EP3161939A1 - Method for operating a power management device, power management device and computer program - Google Patents

Abstract

Method for operating a power management device for controlling an operating device connected to a power supply network, wherein the maximum demanded and/or provided output of the controlled operating device is at least 3 kW, comprising the steps: receiving of an information data set which describes coupling information or a temporal progression of coupling information from a server device associated with a network provider of a power supply network or a power supplier, wherein the coupling information describes a relationship between a device load caused by the operating device and a target variable to be optimised during an optimisation interval, determining of a load profile which describes a predicted temporal progression of the device load of the operating device during the optimisation interval by optimising the load profile with respect to the target variable via the power management device, providing of the load profile to the server device, and controlling of the operating device via the power management device in the optimisation interval according to a default value for the device load which is predetermined by the load profile for the current operating time.

Description

description

Method for operating an energy management device, energy management device and computer program

The invention relates to a method for operating an energy management device for controlling an operating device connected to a power supply network, wherein the maximum claimed and / or provided power of the controlled operating device is at least 3 kW. In addition, the invention provides an associated energy management ^¬ management device and a computer program relates.

Large buildings and industrial plants often have automation systems that control individual devices and device groups. These automation systems may include energy management devices that can monitor power consumption of controlled and non-controlled devices and, in the case of an active power management device, control the controlled devices such that energy efficiency is increased and / or peak loads are limited.

Operating facilities such as large buildings and industrial plants increasingly also have energy-generating facilities, such as photovoltaic systems, wind turbines or the like. In addition, the share of renewable energies in energy supply networks is generally increasing and energy generation by renewable energies is not freely controllable. While it is common in conventional power supply networks, adapt a power to the required energy consumption, this is when operating equipment can act both as consumers and as producers of energy and renewable energy sources are used in all FAEL ^¬ len possible. In addition, optimizing the energy efficiency of a plurality of individual operating devices connected to a power supply network does not necessarily lead to optimum energy efficiency of the entirety of the operating devices. The invention is thus based on the object of specifying a method for operating an energy management device, by means of which energy efficiency in energy supply networks can be increased and / or a more flexible reaction to changes in the amount of energy generated in the energy supply network is possible.

The object is achieved according to the invention by a method of the type mentioned at the outset, which comprises the following steps: a. Receiving an information record describing coupling information or timing of the coupling information from an energy manager external server associated with a grid operator of the power grid or utility, the coupling information having a relationship between a facility load caused by the facility and a target to be optimized during an optimization ^interval ,

 b. Determine a load profile that predicts a time evolution of the facility load

Operating means during the optimization interval describes by optimizing the load profile relative to the target by the energy management ^¬ management device,

 c. Providing the load profile to the server device, and

d. Control of the operating device by the energy management device in the optimization interval as a function of a predetermined ^¬ value for the device load given by the load profile for the current operating time. According to the invention that is determined by the Energiema ^¬ management device a load profile, which ^¬ describes the timing of the device load during a time optimization approximately interval, it is suggested in which this loading mood in response to a by a dedicated power supply network or the utility energy management device external server device provided information record. In particular, the energy supply network can be a power network for supplying the operating device with electrical energy, but it can also be another energy supply network, for example a gas network or a network in which energy is provided in the form of heat or steam. The load profile can represent a sequence of load values for the A ^¬ direction of the load to represent a time course of the device load. The load values can describe a power ^demanded and / or provided by the operating ^device at the time or in the time interval as an ^input direction load. The individual power values can be specified in kW or MW, for example. The load profile may describe positive device loads describing a required power and / or negative device loads describing a power provided to the power grid. By the

Presetting the information data record, the load profile of the operating device of a predicted operating situation in the power grid can be adjusted. The server device can be operated by an operator of the power supply network or by an energy supplier.

It may be associated with an energy market, an aggregator enabling a common appearance of multiple utilities in the energy market, and / or a virtual power plant that allows a co-occurrence of multiple energy providers in an energy market. By which it ^¬ inventive information exchange, so the reception of the information data record, and providing the load profile to the server device, it is achieved that an optimization tion of the equipment loads, and thus the power generation and energy consumption, not only takes place locally for a single operating device, but also a common optimization of the loads for an entire power grid or for at least parts of a power grid he ^¬ is made possible.

By the energy management device the load profile is optimized with respect to a target value, wherein at least one coupling information be ^¬ writes a correlation between the load and the device to be optimized target, provided by the server device. The type of target size specifies the property with which optimization is performed. For example, a target quantity may be a predicted CO 2 consumption or a consumption of non-renewable energy that is minimized. Alternatively or additionally, can be maximized in energy production as an objective example ^¬ as a share of renewable energy. The stated target variables can be used, in particular, if an operator wishes to actively participate in an operating facility to increase the overall efficiency and thus the environmental friendliness of the energy supply network and the supplied operating facilities. Alternatively or additionally, it is possible that the operating device is designed by an energy supplier, a pricing of a power supply so that the operator of a facility is suggested that propel so to be ^¬ that the power grid more efficiently with the connected operating facilities total ent and thus also cheap to operate. Set a target of Kings ^¬ nen therefore cost of a drawn from the power grid energy or income for a provided for the Energiever ^¬ supply network power are evaluated. Given an efficiency-oriented pricing and an optimization of the costs or the remuneration, this also leads to an increase in the efficiency of the energy supply network with the associated operating facilities. The determination of the load profile can be done by minimizing or maximizing a cost function determining the target variable. In particular, the target size and thus the Kos ^¬ tenfunktion several factors may depend. In this case, the individual factors can be taken into account as a weighted sum, but non-linear couplings between the factors are also possible.

As part of the determination of the load profile, predetermined operating parameters and / or properties of the operating device can be taken into account, which are specified by the user or by other devices. For example, when operating an industrial plant, certain operating times of individual elements of the industrial plant are required in order to achieve a given production quantity. If technical facilities or rooms are to be air-conditioned, typically a given temperature range is to be maintained. Depending on the type of operating device, certain predetermined boundary conditions therefore arise, which can be taken into account when optimizing the load profile. The same applies to the

Control of the operating device, since here, too, the control should always be such that predetermined requirements are met. The optimization and / or control can therefore be carried out in each case under at least one boundary condition in the method according to the invention.

In particular, the coupling information may be a proportionality factor between a consumed or provided energy, which can be calculated as a particular segmental integral over the load profile, and

Target size act. For example, a CO 2 consumption or a price per KWh can be provided as coupling information. It is possible in particular to consider only one effective ^device . However, the relationship between load profile and target size and thus the coupling information can also be more complex. For example, a "staggered" proportionality factor can be used, whereby for different supplied or consumed amounts of energy, wise, various proportionality factors are provided. However, the coupling information may also specify any other functional relationships between the load profile and the target size.

In particular, the optimization interval may be one day, but also several days, half a day, six hours, or the like. It is also possible that in addition to the load profile for the optimization interval further load profiles for longer periods, in particular for a week, a month or a year are calculated and provided to the server device. Long-term load profiles enable an operator of the power supply system appropriate measures, game example, to plan at ^¬ the putting into operation of power plants at an early stage, whereby the overall effectiveness of the Energieversor ^¬ supply network can be further increased. For the calculation of the medium and long-term forecasts for load profiles, further coupling information can be provided by the server devices, but it is also possible to determine corresponding medium and long-term load profiles exclusively from operating parameters and / or properties of the operating device itself and to provide them to the server device , The coupling information may be variable over time and in particular during the optimization interval än ^¬ countries. The coupling information may be a coupling information predicted, in particular by the server device, as a function of operating parameters of the energy supply network or provided by a user of the server device. It can be determined by an evaluation of various information provided to an operator of the energy supply network. The information of the information data record, in particular the lung Kopp- information, can be chosen so that an energy supplier side ge ^¬ wünschtes behavior of the operating device is favored at the power supply mains in the context of the determination of the load profile. Are used as coupling For example, if pricing information is provided, low prices may be imposed for times when energy consumption is likely to be less than energy production.

The information record may additionally comprise a fixed offset, which is added to the target size. This is insbeson ^¬ particular advantageous for the optimization of the target with the optimization of other parameters, beispielswei- se a production quantity in an industrial plant, carried equal ^¬ time. Variations of the target, for example due to amendments ^¬ conclusions of the load profile, are therefore weighted differently depending on the off ^¬ sets. A corresponding offset can represent, for example, the basic costs of a power supply.

The communication between the server device and the energy management device can be achieved, in particular, by network-procurable functions implemented, for example, via SOAP, or by network protocols which map network ^users as objects with settable or readable properties, for example BACnet or OPC UA ^¬ gen. A data exchange is possible in particular via the Internet or a VPN. The underlying network can be completely wired, wireless or completely teilwei ^¬ se wired and partly wireless.

Advantageously, the server device implemented ways once provided by the energy management device to the server device retrieve data through the Energiema ^¬ management device again from the server device. This allows a particularly easy Datenwiederher ^¬ position on the part of the energy management device, for example after a restart or reconfiguration of the energy management device.

The steps a) to c) of the process according to the invention Ki ^¬ nen in a predetermined time interval before the Optimierungsin- tervall be performed. In particular, the load profile can be transmitted in a predetermined time interval before the optimization interval corresponding to the entire optimization period, two-thirds of the optimization interval, the half of the optimization interval or one third of the Optimierungsin ^¬ tervalls. In particular, only a minimum time interval can be predetermined in the method according to the invention, so that an earlier transfer of the load profile is possible. The steps a) to c) can be performed several times at a plurality of temporally spaced points in time before the optimization interval. The information data set transmitted by the server device can be determined in a repeated implementation of steps a) to c), in particular as a function of a previously transmitted load profile. Advantageously, a server device communicates with a plurality of energy management devices, and an information data record transmitted to one of these energy management devices as part of a repetition is determined as a function of the provided load profiles and / or further information of several or all of these energy management devices. It is thus achieved an iterative optimization of the target ^¬ size in an overall composite of a server device and one or more energy management devices.

The operating means may direction of the load by the energy management device in the optimization interval in response to a difference between the predetermined by the load profile for the current operating time set value for the input and a current actual value of the difference value setup ^¬ specified load to be controlled. For example, an actual value of the device ^load may depend on the activities of one or more operators of an operating device. For example, some consumers can be turned on or off manually. In addition, the device load of a plurality of energy-converting elements of the operating devices depends on external factors. For example, the device load of an air conditioner or a Photovoltaic system depend on the weather. In the inventive process it is advantageous if the operating means is operated as possible so that the difference value is minimized and the operating device thus netzanschlusssei- tig behave as in the previously determined load profile angege ^¬ ben.

A strict minimize the difference value can to füh ^¬ ren that a facility can not fulfill completely their function and, for example, the production of an industrial plant decreases, can be made a room air conditioning incomplete or the like. At the same time in different operating situations the power supply system, a deviation from the load profile can reduce the efficiency of the power supply system strong and in other Betriebssi ^¬ situations have almost no influence on the efficiency of the power supply network. It is therefore advantageous if the information data record describes a difference information or a time profile of a difference information, wherein the difference information describes a relationship between the difference value and the target size, wherein the loading ^¬ drive device is controlled in dependence of the target size. In the context of the control can thus be taken into account how strongly a deviation from the load profile affects a target size to be optimized. For example, it can be ^¬ averages, how much a C02 emissions increases or inwie ^¬ far sinks share of renewable energy if the facility A ^{¬ ¬} direction load from differs from the load profile. The difference information can also be a price information, with the help of which the energy management device can calculate which costs cause a deviation from the load profile. The inventive method thus makes it possible to take into account ^¬ under the control of the operating device, the extent to which a deviation from the load profile economically and / or environmentally is appropriate in consideration with the information provided by the deviation from the load profile functionalities. The difference information can be any kind of relationship between the target size and the difference value describe, ie in particular a proportionality or ei ^¬ ne sections proportionality with a staggered proportionality factor. By the energy management device, a load adjustment request can be received from the server device, after which the load profile is adapted by the energy management device according to the load adjustment request. A load adjustment request can already be made before the start of the optimization interval and / or during the optimization interval. Load adjustment requests may be sent by the server device, for example, if energy provided and / or consumed in the entire power supply network deviates greatly from consumed and / or provided energy at the appropriate time, thus necessitating adjustments to the energy consumed and provided compensate. While it is typically possible to offset an imbalance between consumed and supplied energy via external energy markets, it can be economical

and / or ecologically more appropriate to adapt a load profile of one or more connected operating ^devices by means of a load adjustment ^request . It is possible for the operating parameter to be influenced by the energy management device as a function of at least one operating parameter influencing the device load of the operating device

and / or at least one of the setting load of the operation ^¬ means affecting property of the Betriebseinrich- tung a a time characteristic of a tolerance range of the device load determined in the optimization interval descriptive To ^¬ leranzprofil and is transmitted to the server device übertra ^¬ gene, after which the load adjustment request is determined such that the adjusted load profile is within the tolerance range. Many operating facilities can easily adjust a load profile in some operating situations without sacrificing functionality. For example, batteries may be provided in operating devices which can be used at short notice. can give or receive additional energy. Heating and cooling systems can also, in many applications, at least slightly shift heating and cooling intervals due to thermal inertia of systems, with which tolerances for the load profile can be provided. By providing a corresponding tolerance profile by the energy management system to the server device and a use of the respective tolerance profiles reasonable fit load matching requests to one or more energy management systems an especially ecological and econometric ^¬ mixer compensate for consumed and supplied energy in power supply networks can be achieved.

Advantageously, the energy management system information can be provided, how far it is ecologically and / or eco ^¬ nomic profitable, appropriate tolerances bereitzustel ^¬ len. Therefore, the information record may describe a tolerance information or time course of tolerance information at least, wherein the tolerance information describes a relationship between adjustments of the load profile due to possible load matching requests and the target value, wherein the tolerance profile is determined depending on the tole ^¬ ranzinformation. Tolerance information may in particular adjustments different relationships between the arrival and the target size for different matching ^¬ directions of the load profile, that is to a larger required by facility power or a lower power provided by the facility or vice versa, include. Tolerance information may be a proportional factor in particular, the proportionality factor for varying degrees of deviation may be different, so that a staggered proportio ^¬ ality is achieved. The information record can be a

Describe power maximum information that determines a relationship between the target size and the maximum of a given time interval, in particular the optimization tervall, provided by the operating device and / or claimed power describes, wherein the determination of the load profile and / or the control of the operating device in response to the power maximum information follows. High power peaks by a facility are typically particularly disadvantageous for effective operation of a power supply ^¬ network with the associated consumers. As a result, utilities may charge additional costs for peak power. It is thus advantageous if bereitge ^¬ provides information within the information record are the extent to which power peaks in the detected load profile or under the control affect the optimization of the target, that is in particular the extent to economic high power peaks and / or ecological disadvantages are caused.

The information data set may describe a reactive power information or a temporal course of the reactive power information, the reactive power information describing a relationship between a reactive power of the operating device and the target variable during the optimization ^interval , the determination of the load profile and / or the control of the operating device being dependent on the reactive power. power information takes place. Through reactive power, energy supply networks are additionally burdened. Depending Be ^¬ operating state of the power grid this Belas ^¬ tung may have different effects. It is therefore advantageous to take into account the severity of the impairment of the energy supply network by means of reactive power within the framework of the determination of the load profile and / or the control of the operating device.

At least during the optimization interval, a single orientation-load of the facility in question ^¬ capture data repeatedly by the energy management device ER- summarizes and provided to the server device. The server device will thus be given concrete data about the actual provided neaxial load profile of the operating device, which can be used in particular for billing and / or optimization purposes. Before step a), a configuration data set can be transmitted to the energy management system by the server device, whereafter the energy management system adapts the determination of the load profile and / or the determination of the tolerance profile and / or the control of the operating device as a function of the configuration data set. It is also possible to adjust distances between a determination of acquisition data or provision of this data. The configuration data set corresponds to the technical counterpart of a "contract", which defines the technical parameters of the data exchange between the energy management device and the server device It is possible for a corresponding configuration data record to be automatically or manually transferred from the specifications of a contract between an operator of the energy management system or ., the operating device and an operator of the power grid is derived.

The configuration data record may in particular include information relating to a validity period of the configuration data record. Additionally or alternatively, the configurations can rationsdatensatz least specify a time of the READY ^¬ development of the load profile with respect to the optimization interval and / or a length of the optimization interval. Also, a particular periodically repeating the start of an optimization interval, the length of an interval for the maximum power determining time points at which other prediction information for medium to long-term load professional ^¬ le are to be transmitted by the energy management, Messin ^¬ intervals for measurement data and / or data formats for by the information data record transmitted information and / or the load or tolerance profiles can be determined by the Konfigurationsda ^¬ cost rate. In addition to the method according to the invention, the invention relates to an energy management device for controlling an operating device connected to a power supply network, wherein the maximum claimed and / or provided power of the controlled operating device is at least 3 kW, wherein the energy management device is designed to carry out the method according to the invention. The Ener ^¬ giemanagementeinrichtung may comprise means for receiving information data, in particular, include cost information from a ger by a network operator or operated Energieversor- server device and means for transmitting a predicted load profile for the operating device to the server device. The means for transmitting and receiving may be provided together in the form of a communication nikationsmoduls that is both ei ^¬ genständige device (gateway) may be provided in a separate housing or integrated in, for example, a computing device of the power management device in particular. The communication module thus forms an interface that provides a communication option between the energy management device and the network operator / network provider, more precisely, the local server device. For this purpose, hardware and software means may be part of the communication module, which form the communication module for receiving the infor- mationsdatensatzes for providing or transmitting the load ^¬ profile and possibly the wide data exchange as described, in particular with respect to the configuration data set in Rah ^¬ men initialization, , In addition, the energy management device can have means for determining a load profile after step b) of the method according to the invention and

Having means for controlling the operating device after step d) of the method according to the invention.

The energy management ^device according to the invention can be part of an automation system for the operating ^device , but it is also possible that the energy management device is designed separately from an automation device and with this, for example via network-accessible functions, communicates. Functions for communication between the server device and the power management device may be an integral part of the power management device. However, it is also possible to configure the power management means so that a communication with the server means is provided by a separate module which, in ^¬ play, via a network connection, in particular via netzwerkaufrufbare functions, communicates with other components of the energy management device of the determination of the load profile and / or the control of the operating device serve. Features that have been explained for the method according to the invention are equivalent to the energy management device according to the invention transferable.

In addition, the invention relates to a computer program, where the computing device according to the invention forms an energy management ^¬ management device upon execution of the computer program on a computing device. For the method according to the invention or the energy management device explained features can be equivalently transferred to the inventive computer program with the advantages described therein.

Further features and details of the invention describe the following embodiments and the accompanying drawings. Showing:

Fig. 1 shows schematically the timing of a method according to the invention, and

Fig. 2 schematically shows an inventive energy management ^¬ ment means, as well as their connection to an operating device and a an energy supply network associated with the server device.

Fig. 1 shows schematically the timing of a method for operating an energy management device 1 for Control of an operating device, not shown, connected to a power supply network. The claimed

and / or provided power of the controlled operating device is at least 3 kW. In Fig. 1, a time sequence is shown schematically, wherein the left edge of the picture time ^¬ Lich early and late time sequences on the right side are shown. Are also schematically, the energy management ^¬ management device 1 associated with said power supply network and in particular by the operator of the energy supply network operated server device 2 and a time Leis ^¬ te 3 is shown. The arrows 4, 5, 6, 7, 8, 9 communications between the energy management ^¬ device 1 and the server device 2 are sorted ^¬ weils shown. In the area of the energy management device 1 and the server device 2, the time ranges 10, 11, 12 or 13, 14, 15 are respectively shown in which the energy management device 1 or the server device 2 perform essential functions for the method described. The procedure begins at time 16 with a through the

Arrow transmitting a configuration data set from the server device 2 4 shown to the energy management ^¬ device 1. The communication between the power management device 1 and the server device 2 takes place during this, and the communication processes described below, respectively by a call to netzwerkaufrufbaren functions that are called, for example, via SOAP ,

The transmission of a configuration data set from the server device 2 to the power management device 1 can be effected by the server device 2 calls a network-callable function of the power management device 1, to set appropriate configuration data to the entspre ^¬ sponding values. Alternatively, the power management device 1 could invoke a network-invokable function implemented by the server device 2 to retrieve the configuration record from the server device 2. Advantageously, both of the functions described are implemen- The method can normally be started by calling a network-invokable function of the energy management device 1 for setting the configuration data, in the case of data loss of the energy management device, for example during a restart

However, configuration data can be retrieved again from the server device 2. The further by the arrows 5, data transmissions illustrated 7 and 9 from the server device 2 to the power management device 1 also take place, so that for each transmitted data respectively erläu ^¬ failed pick-up or setting functions on the server device 2 or on the power management device 1 are implemented. A data transmission from the energy management device 1 to the server device 2, as represented by the arrows 6 and 8, is basically the same, in which case a setting function for setting the data on the server 2 side is implemented and a fetch function, when called Data are provided to the server device 2, is implemented on the power management device 1.

In particular, the configuration record specifies the times and time intervals that will be used in the further procedure. In particular, the configuration data set is technically relevant parameters of a contract between a loading ^¬ driver of the power management device 1 and the associated operating means and an operator of the power grid or a dealer that provides on the power supply network power to the operating device and / or decreases from this, from. By the server device 2, the data of the configuration data set in particular ^¬ sondere can be generated automatically from an electronically present contract record. The configuration data record comprises in particular a start and end time of the contract and a time interval within which a maximum of the power claimed by the operating device is to be determined in each case. By The configuration data set can be assigned to the energy management device a unique identification, which consists in particular of a contract ID and a device ID. As part of the configuration data set, data formats and the units assigned to the transferred numerical values can also be specified. Alternatively, the units assigned to the numerical values can also be transmitted in the context of the further communications represented by the arrows 5, 6, 7, 8, 9 in separate data fields.

Further data of the configuration data record can define a length of an optimization interval 17 and the relative position of the times 18, 19, 20, 21, 22, to which the data transmissions represented by the arrows 5, 6, 7, 8 between the energy management device 1 and the Server device 2 take place, or to which the optimization interval 17 begins. For example, the time 18 with respect to the time 22 and the time 9 with respect to the time 18 can be set, and so on. The position of the times 18, 19, 20, 21, 22 to each other is determined by a time interval to one of the other times.

In addition, are transmitted to the configuration data set interval lengths and points in time for transmitting a long-term and a short-term load profile, wherein the jewei ^¬ time intervals are longer than the optimization interval for example, a month for a short-term load profile and one or more years for a long-term load profile. The identification and transmission of the short and long-term load profiles is not shown. Short- and long-term load ^¬ profiles are determined at the points specified by the configuration record times by a statistical analysis of collected during operation of the facility operating data and trans- ferred to the server means. 2

The configuration data record also describes in what intervals a facility load of the operating facility detected capture data by the energy management device 1 and to be provided to the server device 2. The collection and supply the detection data is not shown in FIG. 1 and can continuously in the background, or even in the optimization interval SUC ^¬ gen.

The transmission of the configura ^¬ tion data set indicated by the arrow 4 has only once at the initialization of communication between the server device 2 and the

Energy management device 1 done. The method steps explained below can be repeated as often as desired after initial configuration of the energy management device 1 by receiving the configuration data record. For reasons of clarity, the preparatory data exchange before the optimization interval 17 at the times 18, 19, 20, 21 and the optimization interval 17 between the times 22 and 23 are shown separately in FIG. It should be noted, however, that even currency rend the optimization interval 17 would be made a corresponding vorbe ^¬ riding communications for a subsequent next Op ^¬ timierungsintervall which follows particular un ^¬ indirectly to the optimization interval 17, that begins at the time the 23rd

The further explanation of the method assumes that, as an objective to be optimized in the method of operating the Energiemana ^¬ ABERGEMENT device 1, a C02 emissions to be minimized. If an economic incentive is to be created for the operator of the energy management device or the operating device to contribute to increasing the overall efficiency of a power supply network, it would also be possible in an alternative embodiment of the method to minimize energy costs as a target variable The following explained information data set by the server device in particular takes place in such a way that a minimization of the costs for consumed energy or a maximization of the remuneration for the energy provided by The energy management facility is expected to increase the energy efficiency of the energy supply network, which, for example, indirectly also reduces CO ₂ emissions and / or promotes the use of renewable energies.

In the time interval 10, an information data record is determined by the server device 2, which is to be transmitted to the energy management system 1 at the time 18. The information record describes the time course of a

Coupling information describing a relationship between a load profile of the operating device and the target size to be optimized. In particular, the coupling information can describe a relationship between an energy consumption described by the load profile or an energy generation described by the load profile and the target variable. This can be for example a C0 ₂ emissions per MWh he ^¬ mounted or a C0 ₂ emissions per MWh. The information record additionally describes a time course of a difference information showing the relationship between a difference value that describes the difference between a predefined by the load profile for a current operation time ^¬ point in the optimization interval default value for the device load and a current actual value of the A ^¬ direction of the load, and the target size.

In addition, the information record describes the time course of a tolerance information that describes a relationship between adjustments of the load profile up and down due to possible load adjustment issues and the target size. An upward adjustment of the load profile is to be understood as an increase in the required power or a reduction in a provision of power, and an adjustment of the load profile downwards is the opposite.

In addition, the information record describes the time course of a reactive power information, the context between a reactive power of the operating device in the optimization interval and the target size describes. High ^reactive power of the operating equipment can reduce the achievable efficiency in the energy supply network and thus increase CO 2 emissions. In addition, they lead to additional costs for an energy supplier.

In addition, the information record comprises two

Maximum power information, each describing a relationship between a maximum of power consumed by the operating device in a given time interval and the target size. The default interval is Zeitin ^¬ for one of these two

 Power maximum information the time interval defined by the configuration record and for the other of the

Power maximum information the optimization interval 17.

In addition, the information data set describes an offset for the target variable, which becomes relevant in particular if the target variable is optimized as a function of further boundary conditions or as part of a multi-factor optimization.

The information described by the information record is determined by the server device 2 from statistical information of previous operating cycles and modeling of the power grid with the supplied by the Ener ^¬ gieversorgungsnetz operating facilities and by a forecast of loads occurring in the power grid loads.

In the time interval 13, a load profile is calculated by the energy management device 1 on the one hand, which describes a prog ^¬ nostizierten temporal course of the device load of the operating device during the optimization interval 17 and on the other hand, a tolerance profile that ^¬ a Tole ^¬ ranzbereich the device load in the optimization interval ^¬ writes, the can be used on a load adjustment question by the server ^device 2 in order to determine the load profile. to fit. The tolerance profile describes for each point of time separate deviation possibilities from the load profile upwards and downwards. The determination of the load profile is carried out by minimizing the target size under at least one boundary condition. In a use of C0 ₂ emissions ~ as a target thus the CO ₂ - minimizes emissions, at a use of any prize as a target ^¬ size of the price. The target quantity depends on the load profile to be determined as well as on the information transmitted with the information data set, namely in particular the coupling information, the power maximum information, the reactive power information and the offset for the target size. The coupling information and the reactive power information are, in particular, time-dependent weighting factors for the calculation of the target variable from the load profile or from an energy supply calculated from the load profile or an energy consumption calculated from the load profile. The tolerance profile is additionally determined as a function of the tolerance information. The boundary condition describes insbesonde ^¬ re requirements for the operation of the facility, for example a temperature interval in which an air-conditioned space is to be kept ^¬ ter or a minimum production quantity of an industrial plant.

Alternatively, the load profile could also be part of a

Multi-factor optimization can be determined, wherein in addition to the target size, another size is optimized. For example, the target size can be minimized while maximizing a size describing the production of an industrial plant. Multiple factor optimization can be combined with the use of boundary conditions.

To determine a tolerance interval, a

Multiple factor optimization performed. The tolerance information describes ecological and / or economic advantages that are achieved when the tolerance range is used in the context of a load adjustment. For example, the tol- ranzinformation a C02 ~ Saving or price savings in a load adjustment by the server device describe. As a further factor, at least one operating result of the operating device is evaluated. For example, a weighted sum of the product of the tolerance information and the deviation described in the tolerance profile and a production quantity of an industrial plant can be minimized or maximized. To determine the load profile and the tolerance profile, prognosis information can additionally be used, which can be determined, for example, by a statistical evaluation of preceding operating intervals of the operating device. The load profile and the determined tolerance determined are ranzprofil, as shown by arrow 6, is transmitted to the server device ^¬. 2

In the time interval 11, the server device 2 evaluates the transmitted via ^¬ load profile of the energy management device. 1 Other energy management devices, not shown, can also calculate load profiles and tolerance profiles and provide them to the server device 2. Depending on these data as well as further information which allows a prognosis of services or energies available in the energy supply network, the server device 2 checks whether information previously transmitted by the information data set has to be adapted, since forecasts of the provided or required services or services are available Have changed energies in the power grid due to the received information. If this is the case, then the information ^¬ data set is fitted and, as shown by arrow 7, is transmitted to the power management device 1, whereupon the latter described in the time interval 14, as to the time interval 13, calculates an updated load profile and / or an updated To- leranzprofil and at the time 21 to the Serverein ^¬ direction 2 provides. In the optimization interval 17 to control the loading ^¬ drive device by the power management device 1 in response to the previously transmitted to the server device 2 ^¬ th load profile and the difference information is carried out. In typical applications, the actual furnishings load ei ^¬ ner factory equipment often varies from a projected and transferred as load profile means loading. ^{By way of} example, the power of a photovoltaic or wind turbine can vary depending on the weather and / or individual elements of the operating device can have a device load that depends on manual operation. Is a difference value, which specifies the deviation between the predetermined by the load profile for the current operating time set value for the setting load and an instantaneous actual value of the device load, different from zero, the operating device is to be typically controlled such that the difference value is mini ^¬ mized , Strict minimization of the difference value is often not appropriate, however, since a corresponding adjustment of the device load can be detrimental to an operating result of the operating device. For example, a production of an industrial plant can be reduced or ^certain comfort features of a building can no longer be made available.

Therefore, it is advantageous to use a multi-factor optimization for controlling the operating device. As one of the optimization factors, in turn, the target ^quantity already explained is optimized, which can represent CO 2 consumption or energy costs. As a further optimization factor at least one operating parameter of the operating device, ie, for example, a production quantity or a deviation from a predetermined temperature is taken into account. In addition, boundary conditions can be specified. The operation of the operating device thus takes place in such a way that it weighs between an optimization of the target variable and operating requirements for the operating device. At least during the operation interval, detection data relating to the device load of the operating device is repeatedly transmitted to the power management device 1 by the power management device 1. A corresponding transmission also takes place by further energy management devices, not shown. In addition, the server device 2 may evaluate forecasts for parameters that affect a device load in the power grid, as explained for the time interval 10. Alternatively or additionally, the energy management device 1 can evaluate under which conditions energy can be bought or sold on electricity markets.

By evaluating this information, in particular by an optimization algorithm, it can be determined by the server device 2 in some operating situations that an adaptation of the services provided or required in the energy supply network is expedient. For example, if part of the energy provided in the energy supply network is provided by photovoltaic systems and during the initial determinations of the information data set in the time intervals 10 and 11, it was indicated by forecast data that a high solar energy supply by the photovoltaic systems is to be expected due to strong solar radiation Time interval 12 updated a corresponding forecast and it is now expected that the energy supply by the photovoltaic system is much lower, is expected to provide sufficient energy in the energy supply network.

Depending on a current cost and supply situation in an energy market, this lack of provided energy can be offset by purchasing energy from an energy market. Often, however, this is not ecologically and / or economically appropriate, so that it may be advantageous instead to adapt the load profile of the controlled by the energy management device 1 operating equipment. For this purpose, the provided from the power management device 1 to the server device 2 tolerance profile is ausgewer ^¬ tet, which describes the extent to which an adjustment of the load profile of the facility is possible. If the tolerance profile indicates, for a relevant period of time, that it is possible to adapt the load profile to reduce the power required by the operating device, the server device sends a load matching request to the energy management device 1 at time 24, as shown by the arrow 9, correspondingly the Lastanpassungsanfrage adapts the load profile and the further operation of the operating device in the optimization interval 17 in accordance with the adjusted load profile ^¬ leads.

By a corresponding load matching question, the load can be ^¬ profile adapted such that power consumption is lowered by the operation means and thus a ge ^¬ ringere energy available, for example Due to the mentioned lower than expected solar radiation is compensated to a photovoltaic system.

FIG. 2 schematically shows an energy management device 28 for controlling an operating device 25 connected to a not shown power supply network. The operating device 25 serves to operate a building 34. The operating device 25 comprises a plurality of consumers 26 and a photovoltaic system 35 controlled by an automation device 27 become. In order to increase the efficiency of the entire energy supply network with the operating device 25 connected thereto, the behavior of the operating device 25 at the network connection, that is to say its device load, is to be coordinated with a device assigned to the energy supply network, namely the server device 31. The server device 31 also communicates with other operating devices 33 and detects their device load, so that via the server device 31, the respective device load of the operating devices 33 and the operating device 25 can be coordinated to a certain extent. The server device 31 additionally communicates with a device 32 assigned to an energy market, in order to adapt the required or provided services in the energy supply network to conditions on the energy market and, in particular as a function of an energy price, to adapt an acquisition or sale of energy.

For the coordination of the AC power behavior of the operating device 25, the building 34 comprising the power management device 28 that a built in the power management device 28, communication module 29 via a network 30 such as the Internet or a VPN, with the Serve pure ^¬ direction 31 as to Fig. 1 explained communicates. The commu nication ^¬ between the power management device 28 and the automation device 27 or the server device 31 is carried out respectively by netzaufrufbare functions.

In alternative embodiments, it would be possible to integrate the energy management system 28 into the automation device 27 and / or form the communication module 29 separately from the energy management device 28, in which case communication between the communication module 29 and the energy management device 28 can also be via network-invoked functions.

Although the invention in detail by the preferred embodiment has been illustrated and described in detail, the invention is not limited ^¬ by the disclosed examples and other variations can be derived therefrom by the skilled artisan without departing from the scope of the invention.

Claims

claims

1. A method of operating an energy management device for controlling an operating device connected to a power supply network, wherein the maximum demanded and / or provided power of the controlled operating device is at least 3 kW, comprising the steps:

a. Receiving an information record describing coupling information or timing of the coupling information from a server device associated with a network operator of a power grid or utility, the coupling information determining a relationship between a device load caused by the device and a target to be optimized during a Optimization ^{interval describes} ,

b. Determining a load profile which describes a prognostic ^¬ timed course of the device load of Be ^¬ drive device during the optimization interval, by optimizing the load profile with respect to the

Target size by the energy management facility, c. Providing the load profile to the server device, and

d. Control of the operating device by the energy management device in the optimization interval as a function of a predetermined by the load profile for the current operating time default value for the A ^¬ direction load.

2. The method according to claim 1, characterized in that the steps a) to c) are performed at a predetermined time interval before the optimization interval.

3. The method of claim 1 or 2, characterized in that the steps a) to c) are performed several times at a plurality of temporally spaced points in time before the optimization interval.

4. The method according to any one of the preceding claims, characterized in that the operating device controlled by the energy management device in the optimization interval in response to a difference between the predetermined by the load profile for the current operating time default value for the device load and a current actual value of the device load indicating difference value becomes.

5. The method according to claim 4, characterized in that the information data set describes a difference information or a time profile of a difference information, wherein the difference information describes a relationship between the difference value and the target size, wherein the Be ^¬ drive device is controlled in dependence of the target size.

6. The method according to any one of the preceding claims, characterized in that a load adjustment request is received by the server device by the energy management device, after which the load profile is adjusted by the energy management device according to the load adjustment request.

7. The method according to claim 6, characterized in that by the energy management system in dependence on at least one the device load of the operating device influencing operating parameters and / or at least one Einrichtungslast the operating device influencing property of the operating device a temporal course of a tolerance range of the device load in the optimistic ^¬ tolerance interval describing tolerance profile is determined and transmitted to the server device, after which the load adjustment request is determined such that the adjusted load ^¬ profile is within the tolerance range.

8. The method according to claim 7, characterized in that the information data set at least one tolerance information or a time course of the tolerance information The tolerance information describes a correlation between adaptations of the load profile on the basis of possible load adjustment requests and the target variable, the tolerance profile being determined as a function of the tolerance information.

9. The method according to any one of the preceding claims, characterized in that the information data set a

Describes power maximum information that describes a relationship between the target size and the maximum power provided and / or claimed by the operating device in a predetermined time interval, in particular the optimization interval, the determination of the load profile and / or the control of the operating device Dependence of the power maximum information takes place.

10. The method according to any one of the preceding claims, characterized in that the information data set describes a reactive power information or a time course of the reactive power information, wherein the reactive power information describes a relationship between a reactive power of the operating device and the target size during the Optimie ^¬ ing interval, wherein the determination of the load profile and / or the control of the operating device as a function of the reactive power information.

11. The method according to any one of the preceding claims, characterized in that Subject Author ^¬ Fende detection data is repeatedly acquired by the energy management ^¬ device and provided to the server device at least during the Optimierungsinter- Valls means load of the operating means.

12. The method according to any one of the preceding claims, characterized in that prior to step a) by the Servereinrich ^¬ tion a configuration data set is transmitted to the energy management device, after which the energy management system the determination of the load profile and / or the determination of the tolerance profile and / or the control of the operating device as a function of the configuration data set adapts.

13. The method according to claim 12, characterized in that is determined by the configuration data set at least a time of deployment of the load profile with respect to the optimization interval and / or a length of the optimization Inter ^¬ Valls.

14. Energy management device for controlling a connected to a power grid operating device (25), wherein the maximum claimed and / or provided power of the controlled operating device (25) at least

3 kW, characterized in that it is for carrying out the method according to one of the preceding claims out ^¬ forms.

15. Computer program, characterized in that formed at from ^¬ management of the computer program on a computing device, the computing device an energy management device (1, 28) according to claim. 13