then by means of the positive I loaf wave via the first measuring circuit M ₁ and by means of the negative half-wave via the second measuring circuit Mi to the respective in series lying temperature-dependent resistors generates voltage drops U ₁ and U ₂ , which are proportional to the respective resistance values of these temperature-dependent resistances at the actual temperatures of the radiators. At the output 26 of the circuit arrangement 1, the summed voltage drops of both the positive and the negative half-wave of the square-wave alternating current fed into the two measuring circuits M and Mi with the frequency / are available, these resulting voltage drops being proportional to the temperatures of all radiator surfaces. These voltage drops are now fed to the operational amplifier 8 as output signals via the line 3, which branches off from the terminal S.

The further processing of the operational amplifier applied signals, d. H. that is, the output signal of the circuit arrangement Z, and the room temperature reference signal now takes place with the help of the central measuring and control device 15.

The microprocessor 11 sets sequentially, e.g. B. with the help of the timer 13, during the time segments; ,, to t _w the reference _{resistor Z 0} and the series connection of all NTC or PTC resistors Z _n .,., (/ = 1 - installed in an apartment IY ₁₎ 6; r = 1 -10) or Z,.,., To the central bus 1 of the house control center 15. Each time within these time segments / ₀ to r _{: o} the Mikrocor controls. ? .u ter 11 to the current source 2, which then feed a positive or negative constant current into the central bus 1 during the period T \ or τι.

At the resistors Z ₀ , Z _n ,,; Thus, the tensions fall Z _pir

Ui - I \ ' ZipTC
U ₂ = I ₂ ■ Z, _NT c

At the same time, the voltage drop across the reference resistor R _{1 is} measured

Uf = R _n -Ii

Uf = R ₀ -I ₂
from this the microprocessor 11 calculates:

Uf

/ ur time: I ₁ , (/ ,, / ■).

From the measured U, and U ₂ and the calculated I ₁ and / _? surrendered:

υ.

R ₀

R ₀

It should be pointed out again that with bipolar currents / ', / "no switch has to be provided, while with positive constant currents / | ⁺ , I ₂ a multiplexer or changeover switch? Has to be provided.

From the current source 2 is assumed that it remains constant, the constancy over the Zeil as should also be infinitely good in terms of temperature.

The measurement of the temperature-dependent NTC or I'TC resistances is thus carried out via a voltage measurement with the aid of the impressed currents / or I ₂ . All errors that may be due to a possible inconsistency of the sources of the stium I 1 and I ₂ are eliminated because, as mentioned, before each measurement cycle f | to in, the currents I ₁ and Λ are calculated from the microcomputer 11, the voltages U \ and U _{2 being} measured via the analog-to-digital converter 10 and input into the microcomputer 11.

The result of the above-described calculation of the determined by the microprocessor 11 is now Temperature difference calculated according to the amount of heat, integrated over time and as one Pulse sequence that corresponds to the total amount of heat given off by the radiators in an apartment, given to the display device 16.

An energy quantity counter of this display device 16 assigned to the respective apartment W 1 to W _{10 shows the resulting measured value digitally.}

These heat meters can, in a known manner, be either electromechanical Counters or appropriately buffered, seven-segment indicators (LCD).

As shown in FIG. 4, the cycle i> ... / κ, repeats itself, each time unit D _{0 being} composed of the two times I ₁ and r>. As a result of this sequential connection of the power source 2 to the respectively assigned circuit arrangements Zi to Zm, which is provided according to the invention, the previously described measuring process for the radiator temperature and possibly also for the room temperature detection is repeated for each individual apartment W _x to W _w of the entire block of flats on a periodic basis.

In the measuring device according to the invention, the individual heat meters of the display device 16 can thus be continuously and sequentially updated with relatively simple means, which corresponds to the actual heat consumption per apartment W _x to W _1n

At the same time, with the help of the totalizer 5 of the display device 16, they know of all the radiators The total amount of heat given off in the apartment block can be displayed as a total.

Instead of using a given room temperature reference signal but it is also possible to give the operational amplifier 8 a mean room temperature proportional reference signal per apartment / u / uführcn, namely that a generation such a room temperature lkv.ugssignales with With the help of a series connection of temperature-dependent resistors serving as room temperature sensors he follows.

In such a case, the measuring device according to the invention can be used to measure the temperature difference be carried out, the difference between the mean temperature of all radiator surfaces an apartment and the mean room temperature is determined.

A simple possibility for this is that each circuit arrangement Z \ to Z _{i0 is modified} in such a way that one measuring circuit M \ is used to determine the radiator temperature and the other measuring circuit M _{1 is used} to determine the room temperatures. In one measuring circuit M ₁ , those in series there are more temperature-dependent! Resistors 29, 31, 33, 35, 37, 39 of the temperature-dependent resistance _{circuits Zi to Z, t6 are} each assigned to the radiators of an apartment W _{ , the temperature-dependent resistors 29 ... in FIG. 2 only as a symbol for a complete temperature-dependent resistance Status circuit are shown. The temperature-dependent resistors 30, 32, 34, 38, 40 of the temperature-dependent circuits Z _n to Zn _{6, which} are in series in the other measuring circuit M _2, are each assigned to a room in the apartment.

In Fig. 3a is a temperature-dependent circuit Z _/; an apartment w. shown. ^{Square-wave alternating currents /, +} and / ₂ "are generated by the constant current source 2. These are fed via diodes to a circuit with the measuring circuits M _x and M ₂ .

wherein in the measuring circuit M \ a temperature dependent resistor 30, a PTC resistor and / a temperature-dependent resistor 29, for example an NTC resistor is arranged in the measuring circuit, for example Λ. 2

The positive current f * flows, as indicated by dashed lines, through the PTC resistor 30, while the negative current Λ, as indicated by dash-dotted lines, flows through the NTC resistor 29 of the measuring circuit M _2. The corresponding voltage drops U], U ₂ can then be picked up at the transistors, which is a measure of the amount of heat given off by the heating element of the circuit Ζ, ι. The voltages U _x and U _{2 are} fed to the microprocessor 11 via the analog-digital converter 10 via an output circuit (not shown in more detail)

In Fig. 3a the reference circuit Zq is also shown, which is fed with the constant currents I *, I { and can be set to a specific room temperature reference voltage with the aid of the potentiometer R _0.

The radiator temperature measuring circuit M \ is thus fed with the positive half-wave of the square-wave alternating current fed in and the room temperature measuring circuit M ₂ with the negative half-wave of this square-wave alternating current, so that, as explained, voltage drops occur at the outputs of the two measuring circuits M \ and M ₂ which are proportional on the one hand to the mean temperature of the radiator surfaces and on the other hand to the mean room temperature.

The respective output signals of the two measuring circuits M \ and Mi may then via lines 3 and 4, the Operationsverstärker8 provided, wherein the further signal processing takes place in the above-described manner.

FIG. 3b corresponds essentially to FIG. 3a, with only the constant current source 2 supplying positive currents, namely I] and I {. In this case, the switch or multiplexer 7 is necessary.

It is also possible, with the aid of the microprocessor 11, to carry out plausibility checks and minimum-maximum measurements with regard to the detected voltage drops during the feed-in of the positive ones and negative half-waves of the bipolar square-wave alternating current fed to a circuit arrangement Zi to Zio be carried out, so that manipulations on them are immediately recognized and displayed can be.

To this end, it is advantageous if, as explained in connection with FIG. 1, a signal lamp 42 is assigned to each counter 43 of the display device 16, each signal lamp 42 being switched on in a resistance-dependent control circuit (not shown), each control circuit actuating a relay Has holding or working contact which is actuated when the total resistance of a dwelling circuit arrangement Z] to Zio changes above a predetermined limit value. This makes it possible that in the event of any manipulation of the radiator sensors or the temperature-dependent circuit arrangements Z ", for example by cutting a line, ie the total resistance becomes infinite, or by bridging a resistor, which decreases the resistance value, a signal that can no longer be erased is triggered. The signal lamp 42 is kept under current by the control circuit, even if the manipulation carried out should be reversed.

Finally, the total resistance value present in the circuit arrangements Zi to Zm can be measured via the terminals A _x , B ₁ or A- _M , Si ,, in each supply line L ₁ - "nd L · with the help of an optionally operable control resistance meter and, for example, with a target value For this purpose, the connection to the power source 2 must be briefly interrupted while the ohmmeter is switched on, for example at terminals A ₁ , B].

For this purpose 4 sheets of drawings

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45

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Claims (4)

Patent claims: 1.Electronic heat cost allocator for a number of apartments with temperature-dependent resistors serving as radiator temperature sensors, which are connected in series for each apartment, at least one microprocessor and with a central display device, I denote η et that for each apartment (W, ... (earlier a single-core line at least two measuring circuits (Mi, M ₂ ) each with a series circuit of temperature-dependent resistance circuits (ZiJ · · · Zifi) are connected, so that a constant current source (2) is provided for powering the two measuring circuits (Mi, Af _{2) in each apartment} that switching means (7,13) for sequential connection of the constant current source (2) ai »f the associated measuring circuits (6f, M ₂ ) are provided, that the switching means for sequential connection of the constant current generator (2) to the associated two measuring circuits ( M ,, M}) each of an apartment (Wi ... W ₁₀ ) one from the microprocessor (II) of the central measuring and control device ng (15) controlled timer (13), which applies the constant current source (2) with appropriate control signals, so that a sequential connection via the respective supply line (L ₁ , L ₂ ) to the respective associated measuring circuits (Mu M ₂ ) takes place and that the central measuring and control device (15) common to all apartments (W _x ... W _t0 ) is supplied with a reference temperature reference signal. 2. Measuring arrangement according to claim 1, characterized in that an upstream reference circuit (Z ₀ ) is provided for generating a predetermined reference signal, which is fed by the constant current source (2) and from which a voltage drop (Uf) _{proportional to a reference resistor (A 0} ) is tapped will. 3. Measuring arrangement according to claim I or claim 2, characterized in that each Counter (43) of the central display device (16) is assigned a signal lamp (42) that each Signal lamp (42) is switched on in a resistance-dependent control circuit that each control circuit has a relay-operated holding or working contact which, when the total resistance changes an apartment switching arrangement (Zi ... Z10) above a specified limit value is operated. 4. Measuring arrangement according to one of claims 1 to 3, characterized in that between the display device (16) and evaluation device (15) an optionally operable control ohmmeter (45) is switched.