DE3322452A1 - Device for direct measurement of thermal energy - Google Patents

Abstract

The invention relates to an electronic device having a microprocessor for measuring thermal energy in air-conditioning devices, by means of which the main parameters of the device can be displayed and transmitted in code. The device consists of an electronic module for processing, integrating counting, digital representation and remote data transmission in coded form, two temperature sensors, specifically a feed temperature sensor and a return temperature sensor, and a volume sensor which is provided with a volume pulse generator. The electronic module processes the data recorded by the temperature/volumetric flow sensors and generates digital signals which are displayed, if required, by means of a key. Displayed in particular are a program volume code, a program calorimetry code, the feed temperature, the temperature difference, the return temperature, the volumetric output and the thermal load, together with the integration of the thermal energy.

Description

Device for direct measurement of thermal energy

The invention relates to a device for direct continuous measurement of the thermal energy by means of of a fluid is transferred to an exchanger for heating or cooling rooms, and for storage and remote transmission of the main parameters of the device.

Devices for direct measurement of thermal energy are known which use signals proportional the temperature difference between two points in the fluid line and provide for the volume of the flow rate.

They are also improved electronic devices known that an electronic computing and integration module have, as the device described in Italian patent application 24091 A / 81, which has a greater reliability of the measurement carried out and continuous control of the accuracy of the Ensure measurement.

The invention is based on the object of creating a device which makes it possible at any point in time to get instant information about the thermal parameters of the device and also to them remotely transmitted to a connected receiving station can.

This object is achieved according to the invention in a device according to the preamble of the claim by the features specified in the characterizing part of claim 1. Appropriate configurations of the invention result from the subclaims.

The invention is explained below with reference to FIGS. 1 to 4, for example. Show it:

Figure 1 is a block diagram of the device, Figure 2 is a complete electrical circuit diagram.

FIG. 3 shows a connection diagram of the resistors and forming the temperature sensors

FIG. 4 shows the circuit for measuring the resistances.

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As Fig. 1 shows, the device has a processing module 1, .The contains a microprocessor which is fed by a network 2 and to which the signals of a Supply temperature sensor 3, a return temperature sensor 4 and a volume sensor 5 arrive.

The processing module 1 sends signals to a volume meter 6, an energy meter 7 and depending on a selection key 8 to a digital display 9. The processing module is also via a bus 10 connected to further remote data transmission facilities.

With 11 to 15 programming data of the microprocessor are designated, specifically each pulse of the Volume 11 corresponding to the volume sensor, the conversion factor 12 of the thermal quantities, the selected thermal unit 13, the values 14 of the volume heat coefficient K and the unit of volume 15.

As shown in FIG. 2, the microprocessor 16 generates a clock signal 17 which controls an A / D converter 18.

The converter 18 receives successively from a multiplexer 19 signals which the values of resistors up to 2 3 determined.

The resistors 20 and 21 form the forward and reverse temperature sensors, respectively 3 and 4, the resistor 22 is a comparison resistor and the resistor 23 is a zero reference resistance. The converter 18 converts the received signals into pulses as a function of the received clock signal of different lengths and sends them to the micropro-

processor 16, which also sends the signals to a pulse generator connected volume sensor 5 arrive. The generated values are then shown on the display 9, and the throughput volume and the consumed Energy is transmitted to meters 6 and 7, via a transmitter 24, this data can also be routed in BCD code to other receiving elements to centrally reading, printing and / or forwarding by means of a telephone line via a suitable interface to enable any distance of all measured and counted quantities (energy, volume). The transferred Thermal energy, the flow rate and the volume heat coefficient K are corresponding to the previous Italian Defined patent application 2 4091 A / 81.

Provision has been made in the processor's program that for each value T. and T ~ the mean coefficient is numerical K is introduced according to a predetermined table. In this way, the determined energy quantity corresponds the effective operating conditions of the device.

The temperature measuring device relates to a single resistor of known and constant magnitude. The analog sampler and multiplexer 19 determines at the input one after the _{other: R, the resistance of the flow probe 3, R 2} , the resistance of the return sensor 4, R, the comparison resistance 22 and R, the zero resistance 23 to ground.

The measurement of these resistances is carried out in sequence and to the single A / D converter 18 and then to dynamic memory of the processor.

The transition from the analog value to the digital value is subject no influence as a result of a change in the voltage, the components, the clock frequency of the processor, etc., because

the value of R is the value at the time of measurement, which is used as a reference dimension.

This measurement is carried out simultaneously and under the same conditions as those of the other values R and R n, so that an automatic correction of the measured values is achieved. In addition, the resistances of the connection lines of the probes are also taken into account during the measurement. The probes are connected in accordance with the circuit diagram of FIG. 3, in that the resistance 20 or R, which corresponds to the measuring element 3 of the flow temperature T, is measured between the connections 25 and 26, and the resistance. 21 or R ₂ , which corresponds to the measuring element 4 of the return temperature T ~, is measured between the connections 27 and 28. Thus, along the measuring line of T, there are twice the resistors 29 and 30, which together correspond to the resistance of the connecting lines of the heat-sensitive elements of the device.

The same applies along the line from T ₂ . If you designate resistor 29 with RFV and resistor 30 with RFR, you get:

R ^ ₁ = R ₁ + 2 RFV + 2 RFR and R ' ₂ = R ₂ + 2 RFV + 2 RFR.

The circuit diagram in FIG. 4 shows the type of connection of the circuit shown to the multiplexer 19.

The computer program can now determine the effective value of R, and R ₂ by obtaining a coefficient o (which is represented by "

o (= - ^ t-. C
r

is given, where R is the initial value of the resistance, R ^{1 is} the value of the resistor 22 for each measurement and C is a fixed value which is a function of and Rp _R.

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The value of R. and R ₂ is obtained from:

R ₂ = o (. R ' ₂

where R 'and R' _{2 are} the values measured simultaneously with R ^1.

The program also provides for the conversion of R, and R ₂ into T ₁ and Tp, if one takes into account the non-linearity of the platinum used in the probe (e.g. PT 500 Ohm / 0 ° C).

The difference found is therefore

Δ φ _ ΓΠ _ φ
1 -2

The values T, T ₂ and Δ T are transferred in the memory of the processor.

Depending on the measured temperature values, a stored law of correspondence is then used a mean value in a suitable interval of the volume heat coefficient K is chosen (see publication 846/74 by Dr. Hans Magdeburg PTB Berlin), which is related to the volume measurement in the embodiment shown that is in the return line of the heat vector fluid is carried out.

The stored volume impulses are multiplied by the corresponding determined values of ΔT and K. The result is transferred to a storage register which, if the quantity, corresponds to a programmed unit of measurement corresponds, is reached, a pulse to the energy meter sends.

Accordingly, the volume pulses become a volume storage register broadcast that if the selected

Volume unit is reached, a pulse to the volume counter sends.

The individually determined values T, T ₂ and A ^T can be called up in digital form.

The values of the hourly output and the instantaneous output can be separated on the basis of the recorded and available data are determined in order to represent them as required using a predetermined time base.

The data T ₁ , T 2, AT, the hourly output and the instantaneous output can, as mentioned above, be converted into the BCD code.

The transmission lines are galvanically isolated from the processing module by means of a phototransistor to avoid any possible To transmit disturbances on the line. If you have a constant time base at a suitable frequency for the Would like to have measurements, such as when using mains voltage with a frequency of 50 Hz If the frequency of the fall is different, the device can be equipped with an additional oscillator, e.g. provided we

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Claims (1)

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MILAN (Italy) Device for direct measurement of thermal energy Claims before XJ Device for the direct measurement of thermal energy, which is transmitted by a fluid in an air-conditioning device, consisting of a microprocessor, flow and return temperature sensors and a volume sensor equipped with a unit volume pulse generator, characterized in that the microprocessor processes the measured values that Integrated consumption data and processing, transmitting and displaying the operating data of the facility on request on a digital display. 2. Device according to claim 1, characterized in that that the reproduced data the program volume code, the program calorimetry code, the flow temperature, the temperature difference, the return temperature, the. Volume output and the corresponding instantaneous thermal load are. 3. Apparatus according to claim 1, characterized in that the operating data of the device in the BCD code are transmitted remotely to the central with an interface Reading, printing and retransmission by means of a telephone line of the measured and integrated quantities to enable. 4. Device according to one or more of claims 1 to 3, characterized by a flow temperature sensor (3), which is arranged in the fluid supply line is, a return temperature sensor or (4), which is arranged in the fluid return line, a volume sensor (5) which is arranged in the fluid return line, and one to the volume sensor connected pulse generator to always then to generate an electrical impulse when a certain return flow medium volume is exceeded, wherein the temperature sensors and the pulse generator of the volume sensor to an electronic module for Processing and display of the heating parameters of the air conditioning system are connected. 5. Device according to one or more of claims 1 to 4, characterized in that the temperature probes (3, 4) consist of resistors (20, 21) and a switch or multiplexer (19) with a certain Sampling time are scanned, with successive measurement of a resistor (22) known and constant size is carried out as a size reference measure and then for controlling the zero value, and wherein furthermore these values are converted into corresponding values of temperature and heat differential, the length of the Connection lines of the sensors and the non-linearity compensate for the response behavior of the sensors used and to a logic interface circuit and from this to the memories in accordance with a basic cycle of the microprocessor. 6. Device according to one or more of claims 1 to 5, characterized in that the pulses of the Volume sensor to a logical interface circuit and from this according to a basic cycle to the memory of the microprocessor. 7. The device according to one or more of claims 1 to 6, characterized in that the stored pulses of the volume sensor are multiplied by the corresponding value of the temperature difference and the volume heat coefficient, which is determined according to the measured temperatures, and that the
Result is transferred to a storage register,
which sends successive switching impulses to an energy meter according to the programmed unit of measurement. 8. Device according to one or more of claims 1 to 7, characterized in that the stored pulses from the volume sensor are sent to a storage register are transmitted, the "successive switching impulses to the volume counter according to the programmed unit of measurement sends. 9. Device according to one or more of claims 1 to 8, characterized in that the values of the
Flow and return temperature, the heat difference, the hourly output and the current output individually ! processed on the basis of the measurements carried out ^ and can be called up as required by means of a dial button to digitally center a certain Time base; s to be displayed. 1.0. Device according to one or more of claims 1 to 9, characterized in that the volume heat coefficient corresponds to each flow and return temperature pair is determined based on a stored table. 11 "Von j_cn do g according to one or more of Claims 1 to 10, characterized in that the remote transmission line for the counter pulses from the device
is galvanically isolated. Device according to one or more of Claims 1 to 11, characterized in that the electronic Part is contained in the cover of the housing receiving it and can be removed by pulling out a connector without removing the electrical connection terminal block. 13. Device according to one or more of claims 1 to 12, characterized by internal accumulators, which ensure operation even in the event of a temporary interruption in the mains voltage :. 14. Device according to one or more of claims 1 to 13, characterized by an additional circuit of constant frequency, which is used for measuring the hourly output and ensures a time base for the current power regardless of the network frequency.