WO2018224222A1 - Procédé de fonctionnement d'un système de consommation thermique - Google Patents

Procédé de fonctionnement d'un système de consommation thermique Download PDF

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Publication number
WO2018224222A1
WO2018224222A1 PCT/EP2018/061530 EP2018061530W WO2018224222A1 WO 2018224222 A1 WO2018224222 A1 WO 2018224222A1 EP 2018061530 W EP2018061530 W EP 2018061530W WO 2018224222 A1 WO2018224222 A1 WO 2018224222A1
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WIPO (PCT)
Prior art keywords
thermal
consumption
profile
individual
consumer
Prior art date
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PCT/EP2018/061530
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German (de)
English (en)
Inventor
Bruno Sailer
Original Assignee
Innogy Se
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Innogy Se filed Critical Innogy Se
Priority to EP18726346.2A priority Critical patent/EP3635492A1/fr
Publication of WO2018224222A1 publication Critical patent/WO2018224222A1/fr

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    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B15/00Systems controlled by a computer
    • G05B15/02Systems controlled by a computer electric
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B2219/00Program-control systems
    • G05B2219/20Pc systems
    • G05B2219/26Pc applications
    • G05B2219/2648Central heating

Definitions

  • the application relates to a method for operating a thermal
  • the application relates to a thermal consumption system and an evaluation device for a thermal
  • Consumption system such as a heat consumption system and / or a
  • Cooling system also called cooling system.
  • a thermal sensor also called cooling system.
  • Consumption system generally includes a central tempering device to provide thermal energy.
  • This thermal energy may be transmitted to a plurality of thermal consumers via an energy mine transport network, such as a pipeline network.
  • a thermal consumer is in particular equipped to deliver the thermal energy obtained at least partially to the environment. In other words, thermal energy is "consumed”.
  • a (central) detection device in the form of an energy quantity meter is usually provided.
  • Energy meter is designed to measure the thermal energy consumed in the thermal consumption system, in particular by the plurality of thermal consumers. The measurement results are then used for billing.
  • the object is according to a first aspect of the application by a method for operating a thermal consumption system, in particular a
  • Heat consumption system and / or a cooling consumption system solved according to claim 1.
  • the method comprises:
  • thermal load of the plurality of thermal consumers from the total consumption profile based on at least one stored individual profile data set of the at least one thermal load of the plurality of thermal consumers.
  • a total consumption profile of a plurality of thermal consumers is detected and from the total recorded consumption profile with the help of at least one stored individual profile data set of at least one thermal consumer, an individual consumption profile of this thermal
  • a thermal consumption system is to be understood as meaning, in particular, a system which provides thermal energy and in which it supplies thermal energy Energy is released by a plurality of thermal consumers at least partially to the environment, so at least partially consumed.
  • the thermal consumption system can be arranged at least partially in a building, for example for the temperature control of the building.
  • the thermal consumption system may be a heat consumption system and / or a cooling consumption system. In other words, by the thermal
  • Consumption system heat energy and / or cooling energy can be provided.
  • Exemplary and non-terminating thermal consumers are radiators, heat sinks, hot and / or cooling water taps, hot or cold water tanks, and the like. It should be understood that a thermal consumer may have two or more sub-consumers. For example, a hot and / or cooling water tapping device may have two or more outlets (sub-consumers).
  • the overall consumption profile may be an aggregated consumption profile in which the individual consumption profiles of the respective thermal consumers are aggregated to form an overall consumption profile.
  • a total consumption profile which by all thermal consumers of a
  • thermal consumption system is detected.
  • a consumption profile according to the present application can be represented by recording the heat output (dQ / dt) over time t.
  • a consumption profile generally represents the thermal energy consumption over time.
  • a consumption profile can change the course of the thermal
  • Thermal energy consumption of the thermal consumption system for a certain period of time (eg year, month, week, day, hour, etc.) represent. It is understood that the thermal energy consumption can be represented in various ways (eg Oil consumption of a heating device, gas consumption of a heating device, heat or cooling amount of a tempering device, etc.).
  • an individual consumption profile that is to say a consumption profile which is caused only by a single thermal consumer, from the recorded total consumption profile
  • a profile data set according to the present application comprises data which characterize the thermal consumption behavior of a specific thermal consumer (unique in the consumption system).
  • a specific thermal consumer unique in the consumption system.
  • the thermal consumers of a thermal consumption system have a different thermal consumption behavior.
  • the (aggregated) total consumption profile can be deaggregated or decomposed into individual individual consumption profiles.
  • an overall consumption profile can be created (often) only by one (or a few) combination (s) of individual consumption profiles. Therefore, a unique decomposition into individual consumption profiles based on the at least one stored profile data set is possible.
  • the detection of the overall consumption profile can be carried out by measuring at least one of the two consumption profiles
  • Consumption parameters in particular a thermal consumption parameter of the thermal consumption system include.
  • Consumption parameters can be measured on at least one tempering device of the thermal consumption system.
  • the tempering device is arranged to provide thermal energy (e.g., heat and / or cooling energy)
  • the tempering device may be a central tempering device of the thermal consumption system.
  • the plurality of thermal consumers can be supplied with thermal energy from the tempering device.
  • Temperianssvoriques so at least one thermal consumption parameter of Temper michsvorraum measured, can be detected (or generated) in a simple manner (for example, by a suitable sampling of the measured values measured) the total consumption profile.
  • the tempering device may be a heating and / or cooling device.
  • Exemplary and non-terminating tempering devices are
  • Cooling generators and heaters such as gas boilers, oil boilers, heat pumps, district heating transfer stations, etc.
  • the at least one (thermal) consumption parameter may be selected from the group comprising:
  • At least one input consumption parameter of the tempering device at least one output consumption parameter of the tempering device, and
  • At least one output parameter of the thermal consumption system For operating the tempering device, provision may be made for materials to be supplied to the tempering device via at least one access. For example, fresh water, oil, gas, district heating, etc. the
  • Temperianssvorraum be supplied.
  • corresponding input consumption parameters of the temperature control device can be measured by at least one counter or measuring device.
  • an energy counter can be provided which measures the provided thermal energy, that is to say an output consumption parameter of the tempering device.
  • the output parameter of the thermal consumption system may be the measurement of a thermal consumption parameter in the main return of the
  • a thermal energy meter may include a volume flow sensor (flow meter, water meter), a temperature sensor, such as a temperature sensor pair, and optionally an electronic calculator for determining the amount of heat from these quantities. Also, an ultrasonic measurement can be used to replace the volume flow, the average flow velocity (together with the
  • the acquired data can be stored in a detection device, in particular a
  • Machining device of the detection device to be processed by suitable scanning, such that a consumption profile is detected or created.
  • the thermal consumption system may at least partially be arranged in a building (or a part of a building, such as an apartment, floor, etc.).
  • the method may further comprise the detection of at least one outside temperature, that is to say in particular the temperature outside the building.
  • the determination of the at least one individual consumption profile may be based on the Outdoor temperature based.
  • the behavior of a thermal consumer may depend on environmental attributes, in particular the outside temperature.
  • the individual consumption profiles can be generated with a higher accuracy.
  • other environmental attributes such as time or calendar data (eg night or day, seasons, etc.), can be taken into account.
  • the at least one profile data record of the at least one thermal consumer can be predetermined, for example, by the manufacturer and stored in a memory device of an evaluation device.
  • the at least one profile data record of the at least one thermal consumer can be determined in at least one calibration step (or phase).
  • the at least one calibration step or phase.
  • only a single thermal consumer can be activated in a calibration step (the other thermal consumers of the consumption system may be deactivated during this time). Then the (individual) consumption profile of the activated consumer for a certain period of time, in particular between
  • Activation time start time
  • deactivation time end time
  • certain parameters characteristic of the behavior in particular individual consumption parameters
  • the profile record may include the recorded or captured (individual)
  • Calibration step specific profile record can be saved.
  • the particular profile data set may together with the outside temperature present during the calibration step and possibly further
  • Environment attributes such as time or calendar data (e.g., night or day,
  • optimizers e.g., neural networks or similar KI systems
  • neural networks e.g., neural networks or similar KI systems
  • Determination results are used. For example, a
  • Calibration phase in the form of a training phase of one can be provided optimizing means (e.g., neural networks or similar KI systems) to the
  • Profile data records can in this case also be stored, for example, in the form of a neural network.
  • the profile data set of the at least one thermal consumer may comprise at least one individual consumption parameter of the thermal consumer selected from the group comprising:
  • a combination of two or more of these parameters is suitable for an almost unique characterization of the thermal behavior of a thermal consumer (of a particular consumption system).
  • Temperature demand parameters may be a parameter, such as the
  • his exemplary usage profile parameters include, for example, information about the location or the application of the thermal consumer, such as the heating of a particular room (with a specific size and / or application (eg living room, bedroom, kitchen, bathroom)), etc.
  • Dynamic control behavior parameters include in particular thermal Ramps or changes in the amount of heat, for example during the
  • Activation phase of the thermal load e.g., heat demand ramp due to room thermostat, buffering hot water tank, etc.
  • the deactivation phase of the thermal load or the like e.g., heat demand ramp due to room thermostat, buffering hot water tank, etc.
  • Consumption parameters result in particular from a recorded in a calibration step individual consumption profile or from this at least derived, for example, be calculated.
  • the method may further comprise determining a thermal usage amount of the particular thermal load based on the determined individual consumption profile of the particular thermal load. In particular, from a consumption profile, the thermal consumption amount can be calculated, after an individual
  • Consumption profile has been determined for a particular thermal consumer, from this the consumed amount of thermal energy can be determined by this consumer during a certain period of time.
  • Consumption quantities can be evaluated, for example (for certain past periods). For example, it can be recognized from which
  • Environmental data can also identify system states or consumer states as atypical and / or inefficient.
  • the method may comprise: Comparing the determined thermal consumption amount of the particular thermal load with at least one (storable) thermal consumption criterion associated with the particular thermal load, and
  • a particularly high and / or rapidly increasing heat demand compared to a thermal consumption criterion in the form of a normal
  • Heat demand of a consumer on one (or more) certain causes, such as a specific open window and / or a defective thermostat close.
  • a predetermined notification action sending a corresponding message to a terminal of the user of the thermal
  • a control of a shading system, a window, an (automatic) door, etc. take place. If, for example, due to an exceeding of a thermal consumption criterion (eg predetermined maximum value), it is determined that a cooling consumer has an instantaneous high consumption this may be due to strong solar radiation, so that a previously described activation can take place.
  • a thermal consumption criterion eg predetermined maximum value
  • the triggering of a predetermined notification action may include an automatic transmission of a control signal to at least one actuator, wherein the actuator and / or the device associated with the actuator (eg
  • Shading system, window, (automatic) door, etc. may be in a thermal relationship with the (particular) thermal load.
  • a thermal relationship means in particular that the actuation of the actuator has an (immediate) effect on the thermal consumption of the thermal load.
  • the effect of shading leads to an immediate consumption reduction of the cooling consumer.
  • the thermal consumption system comprises a plurality of thermal consumers connected via at least one thermal energy transport network.
  • the thermal consumption system comprises at least one detection device, configured to detect an overall consumption profile of the plurality of thermal consumers of the thermal consumption system.
  • the thermal consumption system comprises at least one evaluation device, configured for determining at least one individual consumption profile of at least one thermal consumer of the plurality of thermal consumers from the overall consumption profile based on at least one stored one
  • the thermal energy transport network is set up in particular, which of the at least one tempering device of the thermal
  • Thermal energy supplied eg, in the form of hot or cool fluid (eg, gas, such as air, liquid, such as water)
  • the thermal energy transport network in particular be set up to return the fluid after consumption of the transported with the fluid thermal energy of the plurality of thermal consumers again.
  • the thermal consumption system can be operated in particular by a method described above.
  • the evaluation device comprises at least one input module, configured to receive a total consumption profile of a plurality of thermal consumers of the heat consumption system from a (previously described) detection device.
  • the evaluation device comprises at least one evaluation device, configured to determine at least one
  • the evaluation device can be integrated in a home automation system.
  • the home automation system may include a local control device located in the building or part of a building (e.g., apartment, etc.) having a communication link with a remote central control device (server).
  • the evaluation device can be integrated in the local control device and / or central control device.
  • a home automation system can also trigger a predetermined
  • the input module can be formed as an internal interface between the output of the detection device and the input of the evaluation device.
  • Hardware components may be formed.
  • suitable means such as processors, memories (e.g., for storing the at least one individual profile data set), interfaces, displays, input means, etc. may be provided.
  • FIG. 1 shows a schematic view of an embodiment of a
  • FIG. 2 shows a schematic view of a further embodiment of a thermal consumption system according to the present application
  • Fig. 3 is a diagram of an embodiment of a method according to the present application
  • FIG. 4 shows a diagram with exemplary consumption profiles according to FIG.
  • FIG. 1 shows a schematic view of an exemplary embodiment of a thermal consumption system 100 according to the present application.
  • the thermal utilization system 100 is a (sealed) system in which
  • the thermal consumption system 100 may be a refrigeration consumption system or a heat consumption system.
  • the thermal consumption system 100 comprises a central tempering device 104.
  • central means that the tempering device 104 provides the thermal energy for all the thermal consumers 102 arranged in the thermal consumption system 100. It is understood that according to other variants of the application, two or more Temper michsvortechniken may be provided.
  • the tempering device 104 has at least one inlet 116 and at least one outlet 114.
  • the inlet for example, a
  • Supply medium e.g. a fuel (e.g., oil, gas, etc.), electric power, or similar media.
  • a fuel e.g., oil, gas, etc.
  • electric power or similar media.
  • Temperature control 104 burn the fuel to generate thermal energy.
  • the inlet 116 may be, for example, a connection to a district heating network (or district cooling network). In this case, the
  • Temper istsvortechnisch 104 be a district heat transfer station. It understands that a tempering device may have two or more inlets and / or two or more outlets.
  • the tempering device 104 may feed the generated thermal energy (e.g., in the form of a cooling fluid or warm fluid) into a thermal energy transporting network 112 (e.g., a conduit network 112 having a plurality of tubes, hoses, etc.).
  • a plurality of thermal consumers 102 are connected to the thermal energy transport network 112. In particular, two or more thermal consumers 102 may be provided.
  • a thermal consumer is configured to at least partially dispense at least the thermal energy to the environment.
  • the thermal energy rail transport network 112 may have a return or return pipe.
  • the thermal consumption system 100 comprises at least one detection device 106.
  • the detection device 106 may have at least one sensor or measuring device for measuring at least one (thermal) consumption parameter. In the present example! is indicated that as a first thermal consumption parameter, in particular as
  • the detection device 106 may have at least one sensor or measuring device which performs an at least almost continuous measurement of the at least one (thermal) consumption parameter.
  • the detection device 106 may in particular be configured in such a way from the measured consumption parameter values of the at least one thermal
  • the detection device 106 may have suitable Abstaststoff. In other words, that is
  • Detection device 106 configured to detect a total consumption profile of the plurality of thermal consumers 102 of the thermal
  • the recorded total consumption profile can be made available to an evaluation device 108, in particular an evaluation device 110 of the evaluation device 108, for further processing.
  • the evaluation device 110 is configured to determine at least one individual consumption profile of at least one thermal consumer 102 of the plurality of thermal consumers 102 from the provided total consumption profile based on at least one stored individual profile data set of the at least one thermal consumer 102 of the plurality of thermal consumers 102 At least one individual profile data set for each thermal load 102 of the thermal consumption system 100 may be stored in a memory device 109 of the evaluation device 108.
  • a more detailed description of the operation of the evaluation device 110 is provided below.
  • the detection device may also be at least partially integrated in the evaluation device.
  • the evaluation device can be any suitable measurement device.
  • the ⁇ in particular, be a computer device.
  • the ⁇ in particular, be a computer device.
  • Evaluation device to be integrated in a (anyway provided) home automation system, so that the hardware components of the home automation system can be used.
  • FIG. 2 shows a schematic view of a further exemplary embodiment of a thermal consumption system 200 according to the present application. To avoid repetition, essentially only the differences from the exemplary embodiment according to FIG. 1 will be described below. For the other components of the thermal economy system 200, reference is made to the above References.
  • the thermal consuming system 200 is a heat consuming system. However, the following embodiments can be easily transferred to a refrigeration consumption system or a combined heat and refrigeration consumption system.
  • the heat consumption system 200 comprises a central tempering device 204 in the form of a heating device 204.
  • a gas heater 204 is assumed below. However, the following can
  • Embodiments are easily transferred to other heating devices.
  • the gas heater 204 in the present case has two inlets 216.1, 216.2.
  • the first inlet 216.1 is provided for feeding water, which is to serve inter alia as a transport medium for the thermal energy.
  • the further inlet 216.2 is provided for the supply of gas.
  • the gas heater 204 is set up that
  • the gas heater 204 then feeds the heated water and thus the generated thermal energy into a thermal
  • the energy-harvesting transport network 212 comprises, in particular, a multiplicity of pipes which, for example, can be at least partially installed in the masonry of a building.
  • thermal loads 202.1 to 202.n are connected to the thermal energy harvesting transport network 212.
  • hot water taps 202.1, 202.2 and radiators 202.3, 202.4, 202.n are shown as thermal consumers. It is understood that further and / or other thermal consumers can be provided.
  • the energy rail transport network 212 also has a main return 218 over which spent water is recycled.
  • a main return 218 over which spent water is recycled.
  • the outlet 214 be provided at least a partial return of the water in a public sewer network.
  • the heat consumption system 200 shown includes a detection device, which in the present case consists of a plurality of separate sensors, and the like.
  • Components 206.1 to 206.5, 220 is formed.
  • a plurality of measuring devices 206.1 to 206.5 and a processing device 220 are provided for processing and in particular processing the measured values.
  • the first measuring device 206.1 measures as the input consumption parameter of the tempering device 204 (at least almost continuously) that of
  • Gas heater 204 amount of gas supplied.
  • the second measuring device 206.2 measures in a corresponding manner as the input consumption parameter of the
  • the measuring device 206.3 may in particular be a thermometer for measuring the outside temperature.
  • the temperature outside the building in which the heat utilization system 200 is at least partially installed is measured at at least one suitable location.
  • the measuring device 206.4 measures, in particular as the output parameter of the thermal consumption system 200, the recycled water quantity and the measuring device 206.5 measures (at least almost continuously) as
  • Output consumption parameter of the tempering device 204 the thermal energy fed from the gas heater 204 in the energy harvesting transport network 212.
  • a heat meter can be provided. It is understood that a smaller number of measuring devices can be provided.
  • Each of the illustrated measuring devices 206.1 to 206.5 provides their respective measured values of the respective (thermal) consumption parameter of the Processing device 220 via an interface 222 is available.
  • Processing device 220 may be integrated in particular in the evaluation device 220. The processing device 220 processes the received
  • Measured values in particular such that at least one total consumption profile of, in particular, all heat consumers 202.1 to 202.n are detected, in particular generated.
  • a separate total consumption profile and / or two or more individual separate total consumption profiles can be used to create a common overall consumption profile.
  • Evaluation device 208 Based on the at least one recorded total consumption profile and at least one individual profile data set of the at least one stored in the storage device 209
  • Heat consumer 202.1 to 202.n determines the evaluation device 210 at least one individual consumption profile of at least one heat consumer 202.1 to 202.n.
  • the evaluation device 208 is set up in the present case to determine from the determined individual consumption profile the specific thermal consumption quantity, that is to say the heat energy consumed by a single specific heat consumer 202.1 to 202.n in the present case.
  • This particular thermal consumption quantity that is to say the heat energy consumed by a single specific heat consumer 202.1 to 202.n in the present case.
  • Consumption criteria (which may for example also be stored in advance in the memory device 209) are compared.
  • the consumption criterion is assigned in particular to the specific thermal load 202.1 to 202.n.
  • the consumption criterion can specify a consumption range which is maintained during a normal operation of the consumer 202.1 to 202.n. This can be determined in advance by tests, for example. Upon detection of a predefinable minimum deviation (this can also be found in the
  • Storage device 209) between the determined thermal consumption amount and the thermal consumption criterion may be determined by the
  • Evaluation 208 are triggered a predeterminable notification action. For example, by using an output module 224 a
  • a control signal can be sent to an actuator (not shown) and / or the device associated with the actuator (for example an electrical consumer, such as an electrically operated window, shading system, etc.).
  • the device and the aforementioned consumer may in particular be in a thermal relationship with one another.
  • this evaluation and / or the triggering of the predetermined notification action can also be performed by other components (for example, components of a home automation system).
  • FIG. 3 shows a diagram of an exemplary method according to the present application.
  • FIG. 4 shows a diagram with
  • a first step 301 at least one overall consumption profile of a plurality of thermal consumers 202 of the thermal consumption system 200 is detected.
  • detecting the at least one overall consumption profile may involve measuring at least one (thermal) Consumption parameters (eg that of a tempering device 204
  • thermal energy discharged thermal energy of the thermal power system 200 and then generating the total consumption profile from the measured values.
  • An exemplary overall consumption profile 430 is shown in FIG. As can be seen, the thermal energy delivered is shown in the form of heat output over time t in the diagrams.
  • an evaluation is carried out by the evaluation device 210 based on the recorded total consumption profile 430.
  • the evaluation device 210 based on the recorded total consumption profile 430.
  • at least one corresponding profile data record can be stored for each thermal consumer of a thermal consumption system.
  • different profile data sets may be stored for preferably each consumer for different environmental conditions (e.g., at least two different environmental attribute values in the form of different outside temperature values).
  • the profile data sets can be determined in advance in a (not shown) calibration step or a calibration phase (also called learning phase) and
  • the overall consumption profile (in this case, an individual consumption profile of the (only) activated consumer 202.1) may be recorded by the detection means 206, 220 for a certain period between activation time and deactivation time (as described above). From the recorded (individual) (calibration)
  • Consumption profile can have certain parameters characteristic of the behavior (eg temperature requirement parameter, usage parameter iparameter, dynamic
  • Control behavior parameters are derived and stored (preferably along with the environmental attributes present during the acquisition).
  • the recorded individual consumption profile may be stored in the storage device 209 as a sample file set (preferably along with the environmental attributes present during capture). This may preferably be carried out accordingly for each thermal load.
  • the system may have at least optimizing means in order to determine the individual profile data sets in the learning phase, and in particular subsequently to carry out the determining step 302 with these optimizing means.
  • the evaluation device 208 is set up to determine the individual consumption profiles 432, 434 based on the provided total consumption profile 430 and the stored data (profile data sets and, for example, environmental attributes). Again, solution algorithms (e.g., the above-mentioned optimizer) can be used to allow automatic decomposition of the overall consumption profile within a short period of time.
  • solution algorithms e.g., the above-mentioned optimizer
  • the course of the overall consumption profile 430 is characteristic in particular because of the amplitude values and the ramps or gradients 427, 429; in particular, at least the respective characteristic ramp profile 431, 433 (and / or amplitude values) can be stored in the profile datasets in an almost unambiguous manner from the overall consumption profile 430 the individual consumption profiles 432, 434 are determined, because (as a rule) only a combination of individual
  • Consumption profiles 432, 434 leads to the total recorded consumption profile 430. If several combinations are still possible, historical data, environment attributes, etc. can be used in the determination.
  • the (actual) thermal consumption quantity (for a specific period of time) can then be determined, in particular calculated, for each specific individual consumption profile 432, 434 or the respectively associated consumer 202.
  • an evaluation of the specific consumption quantity can be carried out As stated above, this can result in the execution of a notification action
  • the present application makes it possible to disaggregate an aggregated measured value (total consumption profile), but which is read out at least several times per hour Analysis of the individually consumed energy of the individual consumers of a consumption system
  • the measured energy sources used may be the final energy meter and / or a heat meter
  • Main supply / return of the heating system or energy supply transport network of the consumption system are suitable.
  • conventional or already built measuring technology can be used.
  • a regular measurement acquisition e.g.
  • Machining device 220 can be retrofitted.
  • the measured values can be transmitted to a computer center or evaluation device for storage, visualization and / or processing. Additional data (eg outside temperature) can be used to analyze the data.
  • Additional data eg outside temperature
  • an illustrative interface to the user monitoring, mobile terminal, etc.
  • / or visual and / or audible alarms can be part of the consumption system. This can be displayed in particular previously described notifications due to an evaluation.
  • the described detection and disaggregation or determination of measured values then allows a previously (possibly) possible real-time and / or

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Abstract

La présente invention concerne un procédé de fonctionnement d'un système de consommation thermique (100, 200), en particulier d'un système de consommation de chaleur (100, 200) et/ou d'un système de consommation de froid (100), comprenant les étapes suivantes : la détection d'un profil de consommation totale (430) d'une pluralité de consommateurs thermiques (102, 202) du système de consommation thermique (100, 200) ; et la détermination d'au moins un profil de consommation (432, 434) individuel d'un consommateur thermique (102, 202) de la pluralité de consommateurs thermiques (102, 202) à partir du profil de consommation totale (430), en fonction d'au moins un ensemble de données de profil individuel mémorisé de l'au moins un consommateur thermique (102, 202) de la pluralité de consommateurs thermiques (102, 202).
PCT/EP2018/061530 2017-06-07 2018-05-04 Procédé de fonctionnement d'un système de consommation thermique WO2018224222A1 (fr)

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DE102017112505.1A DE102017112505A1 (de) 2017-06-07 2017-06-07 Verfahren zum Betreiben eines thermischen Verbrauchssystems
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DE102019202440A1 (de) * 2019-02-22 2020-08-27 Siemens Aktiengesellschaft Verfahren zur Ermittlung eines thermischen Verbrauches eines Energiesystems, Energiemanagementsystem sowie Energiesystem
DE102022131614A1 (de) 2022-11-29 2024-05-29 E.On Se Identifizierung einer Konfiguration einer Wärmepumpe basierend auf einem Gesamtstromverbrauch

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20130289788A1 (en) * 2012-04-25 2013-10-31 Abhay Gupta Energy Disaggregation Techniques for Low Resolution Whole-House Energy Consumption Data
US20160212506A1 (en) * 2014-11-17 2016-07-21 Curb Inc. Home intelligence system
US20160266594A1 (en) * 2015-03-12 2016-09-15 Daniel Kauffman System and method for residential utility monitoring and improvement of energy efficiency

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US9261863B2 (en) * 2012-01-23 2016-02-16 Earth Networks, Inc. Optimizing and controlling the energy consumption of a building
US9595070B2 (en) * 2013-03-15 2017-03-14 Google Inc. Systems, apparatus and methods for managing demand-response programs and events
KR102366961B1 (ko) * 2014-10-07 2022-02-24 삼성전자 주식회사 공조기를 관리하는 방법 및 장치

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20130289788A1 (en) * 2012-04-25 2013-10-31 Abhay Gupta Energy Disaggregation Techniques for Low Resolution Whole-House Energy Consumption Data
US20160212506A1 (en) * 2014-11-17 2016-07-21 Curb Inc. Home intelligence system
US20160266594A1 (en) * 2015-03-12 2016-09-15 Daniel Kauffman System and method for residential utility monitoring and improvement of energy efficiency

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
J ZICO KOLTER ET AL: "Energy Disaggregation via Discriminative Sparse Coding", 6 December 2010 (2010-12-06), XP055499502, Retrieved from the Internet <URL:https://papers.nips.cc/paper/4054-energy-disaggregation-via-discriminative-sparse-coding.pdf> [retrieved on 20180814] *

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