FR2860871A1 - Thermal energy meters drift or malfunction detection device for e.g. heating system, has management unit that compares energy measured by thermal energy meter with theoretically consumed energy - Google Patents

Abstract

The device has a management unit (1) connected to a thermal energy meter (2) and comprising a determination unit (4). The unit (4) determines theoretically consumed energy on a system based on arithmetic mean of positive difference between a reference temperature and an external temperature measured in a determined time period. The management unit compares the energy measured by the meter with the determined theoretical energy. An independent claim is also included for a method for detection of malfunctioning and/or drift of a thermal energy meter.

Description

- 1 -

  The present invention relates to a method for detecting the malfunction or drift of a thermal energy meter placed on a pipe of a heating, air conditioning or similar network, a building and a device implementing said method. .

  In the field of heating or air conditioning of premises of a building, it is well known to use thermal energy meters that measure the energy supplied to maintain a so-called comfort temperature in said premises. The energy measurements taken from the meter are then used for billing the consumer. It is well known to those skilled in the art that the meters used to measure the energy consumed on a heating and air-conditioning production and distribution network are liable to drift over time over their accuracy. This drift, which is generally to the advantage of the customer, can cause a significant loss of turnover for the energy supplier. Furthermore, in the event of a sudden stop of the meter, without disruption of the supply of thermal energy on the network, said stoppage of the meter can be detected only a very long time later, so that this stop can cause a considerable loss. turnover for said thermal energy supplier.

  In order to remedy this drawback, electronic modules equipped with a logic unit or a microprocessor have already been devised to control the operation of the meter and to detect major anomalies of this operation. These electronic modules are advantageously provided with communication means such as a modem to transmit detected anomalies to a remote site for qualified personnel to intervene on the site to repair or change the meter.

  This type of device has the disadvantage of being effective only in the event of major malfunction or stoppage of the meter and not to allow detection of the drift of the accuracy of said counter.

  BOT-FR-7 -TEXTE REMOVAL 2860871 2 In addition, the "degrees / days" corresponding to the average value over one day of the positive difference between a reference value and the outside temperature and the "degrees / unified days "which correspond to" degrees / days "calculated for a reference value of 18 C, the unified degrees / day being calculated according to the method of the company" METEO FRANCE "or" COSTIC "for example. The degrees / day allow the operators, the heating engineers, climatizers, Cabinets of Studies, Trustees and Managers of collective housing to optimize the management of the heating or the air-conditioning in order to realize energy savings. For example, degrees / days are usually used to verify a posteriori that the overall thermal consumption of a single building or a group of buildings is consistent with the climatic conditions to which the buildings were exposed during a reference period.

  This method is relatively unclear because, on the one hand, measurements of the outside temperature entering the determination of "unified degrees / day" are made at a single point of a geographical region and, on the other hand, the usual methods of calculation approximates the average value from the minimum and maximum temperatures recorded over the reference period. Moreover, this method has the disadvantage of allowing the observation of a drift of the meter that posteriori thus risking to burden the turnover of the energy supplier.

  One of the aims of the invention is therefore to overcome these drawbacks by proposing a method for detecting the malfunction or drift of a thermal energy meter placed on a pipe of a heating, air-conditioning or similar system. of a building to allow automatic or semi-automatic, rapid and reliable detection of malfunction or drift.

  For this purpose and in accordance with the invention, there is provided a method for detecting the malfunction or drift of a thermal energy meter placed on a BOT-FR-7 - TEXT REMOVAL - 3 heating, air-conditioning or the like, of a building, characterized in that it comprises at least the following steps of at least one measurement of the external temperature of the building, and then of determining the energy theoretically consumed on the network in a function of the positive difference between a reference temperature and the outside temperature measured in at least one determined time interval, and then measuring the energy consumed in said time interval, said measurement being provided by the thermal energy meter , then comparing said energy actually consumed on the network with the energy theoretically consumed, and finally triggering an alarm signal if the difference between the energy ef fectively consumed in the time interval and the energy theoretically consumed is greater than a threshold. The alarm signal is preferably transmitted to a remote site by means of communication.

  In a particularly advantageous manner, the step of determining the energy theoretically consumed on the network consists at least in the following steps of n measurements of the outside temperature of the building during at least one determined period of time, and then calculating the differences between a reference temperature and each of the measurements of the outside temperature, then of calculating the arithmetic mean of the positive deviations during the period of time, and finally of calculating the energy theoretically consumed which corresponds to an algebraic value added to the arithmetic mean of the positive differences between the reference temperature and the outdoor temperature measurements multiplied by a so-called thermal coefficient depending on the thermal characteristics of the building.

  It will be observed that the algebraic value corresponds to an energy consumption that is independent of the differences between the reference temperature and the measurements of the outside temperature such as, for example, the ergonomic consumption of the network for the production of domestic hot water and is BOT-FR -1 - TEXT REMOVAL 2860871 - 4 - zero for a heating network comprising independent heat exchangers for the production of heating and the production of hot water.

  Moreover, the algebraic value and the thermal coefficient are either predetermined or determined by linear regression from the energy measurements actually consumed and the arithmetic means of the positive differences between the reference temperature and the outside temperature. Said reference temperature may be variable over time. Indeed, a reference temperature can be set for the daytime hours and for the nocturnal hours, for the days of the week and for the days of the weekend, etc ...

  Moreover, the threshold triggering the alarm signal is either a predetermined fixed value or a variable value which depends, for example, on the standard deviations of the series of values of the energy actually consumed by the installation over different periods for a given period. same value of degrees / period calculated over the corresponding periods.

  In a particularly advantageous manner, the steps of determining the energy theoretically consumed, measuring the energy consumed and comparing the energy effectively consumed with the energy theoretically consumed, are performed in two time intervals, a first interval said "short" time of the order of a few minutes, such as an interval of 15 minutes, for example, for detecting malfunctions of the thermal energy meter and a second time interval called "long" of the order several months such as an interval of 3 months for example, allowing the detection of the drift of the accuracy of the thermal energy meter.

  Another subject of the invention relates to a device for detecting the malfunction or drift of a thermal energy meter placed on the pipe of a heating, air-conditioning or similar system of a building that is remarkable in that it comprises means for taking the external temperature connected to a management unit connected to a thermal energy meter and comprising means for determining the energy theoretically consumed on the network. according to the arithmetic mean of the positive difference between a reference temperature and the outside temperature measured over at least a determined period of time so that the management unit can compare the energy actually consumed on the network, which corresponds to the energy measured by the meter, with the theoretically consumed energy which is calculated by the theoretical energy determination means consumed.

  Other advantages and features will become more apparent from the following description of several alternative embodiments of the device and of the method according to the invention, with reference to the appended drawings in which: FIG. 1 is a schematic representation of the device for detecting the malfunctioning or drifting of a counter of the thermal energy according to the invention; - FIG. 2 is a graph representing on the ordinate the energy theoretically consumed and on the abscissa the degrees / period, that is, that is, the arithmetic mean of the positive deviations between the reference temperature and the measurements of the outside temperature during a given period.

  With reference to FIG. 1, the device according to the invention consists of a management unit 1 connected to a thermal energy meter 2 placed on a pipe 3 of a heating, air-conditioning or similar network of a building. Said management unit 1 comprises data storage and processing means necessary for verifying all the counter parameters such as, for example, the flow rate and / or the upstream and downstream temperatures, not shown in the figures. Indeed, it should be noted that it is appropriate to isolate the problems related to the BOT-FR-i -TEXTE REMOVAL 2860871 - 6 - malfunction of the thermal energy meter problems related to a malfunction of the other components of the thermal installation, by identifying and analyzing, among other things, the nominal and extreme values of the upstream and downstream fluid and flow temperatures in the various operating regimes, these values being measured by the meter. Thus, for example, readings indicating no flow, high upstream temperature, and abnormally low downstream temperature will indicate a problem with a pump or valve and not a meter problem.

  Moreover, the management unit 1 comprises determination means 4 represented in dotted lines in FIG. 1, the energy theoretically consumed Eth on the network as a function of the difference between a reference temperature Tref and the outside temperature. Text measured over a given period of time P in such a way that the management unit 1 can compare the energy effectively consumed Econs on the network, which corresponds to the energy measured by the meter, with the energy theoretically consumed Eth which is calculated by the means for determining the energy theoretically consumed Eth. These means 4 for determining the theoretically consumed energy Eth consist for example in electronic means and / or a computer program of the management unit 1 which advantageously comprises a display unit 5 such as an LCD screen for example for that an operator can read the state of the management unit 1 for example. The latter furthermore comprises communication means 6 so as to transmit an alarm to a remote site 7 as soon as the difference between the energy measured by the counter 2, that is to say the energy actually consumed. Econs and the energy theoretically consumed Eth calculated by the determination means 4 of the energy theoretically consumed is greater than a determined threshold. These communication means 6 consist of a radio frequency modem, a PSTN-switched telephone network modem or any other means of communication well known to those skilled in the art.

  According to a first variant embodiment of the device according to the invention, the communication means 6 of the management unit 1 are substituted by removable means for storing and exchanging computer data capable of cooperating with reading means. / write located on the existing site to allow a transmission deferred in time, said semi-automatic transmission, in the event that the detection time of the drift or malfunction of the electrical energy meter is not critical.

  With reference to FIG. 1, the device furthermore comprises means for taking external temperature such as an electronic thermometer 8, for example, connected to the management unit 1. The thermometer 8 is, for example, fixed on one of the walls of the building, outside.

  According to another variant embodiment, the measurement of the outside temperature can be transmitted to the management unit 1 by the thermal energy meter 2, the external temperature measurement means being connected to said counter 2.

  According to a last variant of execution, the degrees / period, that is to say the arithmetic mean of the positive differences between the reference temperature and / or the measurements of the outside temperature during a given period, can be transmitted to the management unit 1 by the communication means 6 or by the removable means for storing and exchanging computer data.

  It goes without saying that the management unit 1 may be integral with the thermal energy meter 2 without departing from the scope of the invention.

  The operation of the device according to the invention will now be explained with reference to FIGS. 1 and 2.

  The external temperature of the building is measured by the thermometer 8 and transmitted to the management unit 1 which BOT-FR-1 - TEXT REMOVAL 2860871 - 8 then determines the energy theoretically consumed Eth on the network as a function of the average of the deviations positive between a reference temperature Tref and the outside temperature measured in a determined time interval D, the reference temperature Tref being recorded in the management unit 1. The energy consumed Econs in said time interval is then measured, said measurement being provided by the thermal energy meter 2, then the management unit compares the energy actually consumed Econs on the network with the energy theoretically consumed Eth calculated by the management unit 1. If, after verification of the consistency of the measured values of flow and upstream and downstream temperatures, the difference between the energy actually consumed Econs and the energy theoretically Consumption Eth is above a threshold, the management unit 1 triggers an alarm signal and transmits it through the communication means 6 to the remote site 7 so that maintenance services, for example, can intervene as quickly as possible. possible on the meter or, failing that, on the installation in order to repair.

  In order to determine the energy theoretically consumed Eth on the network, the management unit 1 takes n measurements of the outside temperature Text of the building during a determined period of time, and then calculates the differences between the reference temperature T ref and each measurements of the outside temperature Text then it calculates the arithmetic mean of the positive deviations during the period of time D, said average being called degrees / period Dp, and finally, it calculates the theoretically consumed energy Eth which then corresponds to a algebraic value Eo added to the arithmetic average of the positive differences between the reference temperature and the measurements of the outside temperature), that is to say at the degrees / period Dp, multiplied by a thermal coefficient K depending on the thermal characteristics of the building . The energy theoretically consumed Eth is then written in the form of the following equation: Eth = E0 + K Dp BOT-FR-1 -TEXT REMOVAL 2860871 - 9 The algebraic value Eo corresponds to the energy consumption of the network for the production of domestic hot water and is therefore zero for a heating network comprising independent heat exchangers for the production of heating and the production of hot water. In the present case, with reference to FIG. 2, the algebraic value Eo is not zero, the heat exchanger of the heating network being identical for the production of heating and the production of hot water.

  The algebraic value Eo and the thermal coefficient K can either be predetermined and recorded in the management unit 1, or determined during a so-called linear regression learning phase from the measurements of the energy actually consumed ECOR5 and arithmetic means. over a reference period, positive deviations between the reference temperature TYef and the external temperatures Text, ie degrees / periods Dp.

  As regards the reference temperature TTef, it is usual to use the reference temperature Tref = 18 C; however, it will be possible to program in the management unit 1 the reference temperature Tref that one wishes, the latter being able to vary over time. Indeed, this reference temperature Tref corresponds to a comfort temperature which is lower at night than the day in particular and which is higher during the day during the weekend rather than the rest of the week.

  Furthermore, the threshold beyond which the alarm signal is transmitted to the remote site 7 may be either a predetermined fixed value and stored in the management unit 1, or a variable value which is calculated by said management unit 1 and which depends for example on the standard deviations of the series of values of the measured energy, that is to say the energy consumed Econs corresponding to a value of degrees / period obtained by performing the arithmetic mean of the positive differences between the temperature Reference Tref and outdoor temperature measurements Text BOT-EN-1 TEXTE REMOVAL - 10 - Finally, it goes without saying that the device for detecting the malfunction or drift of a thermal energy meter may be adapted to all types of thermal energy meters and the examples that have just been given are only particular illustrations in no way limiting the scope of the invention.

BOT-FR-t - TEXT REMOVAL

Claims (15)

- 11 - CLAIMS   1 - Device for detecting the malfunction or drift of a thermal energy meter (2) placed on a pipe (3) of a heating, air-conditioning or similar network of a building, characterized in that it comprises means for taking external temperature (8) connected to a management unit (1) connected to the thermal energy meter (3) and comprising means for determining the energy theoretically consumed on the network according to the arithmetic mean of the positive difference between a reference temperature and the outside temperature measured over at least a determined period of time so that the management unit (1) can compare the energy actually consumed on the network, which corresponds to the energy measured by the meter, with the energy theoretically consumed which is calculated by the determination means (4) of the energy theoretically consumed.   2 - Device according to the preceding claim characterized in that the management unit (1) comprises communication means (6) so as to transmit an alarm to a remote site (7) as soon as the difference between the measured energy by the counter (2) and the energy theoretically consumed calculated by the determination means (4) of the energy theoretically consumed is greater than a determined threshold or to receive information for the determination of the energy theoretically consumed such as the outdoor temperature values and / or degree information / day.   3 - Device according to claim 2 characterized in that the communication means (6) consist of a radio frequency modem.   4 - Device according to claim 2 characterized in that the communication means (6) consist of a dial-up network modem called RTC.   - Device according to claim 2 characterized in that the communication means (6) consist of BOT-FR-t -TEXTE REMOVAL - 12 removable means for storing and exchanging computer data capable of cooperating with reading means / located at the remote site (7) to allow delayed transmission of the alarm.   6 - Device according to any one of the preceding claims characterized in that the external temperature taking means (8) consist of measuring means connected to the thermal energy meter (2).   7 - Device according to any one of the preceding claims characterized in that the management unit (1) is integral with the thermal energy meter (2).   8 - Method for detecting malfunctioning and / or drifting of a thermal energy meter (2) placed on a pipe (3) of a heating, air-conditioning or similar network, of a building characterized in that it comprises at least the following steps: - at least one measurement of the external temperature of the building, - determination of the energy theoretically consumed on the network as a function of the difference between a reference temperature and the temperature external measurement measured in at least a determined time interval, - measurement of the energy consumed in said time interval, said measurement being provided by the thermal energy meter, - comparison of the energy actually consumed on the network with the energy theoretically consumed in the time interval, - the triggering of an alarm signal if the difference between the energy actually consumed and the energy theoretically consumed is greater than a threshold.   9 - Process according to claim 8 characterized in that it comprises a step of transmitting the alarm signal to a remote site (7) by means of communication (6).   - Process according to any one of claims 8 or 9 characterized in that the step of BOT-FR-1 -TEXTE REMOVAL 2860871 - 13 - determination of the energy theoretically consumed on the network consists at least in the following steps - n measurement (s) of the external temperature of the building for at least a predetermined period of time, 5 then - calculating the differences between a reference temperature and each of the measurements of the outside temperature, then - calculating the arithmetic mean positive deviations during the period of time, and finally - calculation of the energy theoretically consumed which corresponds to an algebraic value added to the arithmetic mean of the positive deviations between the reference temperature and the measurements of the outside temperature multiplied by a so-called thermal coefficient depending on the thermal characteristics of the building.   11 - Process according to claim 10 characterized in that the algebraic value corresponds to the energy consumption of the network for the production of domestic hot water.   12 - Process according to claim 11 characterized in that the algebraic value is zero for a heating network comprising independent heat exchangers for the production of heating and the production of hot water.   13 - Process according to any one of claims 10 to 12 characterized in that the algebraic value and the coefficient are predetermined.   14 - Process according to any one of claims 10 to 13 characterized in that the algebraic value and the coefficient are determined by the linear regression from the measurements of the energy actually consumed and the arithmetic means of the positive differences between the temperature of reference and outside temperatures.   - Process according to any one of   Claims 10 to 14 characterized in that the   reference temperature is variable over time.   BOT-FR-7 - TEXT REMOVAL 2860871 - 14 - 16 - Process according to any one of claims 10 to 15 characterized in that the threshold triggering the alarm signal is a predetermined fixed value.   17 - Process according to any one of claims 10 to 15 characterized in that the threshold triggering the alarm signal is a variable value.   18 - Process according to claim 17 characterized in that the threshold depends on the standard deviations of the series of values of the energy corresponding to the values of the period degrees obtained by performing the arithmetic mean of the positive differences between the reference temperature and the measurements of the outside temperature.   19 - Process according to any one of claims 8 to 18 characterized in that the steps of determining the theoretically consumed energy, measuring the energy consumed and comparing the energy actually consumed with the energy theoretically consumed , are performed in two time intervals, a first so-called "short" time interval for detecting malfunctions of the thermal energy counter (2) and a second "long" time interval for detecting the drift of the accuracy of the thermal energy meter. BOT-FR-1 - TEXT REMOVAL