DE2736825A1 - Measurement system for consumed heat - determines temp. difference values of heating medium and applies them to summating counter which adds results - Google Patents

Abstract

The system comprises a meter, and the flow and temperature difference are measured between the heating medium inlet and outlet. Measurement results are multiplied with each other, taking into account the temperature coefficient. Temperature is measured by a sensor consisting of a linearised thermistor network, whose resistance-temperature characteristic and reproducibility are highly accurate, as in 2710782. The temperature difference values are applied in digital form to a summating meter, which adds them until a certain digital value - the detection number Z - is reached, when the mechanical meter for the consumed heat is moved forwardly by one step.

Description

Heat meter with digital temperature measurement

(Addition to P 27 10 782.0) The invention relates to a device to determine the amount of heat consumed by means of a counter, with between Flow and return of the heat-emitting medium, its flow rate and temperature difference are measured and these measurement results taking into account the heat coefficient are multiplied together, on the basis of a temperature meter, which is called Encoder linearized thermistor networks are used, the resistance of which is temperature-dependent and reproducibility are highly accurate, according to patent no. ......

(P 27 10 782.0).

Heat meters are known in numerous embodiments. So For example, the German Auslegeschrift 1 157 811 discloses a heat meter with a switching element arranged in a measuring chamber, its open contacts parallel to the setting resistors and when the temperature rises in short-circuit the resistance of the measuring chamber above a certain value.

Another embodiment is disclosed in the German Offenlegungsschrift 1 801 554 disclosed, in which a heat meter with each on the heat-emitting Surface-mounted temperature-dependent resistors through which the current flows whose size is a measure of the amount of heat given off is provided. the Values go into a counter and are evaluated, the temperature-dependent Resistors each at a voltage assigned to the size of the heat-emitting area lie. This is to create a heat meter that is independent of the size of the heat-emitting surface, always the same temperature-dependent resistances can be used. The expense of all of these facilities in terms of electronic Components, assembly and maintenance is way too big. You can also use these counters only ever use for certain flow rates.

The present invention is based on the object of a device to create, which not only largely eliminates the aforementioned disadvantages, but also an adaptation to a large flow rate range - in particular for small flow rates - can be achieved.

This object is achieved in that the temperature difference in supplied in digital form from the temperature difference measuring circuit to a totalizer which records the value of the temperature difference and for as long as the temperature difference values be added up until a certain digital value - the detection number Z - reaches and thus the mechanical display counter for displaying the amount of heat consumed around is taken one step further.

The solution has the advantage, with the same and equivalent task fulfillment to require a lower cost of components and thus also a frequency of errors to be reduced considerably. This again leads to a substantial increase in the Operational safety.

Further features of the invention, in particular the design of the Arrangement are laid down and explained in the claims and in the description. The single figure of the drawing shows a block diagram of the exemplary embodiment described.

The method of the device according to the invention is based on the following functional equation: (1) WM = TVK DMJI Here, WM = amount of heat consumed in MJ V = flow rate in m31 K = thermal coefficient of the liquid in T = temperature difference between supply and return in LK.

A flow meter is used to measure the flow rate V, whose flow indicator mechanism runs in the dry and that in the liquid running fluid mechanical part by means of magnetic coupling, consisting of two permanent magnets. The flow meter is now modified so that that the flow display mechanism now available either by a combination, consisting of a Permanent magnets and one relative to this permanent magnet suitably arranged reed contact, or only by a suitable one above the one in the wet running permanent magnet mounted reed contact is replaced.

In the first case, the permanent magnet of this combination is mounted in such a way that that it is driven by the part running in the wet and driven by the fluid mechanical part Permanent magnet runs synchronously via the mutual magnetic force line field and periodically opens and closes the nearby reed contact.

In the second case, the flow meter is converted so that the now existing flow display mechanism only by a suitably arranged Reed contact is replaced. This reed contact is mounted so that the magnetic field the permanent magnet, which runs in the wet and is driven by the fluid mechanical part periodically the reed contact opens and closes.

The reed contact is connected to the input of the electrical measuring circuit connected, in which with n closings and openings of the reed contact n electrical Pulses are generated bounce-free. A possible bouncing of the reed contact would have an oscillation of the electrical pulse edges result. This will oscillate by using an integrating R-C element to generate the electrical Impulses prevented.

The number n of electrical input pulses generated in this way increases proportional with increasing flow rate. Is the scaling factor of the modified Flow meter a [m3 / Impulsi, one obtains the according to the number n of the generated electrical input pulses, the amount of water flowing through to V = a n Cm The from the modified flow meter via the reed contact and a integrating R-C element generated input pulses now clock n times the electrical Measuring circuit.

This electrical measuring circuit consists of a divider with the division factor u, a measuring circuit for the temperature difference of before and Return, a totalizer for the product formation of T V (see equation (1) ) and a control circuit for the mechanical counter that measures the amount of heat consumed indicates.

The electrical measuring circuit works as follows: The from Flow meters described above generated electrical input pulses the number n are converted into a number via the divider according to the divider factor u m = n Au m = u output pulses converted; i.e. m output pulses correspond to one The amount of water flowing through, V = a u m cjl, per divider output pulse therefore flowed an amount of water of V = a u [m3] through the flow meter; i.e. about the Switching the division factor u is a range switching for the flow rate measurement given. If you now start the temperature difference measuring circuit with each of the m output pulses of the divider, where you get the measurement result as a count of an up / down counter, so as digital value, D = Tb, with the scaling factor b in K / digitd, so needs one only uses the D-values obtained after each of the m divider output pulses in an up-counter, the so-called totalizer, to add up according to the functional equation (1) a digital value for the product T V V = - D b a u m in [m3. OK to receive. The D-values are added up in the totalizer by counting down the Up / down counter of the temperature measuring circuit and simultaneous up counting of the totalizer until the up / down counter reaches the counter reading Has reached zero.

The amount of heat consumed WM results from what has been described above the following new calculation equation (2): (2) WM = m a u D b K [MJ] with: a = scaling factor of the modified flow meter in [m3 / pulse] u = Divider factor m = number of divider output pulses in [Impulseq b = scaling factor of the digital temperature measurement in fK / digit D = digital value of the temperature difference measurement in [Digitsd K = heat coefficient of the liquid in rMJ / (mJ. ° K)] One uses now a mechanical counter as a display for the amount of heat consumed, which always when a certain amount of heat, a WM, has been consumed, clocked one step further is, you can get a certain count of the totalizer, a certain digital number, the so-called detection number Z, calculate at which the mechanical The display counter for the amount of heat consumed can be clocked one step further got to. This detection number Z is calculated according to Eq. (2) as follows: 3 Z = m. D = aWM a.bu.K If the counter reading of the totalizer is reached when adding up the digital Temperature difference value D the detection number Z, then not only, as described above, the mechanical display counter for the amount of heat consumed is incremented by one, but also the excess digital amount as an initial value for the following Additions are transferred to the totalizer without any bit loss. The excessive one digital amount is not lost; rather, it will add up the next time considered.

The division factor u is as small as possible under the aspect of Power consumption selected. The biggest consumers of electricity are the analog part of the digital temperature measuring circuit and the associated crystal oscillator. Therefore, at the nominal flow rate Vnenn, the analog part of the temperature measuring circuit should be used as well as the crystal oscillator circuit only at time intervals, At, switched on and after the running-in and measuring times must be switched off again.

According to the equation, anenn t V = au, we get nenn nom the division factor u: The detection number Z is calculated according to equation (3).

The possibility to switch the division factor u allows the adaptation of the heat meter according to the invention to larger, but also to very small flow rates without having to change the fixed detection number.

The divider also has the option of using the "input for division factor correction "the division factor u corresponding to that in the temperature difference measuring circuit Incidentally received digital value for the return temperature to be corrected so that with very precise heat quantity measurements also the temperature-density dependency of the Flow medium can be taken into account.

The power consumption is extremely low, and the facility can at least can be kept in operation for a whole year on one battery charge.

Patent claims: L e r s e i t e

Claims (9)

Device for determining the amount of heat consumed by means of a counter, with between the flow and return of the heat-emitting Medium whose flow rate and temperature difference are measured and this Measurement results are multiplied with one another, taking into account the thermal coefficient on the basis of a temperature meter, the linearized thermistor networks as a transmitter used, their resistance temperature dependence and reproducibility with high precision are, according to patent no. . 0. . . . . (P 27 10 782.0), thus g e k e n n n z e i c h n e t that the temperature difference in digital form from the temperature difference measuring circuit is fed to a totalizer that records the value of the temperature difference, and as long as the temperature difference values are added up until a certain one digital value - the detection number Z - is reached and thus the mechanical display counter for the display of the amount of heat consumed advanced by one step will. 2. Device according to claim 1, characterized in that g e k e n n z e i c h -n e t that the electrical measuring circuit, consisting of a divider, a measuring circuit for the temperature difference between the flow and return of the medium, a totalizer and a control circuit for the mechanical display counter, an integrating one RC element is assigned. 3. Device according to claims 1 and 2, characterized g e k e n n -z e i c h n e t that the one used for the realization of various division factors Counter can be set according to the desired division factors. 4. Device according to one or more of claims 1 to 3, characterized it is noted that the voltage supply is the digital temperature difference measuring circuit by the pulses generated at the output of the divider is switched on and after decay the settling and measuring time is switched off again. 5. Device according to claims 1 to 4, characterized g e k e n n -z e i c h n e t that the display mechanism for the flow rate from a permanent magnet and a reed contact. 6. Device according to claims 1 and 3, characterized g e k e n n -z E i c h n e t that the permanent magnet of the flow indicator mechanism differs from the one in the wet running permanent magnet driven by the fluid mechanics part via the mutual magnetic force field runs synchronously and thereby the reed contact periodically opens and closes. 7. Device according to claims 1 to 4, characterized g e k e n n -z e i c h n e t that the reed contact with the input of an electrical measuring circuit connected is. 8. Device according to claims 1 to 7, characterized g e k e n n -z e i c h n e t that the fluid mechanical part coupled with the fluid mechanical part running in the medium Permanent magnet, via its magnetic field, directly touches the dry reed contact periodically opens and closes. 9. Device according to one or more of claims 1 to 8, characterized it is not indicated that the flow-mechanical part running in the medium by means of two permanent magnets as a magnetic coupling, the flow rate display mechanism, which is running in the drying process drives.