DE2917711A1 - TIMER HEAT MEASUREMENT SYSTEM FOR MEASURING AND CALCULATING EVALUATIONABLE HEAT - Google Patents

Description

PATENT ADVOCATE DIPL.-ΙΝΘ. J. MEINKE

46OO DORTMUND 1, April 30, 1979 WESTENHELLWEQ 67 M / W

TELEPHONE CO2313 14581O

TELEBRAM DOPAT Dortmund TELEX 8227328 pat d

FILE NO .:

Applicant: KOMA S.p.A., Via Roma, 6, Longarone / Italy

description

"Time heat measuring system for measuring and calculating of evaluable heat "

909846/0678

The invention relates to a time heat measurement system for measuring and calculating evaluable heat for the purpose of dividing the costs of heating for the individual Apartment consumers in a shared property building.

One of the biggest problems with any joint ownership building is the fair and correct distribution of the Cost of running a central heating system among users. It is known that in practice all heat calculation systems that have been used so far are only able to alleviate the existing problem. The thermostat / hour measuring system is completely unsuitable for inequalities with regard to the different Consumers installed heating surfaces to include the favorable or unfavorable influences of ventilation and radiation to take into account, or the location of various users in the overall context, so that the recorded Heat amounts do not reflect the actual share of consumption in the common heating system.

The system that uses calorie counters to measure flow rates and temperature differentials between the inflow and measures outflow to each individual consumer on the one hand correctly the calories flowing through the normal distribution system to the individual consumer, on the other hand, however, completely neglects the indirect addition of calories by neighboring, above and below located areas and also the advantages or

909848/0678

Disadvantages of the various consumers with regard to direct sunlight or others outside Phenomena.

The object of the invention is to create a solution which makes it possible in a single and unquestionable way valid measuring process for all consumers the measurement of the amount of heat used by each individual consumer integrate regardless of the fact that these amounts of heat come directly from the distribution system or from others different systems that are an integral or external part of the consumer network.

To solve this problem, a time heat measuring system is used to measure and calculate the heat that can be evaluated for the division proposed the cost of heating to the individual consumer, which according to the invention indicates that at least one internal temperature sensor, a comparator, a mathematical multiplier and a meter for each apartment and at least one timer and one external temperature sensor are provided are, the inner temperature sensor and the outer temperature sensor for each apartment assigned to the comparators take in input signals and output an output signal, the latter as a function of the difference between the external temperature and the internal temperature of each apartment, the output signal being the mathematical Multiplier applied, which is operatively connected to the time counter to thereby act as the output signal of the

909846/0678

(ρ

Multiplier is the product between the output signals of the time counter and the output signals of the comparator to obtain, wherein the counter measuring device is provided for calculating the output signal from the multiplier.

Further features, details and advantages of the invention are detailed below, for example with reference to the drawing explains which a circuit diagram of the Zeitwärmemeß-System reproduces according to the invention.

The heat generation and distribution system shown in the drawing has a heat source 1, a burner 2, a mixing valve 3, a circulation pump 4, a feed circuit 11 and a Rückflußkrexslauf 12, between which radiators 5 are arranged. The system is used to Heat supply to internal spaces TA, TAl, TA2, etc. The total heat that is supplied to the rooms TA to a desired Obtaining ambient temperature is mathematically related to the dispersion coefficient of the Building construction 21, which isolates the internal spaces TA from the external environment TE and to the temperature differential ST, which exists between the temperature of the internal spaces TA and the temperature of the external environment TE. The insulating structure 21 has a conductivity coefficient, which can be regarded as constant, so that the inner spaces TA to achieve the desired Temperature supplied heat in exact mathematical

909846/0678

relationship to the temperature difference between TA and TE. It is therefore evident that it is used for calculation the amount of heat that is directly or indirectly consumed by the various consumers is sufficient for For each consumer connected to a specific central heating system, the heat difference between the ambient temperature TA, TAl, TA2, TA3, etc., measured individually by the various consumers and the external ones Temperature TE, measured at a point that is valid for all consumers, to be measured during the individual measurement St is fed to a time calculation device. For example, below is a possible practical solution the problem of calculating the amount of heat consumed by each individual consumer is described:

An internal temperature sensor 31 measures the temperature in the Space TA and converts this into an arbitrary value labeled P1, which is labeled with a schematically labeled 4l Comparator is connected.

With the other end of the comparator 41 is an outer one Temperature sensor 32 connected, which measures the temperature of the outside environment TE and in an arbitrary with P2 converts the designated value (but of the same type and influence as Pl). The difference between the two Values Pl and P2 are denoted by St, which in turn are reversely identified as the multiplication ratio that can range from zero (if Pl and P2 have the same value), up to a maximum (if a

909846/0678

maximum difference between P1 and P2 exists). This difference St between the values Pl and P2 is in one mathematical, schematically reproduced multiplier 51 identified. A time counter 61 of suitable type with absolutely regular behavior marks the time and outputs it as an output value 62 (valid for the calculation towards all consumers connected to the same system). This output value 61 is multiplied by the multiplier 51 of each individual consumer and included on an individual counter 71 for each individual consumer, whereby the task is solved, the actual consumption on each individual meter to calculate in relation to the amounts calculated by the individual meters of all other consumers will. To split the costs, the consumption calculated individually by the meter must match the actual Apartment space contents of each individual consumer can be multiplied to get a single resulting value obtain. The sum of the total heating costs for the entire building divided by the sum of the individual resulting values and multiplied by the respective individual resulting value results in the exact amount, which is to be paid by every consumer.

EXAMPLE

In a building with three apartments Al, _A2 and A, was the entire volume of the three apartments, ie the sum of the solid content of the individual apartments, the numerical

909846/0678

Assigned value 1000. The space conditions of each apartment in relation to this value, i.e. the thousandths of each apartment are as follows:

A ₁ : 320, A ₂ ; 38O and A,: 300.

There was an internal temperature sensor in each apartment, a comparator, a multiplier and a counter of conventional type are arranged to receive the internal temperature. An external temperature sensor and a time counter of the usual type were provided for the entire building to measure the outside temperature to record. The time interval counter was set up in such a way as to generate predetermined usual frequency pulses submit.

In each apartment, the pulses emitted by the time interval counter were multiplied by the multiplier, with the numerical value that corresponds to the temperature difference output by the comparator and the product of this multiplication was calculated or recorded by the numerator. the Instruments were set in such a way that at a temperature difference of 60 ° C the counter had a counting unit for every 7 minute interval counted.

During a predetermined period of time, the counters of the three apartments showed the following total number of units of time at :

A _1: 8928, A _2: 7290, A _3: 12,310th

909846/0678

Atf

By multiplying each of the above hex numbers with the corresponding thousandth volume ratio for each apartment, the following values were obtained:

A ₁ : 285696O, A ₂ : 2770200, A ₃ : 3693000. The sum of these values gave the value 9320160.

The total costs for the heat consumption of the heating system in the period under consideration were $ 1,700. The costs for each counting unit were accordingly 1,700: 9,320,160 = O.OOO1824.

The costs to be paid for the individual apartments in US $ are:

: 521.12, A ₂ : 505.28, A ₃ : 673,

60

909846/0678

Claims (5)

Expectations : 1.) Zextwärmemeß-System for measuring and calculating the evaluable Heat for sharing the costs of heating among individual consumers, characterized in that At least one internal temperature sensor (31), a comparator (41), a mathematical multiplier (51) and a counter (71) for each apartment (TA, TAl, TA2 u.s.w.) and at least one time counter (6l) and an outer temperature sensor (32) are provided, the inner Temperature sensor (31) and the external temperature sensor (32) assigned to the comparators (4l) for each apartment that receive input signals and output an output signal, the latter as a function of the difference (St) between the external temperature and the internal temperature of each apartment, the output signal being the mathematical Multiplier (51) applied, which is operatively connected to the time counter (61) to thereby as the output signal of the multiplier, the product between the output signals of the time counter (61) and the output signals of the comparator (4l), the counting measuring device (71) for calculation or recording of the output signal from the multiplier is provided. 2. System according to claim 1, characterized in that a plurality of internal temperature sensors in different internal spaces is arranged. 909846/0678 ORIGINAL INSPECTED 3. System according to claim 2, characterized in that the plurality of internal temperature sensors are operatively effective is connected to a plurality of comparators to which a single external temperature sensor is assigned. 4. System according to claim I _9, characterized in that a plurality of mathematical multipliers is provided, one for each consumer output, with each of the mathematical multipliers being connected to a single common hour meter for all consumer outputs. 5. System according to claim 1, characterized in that it has a plurality of measuring devices, namely one for each individual consumer output. 909848/06? $