DE3050923C2 - - Google Patents

Description

The invention relates to a device for measuring heat consumption according to the preamble of claim 1.

Such a device is the subject of the patent application P 30 44 262.7 and serves to intervene in the heat consumption measurement by unauthorized persons, as in a known heat consumption measuring device according to DE-OS 27 11 437 are given: There is in one a memory allocated to a microprocessor is a digital one Number that corresponds to the current heat consumption, which calculates signals from the microprocessor which is the flow temperature, the return temperature and the throughput of heating medium at the measuring point under consideration correspond. The content of this memory is used for Control of a frequency generator, whose output pulses be placed on a conventional counter. By interrupting the line between frequency generator and counter the counting result can be falsified.

The present invention is intended to provide a device for Measuring the heat consumption according to claim 1 to that effect be further educated that easy decentralized reading of the read / write memory is possible.

According to the invention, this object is achieved by a device according to claim 1.

The reading takes place in the device according to the invention of the result of the heat consumption measurement Read / write memory without the operator of the reading device. The measurement results recorded by the latter can be easily processed in a central computer.  

Advantageous developments of the invention are in the subclaims specified.

With the development of the invention according to claim 2 achieved that the reader is particularly compact and is light in weight. Because data on magnetic Disks can be recorded in high packing density can read the results of a variety of apartments easily by mail to the head office of the accounting company be transferred.

The development of the invention according to claim 3 enables it that initially does not directly reflect heat consumption read out measurement results in heat consumption values to convert. The computer can also check directly Checks whether all measuring units belonging to an apartment are checked and, if necessary, can specify which Heat measuring units can still be read.

In a device according to claim 4, the reading device easily the respective measuring point in the form of alphanumeric Data can be entered. There may also be other comments and data that can be important for billing, can be entered.

In a device according to claim 5, the individual Measuring units, which quartz crystals with production-related Fluctuation in the temperature response of the frequency, calibrate easily on the spot, using the correction factor either on the recording device of the reading device recorded for later central consideration or in additional memory cells of the read / write memory  is read.

With the development of the invention according to claim 6 achieved that the correction factor for the real temperature response the frequency of the quartz crystal of the considered Measuring unit at the same time as reading the heat consumption can be checked. The newly measured temperature factor can then be in the central computer together with the Correction factor measured at the beginning of the reading period even more precise determination of heat consumption used will.

With the development of the invention according to claim 7 achieved that the reference measuring unit and that on the heat emitting Partly attached measuring unit in good heat-conducting Are in contact, i.e. at the same temperature.

The development of the invention according to claim 8 is also with a view to avoiding temperature differences between Reference measuring unit and measuring unit to be read is an advantage.

According to claim 9, an easily detachable, thermally well conductive connection between reference Obtain the measuring unit and the measuring unit to be read.

The development of the invention according to claim 10 is in view on a simple construction of the plug, on a simple Attach the reference measuring unit in the connector and on a simultaneous good thermal coupling between the Reference measuring unit and the measuring unit to be read is important.

With the development of the invention according to claim 11 achieved that the reference measuring unit and the transmission block can be quickly warmed up to a temperature  which is close to the temperature of the measuring unit to be read lies. With the heating resistor switched off, you can then Complete the temperature compensation. Switching off the Heating resistor at the right time can easily drop below Comparison of the output signals of the reference measuring unit and of the measuring unit to be read by the reading device will.

In a device according to claim 12 you can already in Readout device that implicitly reflects heat consumption "Warm time" by comparison with a time standard in a Convert the number that better characterizes heat consumption.

The development according to claim 13 is with regard to extensive standardization of device parts and on a directly comparable work of the timepiece and the Measuring units an advantage.

With the development of the invention according to claim 14 achieved that the existing heat meter at the same time as a temperature sensor working with very high resolution can use.

The development of the invention according to claim 15 is in With regard to particularly low production costs in large Quantity of heat measuring units required is an advantage. You don't have to tune the quartz crystals precisely, Rather, this can be done directly with the production-related Use tolerances.

With the development of the invention according to claim 16 in a simple way and without any structural measures precise calculation of heat consumption possible, which also the heat flows within a building between various apartments through walls and ceilings and the  Temperature.

The invention is described below using exemplary embodiments explained in more detail with reference to the accompanying drawing. In this shows

Fig. 1 at A) is a schematic view of a mounted on a radiator Wärmemeßeinheit, wherein b) is a schematic view of a room of a building whose walls are provided with a plurality Wärmemeßeinheiten, and c) a top view of a device for reading out the Wärmemeßeinheiten;

FIG. 2 shows a block diagram of a heat measuring unit and a read-out device which cooperates with it;

3 is a block diagram of an alternate Wärmemeßeinheit and cooperating with their reader.

Fig. 4 is a block diagram of a further modified Wärmemeßeinheit;

Fig. 5 is a block diagram of a further modified Wärmemeßeinheit; and

Fig. 6 is a vertical section through a connector, via which the reader can be connected to the heat measuring units.

In Fig. 1 you can see two fins 10 and 12 of a radiator of a central heating system. Legs 14 of a holder 16 made of sheet metal are welded to the radiator fins 10 and 12 . The latter also has edges 20, 22 folded over from a plate-shaped base section 18 .

In the trough-shaped space delimited by the legs 14 , the base section 18 and the edges 20, 22 , a heat measuring unit, designated as a whole by 24 , is accommodated (cf. also FIG. 6). A corrugated spring 26 , which is supported on noses of the edges 20, 22 ( not shown) , holds the flat back of the housing of the heat measuring unit 24 made of heat-conducting material in flat contact with the flat bottom section 18 of the holder 16 , possibly with the interposition of a plastically deformable layer of good heat-conducting material if the two contact surfaces of the holder 16 and the heat measuring unit 24 are not precisely machined. A sealing wire 30 closed by a seal 28 prevents the unauthorized removal of the measuring unit 24 from the holder 16 .

The floor section 18 faces the interior of the room and is provided on its outside with an embossed identification 32 characterizing the measuring point, e.g. B. provide a letter / number combination. In the bottom section 18 there is also an elongated recess 34 through which the sockets 36 provided in the heat measuring unit 24 are accessible. Details of the heat measuring unit 24 will be described later in more detail with reference to FIGS . 2 to 5.

Contact pins 38 of a plug 40 fit into the sockets 36 , the details of which will be discussed later with reference to FIG. 6. The plug 40 is fastened to a connecting cable 42 , via which an intelligent portable reading device 44 can be connected to a heat measuring unit 24 . The electronic structure of the reading device 44 will also be described in more detail later. In Fig. 1 it can be seen that the reading device 44 a typewriter keypad 46 for inputting data, a dot matrix printer 48 for outputting reading logs, a magnetic recording device 50 for recording the measurement results for further processing in a computer and an electrically heated calibration plate 52 has heat-conducting material.

The calibration plate 52 is installed in the housing of the reading device 44 via an insulating foam tray 54 . A serving as normal heat measuring unit 56 is fixedly mounted on the calibration plate 52 via a bracket 58 . The heat measuring unit 56 is fixed in the holder 58 in the same way by a spring and secured by a lead seal, as has already been described above for the heat measuring unit 24 with reference to the holder 16 . For the heat measuring unit 56 , the temperature dependence of the frequency of a quartz crystal contained in it, which serves as the actual temperature sensor, has been precisely determined in the laboratory. The calibration plate 52 also carries a second holder 60 , in which a heat measuring unit to be calibrated can be inserted in exactly the same way as the heat measuring unit 56 in the holder 58 .

It was found that the production-related deviation of the temperature response of the frequency of a heat measuring unit from a target characteristic consists in the fact that the corresponding frequency curve is shifted in the ordinate direction parallel to the target curve. By taking a single correction value into account, a measured value of a heat measuring unit, which is subject to production-related errors, can thus easily be converted to the correct measured value. This correction value can be determined for each heat measuring unit before installation in the holder 16 using the intelligent read-out device 44 if an operating mode switch 62 is set to the "basic calibration" position. The temperature of the calibration plate 52 for this basic calibration can be set using a rotary knob 64 .

Since the heat dissipation of a radiator 66 in a room 68 under consideration not only depends on the temperature of the radiator itself but also on the outside temperature and the heat flows within the building must also be taken into account for a fair calculation, there is also a heat measurement unit 24 carried by the radiator 66 another heat measuring unit 70 is attached to the inner wall of the adjacent room and another heat measuring unit 72 is attached to the outside of a suitable building wall that is not directly exposed to the sun. These thermal units are read in determining the heat consumption in space 68, and the computer used for billing then calculated from these three readings heat consumption in space 68th It goes without saying that the heating unit 72 need only be provided once for each building or even for a group of neighboring buildings, and that heat measuring units 70 are only required in those building walls (and possibly building ceilings) which separate different apartments from one another.

As FIG. 6 shows, the plug 44 has a housing 76 which is closed by a cover 74 molded from poorly heat-conducting plastic and which is likewise injection-molded from poorly heat-conductive plastic. A projection 78 is formed on the circumferential wall of the housing 76 , in which heads 80 of the contact pins 38 with enlarged diameters and corresponding heads 82 of further contact pins 84 pointing in the opposite direction are embedded. Individual conductors 86 are connected to the contact pins 38 and 84 , which are likewise embedded in the plastic material of the housing 76 and are connected to the connecting cable 42 .

A heat transfer block 88 is accommodated in the sliding fit in the plug-in direction in the housing 76 . Its dimension in the direction of insertion is slightly larger than the dimension of the projection 78 in this direction. A recess 90 of the heat transfer block 88 engages positively over the projection 78 in the sliding fit. In the heat transfer block 88 , a heating resistor 92 is positively inserted into a countersunk bore 94 and is also connected to the connecting cable 42 via flexible conductors 96 .

In the slots 98 of the housing 76 which run in the plug-in direction and run out freely at the front, swivel bolts 100 are provided which are biased by wire springs (not shown) into the locked position shown in the drawing, in which they overlap the edges 20 and 22 of the holder 16 with their locking sections 102 . Actuating sections 104 of the swivel bolts 100 project beyond the outer surface of the housing 66 .

The heat transfer block 88 lies with its end face on the right in the drawing against the bottom section 18 of the holder 16 . With its end face located on the left in the drawing, the heat transfer block 88 lies on the bottom section 18 'of a further holder 16' , which differs from the holder 16 only in that it has no legs 14 . In the holder 16 ', a reference heat measuring unit 24' is fixed by a spring 26 ' , and the sockets 38' of the heat measuring unit 24 ' are displaceable on the contact pins 84 . The bracket 16 ' and the reference heat measuring unit 24' are biased by an elastic rubber layer 106 in the direction of insertion. In this way, when the connector 40 is placed on the holder 16, there is a good heat-conducting surface contact between the reference heat measuring unit 24 ' and the bottom section 18 of the holder 16 , against which the heat measuring unit 24 also lies flat. So that the two heat measuring units 24 and 24 ' at the same temperature.

In order to establish the temperature equality between the two heat measuring units 24 and 24 ' as quickly as possible after attaching the plug 40 to the holder 16, the heating resistor 92 is heated under the control of the intelligent reading device 44 until the temperature of the heat transfer block 88 and the holder 16' and the reference heat measurement unit 24 ' substantially corresponds to the temperature of the heat measurement unit 24 . This can easily be determined from the signals emitted by the two heat measuring units. Then the heating resistor 92 is switched off, and after a preprogrammed waiting time which is surely sufficient to set the same temperature distribution has elapsed, the reading device 44 then initiates the actual measurement. This consists in taking over the measurement result and determining the correction factor for the respective heat measuring unit 24 compared to the calibrated reference heat measuring unit 24 ' . Both values are stored on the magnetic tape recorder 50 for further processing.

After pressing the actuating sections 104 , the plug 40 can be easily removed from the heat measuring unit 24 and then pushed onto another heat measuring unit.

Fig. 2 shows details of the circuitry structure of the Wärmemeßeinheit 24 and the reader 44th

A tuning fork quartz crystal 108 , which vibrates at room temperature at 32 kHz, is cut so that a large temperature dependence of its natural frequency is obtained. The output of the quartz crystal 108 is connected to a prescaler 110 , the output of which provides a signal with a frequency of 128 Hz. With this signal, a counter 112 is applied, which consists of individual counters 112 a - is shown composed f 112 which deliver at their overflow outlets at intervals of seconds, minutes, hours, days, months and years pulses.

The circuits 110 and 112 are contained in the integrated circuits for quartz watches, which are manufactured in large numbers and are therefore available at low cost, which can be used to implement the heat measuring unit 24 according to FIG. 1.

The respective counter state in the form of two-digit BCD number is provided 112 f - to the outputs of the single counter 112 a. The outputs of the retailer 112 a - 112 f are a 48-bit sub-area 114 b of a shift register 114 is connected. In the exemplary embodiment considered here, its total length is 128 bits. Thereof is a 16 bit large sub-area 114 a from a read only memory 116 be read, which contains an identification number that is specifically associated with the considered Wärmemeßeinheit 24th Another 64-bit sub-area 114 c of the shift register 114 is used to hold variable information, e.g. B. the correction factor for the respective quartz crystal 108 , the size of the radiator associated with the measuring point and code information. The 64-bit sub-area 114 c of the shift register 114 is connected to a comparator 118 , which is connected with its second input to a read-only memory 120 containing the code information. The comparator 118 can be activated via a control line 122 from the read-out device 44 and, if the content of the read-only memory 120 matches the code content of the sub-area 114 c of the shift register 114 , the individual counters 112 a - 112 f are reset or caused to zero with appropriate training of the retailers the same to take over the assigned bits of sub-area 114 b of the shift register 114 as an output counter.

The shift register 114 is designed in such a way that it can read in and output data in parallel at the parallel data transmission terminals DP in the drawing, when a signal is applied to a parallel clock control terminal TP . This terminal is connected to the output of the single counter 112 a , which emits a pulse at intervals of 1 second.

The shift register 114 also has a serial data transmission terminal DS , via which data can be read in or out serially when a signal is applied to a serial clock control terminal TS . The latter is connected to the output of an AND gate 124 , one input of which is connected to the output of prescaler 110 and the second input of which is connected to a control line 126 leading to readout device 44 . A data line 128 connects the serial data transmission terminal DS of the shift register 114 to the reading device 44 .

The three lines 122, 126 and 128 are connected via the connecting cable 42 to an input / output register 130 , which is assigned to a microprocessor 132 . A real-time clock 134 , the reference heat measuring unit 24 ' , the magnetic tape recorder 50 and the dot matrix printer 48 are connected to this as further peripheral devices.

The real-time clock 134 has the same structure as the "thermal time clock" formed by the quartz crystal 108 , the prescaler 110 and the counter 112 , except that its quartz crystal is cut in a manner customary for quartz clocks in such a way that its working frequency is independent of temperature. If desired, the real-time clock can also have a radio receiver and can be automatically set to the official normal time at regular intervals.

The heat measurement unit 24 and the readout device 44 described above, which are loud due to the built-in battery, are used as follows:

Before the measuring unit 24 is installed in the holder 16 , it is attached to the calibration plate 52 and the quartz crystal correction factor is determined by the reading device 44 and stored on the magnetic tape recorder 50 . Then the measuring unit 24 is inserted into the holder 16 , clamped with the spring 26 , and the sealing wire 30 and the seal 28 are attached. Then the plug 40 is inserted into the measuring unit 24 , and the exact real time is entered into the shift register 114 by the reading device 44 together with the code information, the information about the size of the radiator and the quartz crystal correction factor. The comparator 118 now loaded with the same code information at both inputs now responds, and the sub-area 114 b of the shift register 114 is then adopted as the output counter reading in the counter 112 . Thereupon, the shift register 114 is overwritten by the read-out device 44 with any information not containing the code information, and the plug 40 is removed.

The heat measuring unit 24 now provides the previous heat consumption in the form of a time in the shift register 114 every second. If desired, the TP terminal of the shift register 114 can also be connected to the minute output of the individual counter 112 b .

After a heating period has elapsed, the reading device 44 is reconnected to the heat measuring unit 24 , and when a control signal is provided on the control line 126 , the content of the shift register 114 is read out serially. For security reasons, this can be done several times, in which case the reading device 44 then uses the identifier for the heat measuring unit 24 , which is taken from the read-only memory 116 , as a marker for the beginning of the content of the shift register 114 .

If the content of the shift register 114 can also be read out by the owner of the apartment, a simple display device can be made available to it, which does not contain any code information and is only capable of reading out the shift register 114 and the sub-area 114 b in the form of a Number.

A heat measuring unit 70 arranged on a wall of the room can also be used during the reading period as a temperature sensor with single-wire signal transmission by connecting the lower input terminal of the AND element 124 in the drawing to the second or minute output of the counter 112 and the line 128 with a control unit connects the room air conditioning system, which either digitally evaluates the change in the content of sub-area 114 b or determines the deviation of the read clock frequency from the exact 128 Hz clock frequency and takes it as a measure of the actual temperature in the room.

To read the heat consumption after a heating period after attaching the connector 40 from the reader 44, the content of the shift register 114 is read out and held on the magnetic tape recorder 50 , and if a reference heat measuring unit 24 'is integrated in the connector 40 , is also described in the already described The way the correction factor for the heat measuring unit 24 is newly determined and also recorded magnetically. Then the shift register 114 is filled with the real time from the reading device 44 and the status of the counter 112 is corrected accordingly, as has already been described above.

The readout device 44 then checks the data entered via the magnetic recording device 50 to determine whether all the heat measuring units in an apartment or house have been checked, and prints out the measurement results on the dot matrix printer 48 as evidence.

After reading off all the heat measuring units of a house or a group of buildings, the tape cassette described by the magnetic tape recorder 50 is removed and sent to a data center of the accounting company for the preparation of the final bill, which can easily be done by post. The recordings on the magnetic tape cassette can also be used for checking the meter reader and for wages accounting for the meter reader.

It can be seen that with this type of determination of heat consumption Tampering or unintentional errors eliminated are. The reading can also be done by inexperienced people how caretakers are made, and also finishing the measurement results are done without human intervention purely mechanical and error-free.

Fig. 3 shows a modified heat measuring unit 24 *. The shift register 114 and the low-frequency counter stages are replaced here by a random access memory (RAM) 136 , which has 2 ^N separately addressable memory cells, each one bit, and by a binary adder, which is connected between the data output terminal DO and the data input terminal DI of the read / write memory 136 is connected and in turn has an inverter 138 , a delay circuit 140 connected downstream and a clocked RS flip-flop 142 (carry flip-flop) and an exclusive OR gate 144 . The inputs of the exclusive OR gate 144 are connected to the data output terminal DO of the read / write memory 136 or the "1" output of the flip-flop 142 . Its reset input R is also connected via the delay circuit 140 and the inverter 38 to the data output terminal DO of the read / write memory 136 , its set input S is connected to the overflow terminal O of a pre-counter 146 used for cyclic addressing of the read / write memory 136 . At the input, this receives a signal with a frequency of approximately 128 Hz, which is derived from a 256 Hz signal by an intermediate divider 148 with a partial factor two, which is provided by a prescaler 150 . The latter is connected to the output of a tuning fork quartz crystal 152 , which is again cut so that its natural frequency changes greatly with temperature.

The output signal of the prescaler 150 is fed directly to the read-in clock terminal TI and, via an inverter 154, to the read-out clock terminal TO of the read-write memory 136 .

A data output line 156 is connected to the data output terminal DO of the read / write memory 136 . A data read-in line 158 is connected to an input terminal of an AND gate 160 , the second input terminal of which is connected to a read-in control line 162 . The output of the AND gate 160 is connected to the data input terminal DI of the read / write memory 136 via an OR gate 164 . Its second input terminal is connected to the output of an AND gate 166 , one input of which is also connected via an inverter 168 to the read-in control line 162 and the other input of which is connected to the output of the exclusive OR gate 144 . The signal on the read-in control line 162 is also used to reset the dividers 148, 150 and the pre-counter 146 via a fast monostable multivibrator 167 .

The measuring unit 24 * described above works as follows:
The various memory cells of the read / write memory 136 (given the frequency ratios in practice 128 above) are cyclically addressed once in one second (“warming time”). Each address signal is present for 1/128 seconds. Every second is set by an overflow pulse from the pre-counter 146 of the flip-flop 142 . The exclusive OR gate 144 now converts all incoming binary ones into binary zeros, and the first incoming binary zero is converted into a one. The data converted in this way are read back into the read / write memory 136 via the data input terminal DI . All subsequent bits provided at the data output terminal DO are read in unchanged via the exclusive OR gate 144 again via the data input terminal DI of the read / write memory 136 . In this way, periodic reading of the heat consumption ("warming time") and addition of second pulses for the purpose of integrating the heat consumption takes place simultaneously. This combination of interface function and counting function in the read / write memory 136 obviously gives the circuit a particularly simple structure.

Protection against manipulation can be obtained in the embodiment according to FIG. 3 by covering the socket for the read-in control power 162 by the holder 16 and by carrying out the annual consumption determination taking into account the reading of the last period. A first read-in of the read / write memory 136 is only necessary after replacing the battery, for which purpose the seal 28 of the holder 16 has to be destroyed anyway and the heat measuring unit 24 * of the holder 16 has to be removed.

If additional information about the correction factor of the quartz crystal 152 and / or the size of the radiator assigned to the measuring unit and / or code information is to be stored in the read / write memory 136 and is then automatically output cyclically together with the heat consumption, the circuit can be used as 4 shown in FIG . Circuit parts already discussed with reference to FIG. 3 are again provided with the same reference numerals and do not need to be explained again in detail.

The prescaler 150 , the intermediate divider 148 and the pre-counter 46 are shown summarized as a pre-counter 170 , the first output terminal of which is used for specifying the reading or reading in of the read / write memory 136 , the second output terminal of which is used for clocking the flip-flop 142 , the subsequent one Output terminals (in practice at the frequency ratios 8 described above) are used to address the read / write memory 136 and the last output terminal is used to reset the counter 170 when reading the heat consumption, while the penultimate output terminal is used to reset the counter 170 in normal measuring operation becomes.

For this purpose, the latter two output terminals are connected to first inputs of AND gates 172, 174 , the outputs of which are combined via an OR gate 176 . Its output is combined via a further OR gate 178 with the signal on the read-in control line 162 ; the output of the OR gate 178 is connected to the input of the monostable multivibrator 167 .

The read / write memory 136 has 2 ^{N +1} memory cells, of which, however, only 2 ^N are used, as in the exemplary embodiment according to FIG. 3, for storing the "heat time" that characterizes the heat consumption. The second, upper half of the read / write memory 136 contains the information about the correction factor, radiator size and code information. If there is no signal on the read-in control line 162 , the upper half of the memory is not addressed at all and the circuit operates in the same way as the circuit according to FIG. 3. If a read-in control signal is present, the memory cells in the upper half of the memory are also addressed and their content is opened the data output line 156 together with the content of the lower half of the memory. The read-out data can be processed further in the read-out device 44 and either returned unchanged (update of the consumption measurement, no redetermination of the correction factor) to the read / write memory 136 , as indicated by the loop 180 in the read-out device 44 , or the read-out device 44 fills the read / write memory new, whereby the "warming time" is brought into line with the real time and / or a new quartz crystal correction factor is entered.

In the exemplary embodiment according to FIG. 4, the lower half of the read / write memory 136 contains the information about the heat consumption, the upper half of the read / write memory 136 contains code information, the quartz crystal correction factor and information about the radiator size, etc. In order to manipulate the content of the write / read random access memory 136 further impede, one may in the embodiment of Fig. 5, the additional information and the information about the heat consumption in unit of heat to different thermal unit arbitrarily distributed manner on any memory cells of the read / write memory 136.

For this purpose, the heat measuring unit 24 *** shown in FIG. 5 has a read-only memory 182 which, like the read / write memory 136, contains individually addressable memory cells for one bit and is addressed with the same signals from the pre-counter 170 . A binary one in a memory cell of the read-only memory 182 stands for the fact that the corresponding memory cell of the read / write memory 136 contains information about the heat consumption to be processed arithmetically, a binary zero for that the corresponding memory cell of the read / write memory 136 contains additional information, which at the update of the heat consumption must not be processed arithmetically.

The data output terminal DO of the read-only memory 182 is connected to an input terminal of an AND gate 184 , the other input terminal of which is connected to the output of the inverter 138 and the output terminal of which is connected to the input of the delay circuit 140 . This ensures that only those binary zeros output by the data output DO of the read / write memory 136 can reset the flip-flop 142 , which belong to arithmetically processed bits of the part of the content of the read / write memory 136 which characterizes the heat consumption.

The data output DO of the read-only memory 182 is also connected to the input of a further AND gate 186 , which is connected at the other input to the 256 Hz output terminal of the counter 170 and which is connected at the output to the read-in clock control terminal TI of the read / write memory 136 . Thus, during the periodic addressing of the read / write memory 136 , such memory cells are protected against overwriting, which contain additional information, since when these memory cells are addressed, a binary zero is output at the output of the read-only memory 182 .

The read-only memory 182 is an electrically programmable read-only memory (EPROM) and is read in differently in the factory for the different heat measuring units. The corresponding information is only stored in the accounting company's computer; it cannot be determined from the heat measuring unit, in which all parts with the exception of the battery are encapsulated with the housing, nor when reading out the heat measuring unit with a reading device, since it is then not possible to see the different bits read out serially, whether they contain additional information or a part represent the digital number indicating heat consumption. In this way, manipulation of the measurement results in a targeted manner is not possible.

Claims (16)

1.Device for measuring heat consumption, in particular for use in a heating system, with a measuring unit which can be thermally coupled to a heat-emitting part and which has a temperature sensor operating at a temperature-dependent frequency and a counter acted upon by its output signal, the counter having a read / write memory which can be read out in series is assigned, which has a greater capacity than is necessary for storing the counter reading of the counter in order to record additional information, characterized in that the read / write memory ( 114; 136 ) can be connected via a plug connection ( 40 ) to a reading device ( 44 ) which comprises means ( 50 ) for recording the content of the read / write memory ( 114; 136 ) on a data carrier. 2. Device according to claim 1, characterized in that the recording device ( 50 ) is a magnetic recording device. 3. Apparatus according to claim 1 or 2, characterized in that the reading device ( 44 ) has a computer ( 132 ) and a data carrier ( 50 ) for a computer program. 4. Device according to one of claims 1 to 3, characterized in that the reading device ( 44 ) has a keypad ( 46 ) for entering data. 5. Device according to one of claims 1 to 4, characterized in that the reading device ( 44 ) has a heatable calibration plate ( 52 ) on which a calibrated measuring unit ( 56 ) is attached and on which a measuring unit to be calibrated ( 24 ) can be attached . 6. Device according to one of claims 1 to 5, characterized in that in the connection for connecting the readout device ( 24 ) with a measuring unit ( 24 ) serving plug ( 40 ) a reference measuring unit ( 24 ' ) is integrated, which when connecting the Plug ( 40 ) is brought to a measuring unit ( 24 ) in heat-conducting contact with the measuring unit ( 24 ) to be read. 7. The device according to claim 6, characterized in that the reference measuring unit ( 24 ' ) in the plug-in direction is accommodated in the plug ( 40 ) and is biased by a spring ( 106 ) in the direction of the free plug end. 8. Apparatus according to claim 6 or 7, characterized in that at least the reference measuring unit ( 24 ' ) containing part of the housing ( 74, 76 ) of the plug ( 40 ) is made of poorly heat-conducting material. 9. The device according to claim 8, characterized in that the plug ( 40 ) has spring-loaded claws ( 102 ) with which it can be locked on the measuring unit ( 24 ) to be read or its holder ( 16 ). 10. The device according to one of claims 6 to 9, characterized by a transmission block ( 88 ) made of a good heat-conducting material, which has a recess ( 90 ) in which the contact pins ( 38, 84 ) for the measuring unit ( 24 ) to be read and the Reference measuring unit ( 24 ' ) carrying plug section ( 78 ) is accommodated in the sliding fit, and which has a slightly larger dimension in the plug-in direction than this plug section ( 78 ). 11. The device according to claim 10, characterized in that a heating resistor ( 92 ) is installed in the transmission block ( 88 ). 12. The device according to one of claims 1 to 11, characterized in that the reading device ( 44 ) has a timer ( 134 ), preferably a real-time clock. 13. The apparatus according to claim 12, characterized in that the timepiece is formed by a standard measuring unit ( 24 ) in which the quartz crystal ( 152 ) operating at a temperature-dependent frequency is replaced by a quartz crystal operating at a temperature-dependent frequency. 14. Use of a device according to one of claims 1 to 13 as a temperature sensor cooperating with the control unit of a heating system or air conditioning system, characterized in that a data output terminal ( 156 ) of the measuring unit ( 24 ) on which pulses continuously derived from the output signal of the quartz crystal ( 152 ) are provided, is connected to an input terminal of the control unit and the control unit has a frequency meter or a computing circuit which together evaluates successive pulses representing a binary number, and that the output signal of the frequency meter or the computing circuit is used to control the heating or cooling capacity . 15. Method of measuring heat consumption in heated Broaching using a device after a of claims 1 to 13, characterized in that Quartz crystals with only about the target temperature response the frequency corresponding temperature response used and the deviation of the temperature response correction factor characterizing the target temperature response into the additional memory cells of the Read / write memory is entered.   16. Method of measuring heat consumption in heated Clear and use multiple fixtures one of claims 1 to 13, characterized in that that at least one measuring unit on the inside of a Building wall and / or at least one measuring unit on the Outside of a building wall is arranged and that in additional memory cells of the read / write memory of this Measuring units Information to identify the different Measuring points is stored.