WO2021204439A1 - Method for controlling a heat network, control unit and heat exchange system - Google Patents

Abstract

What is proposed is a method for controlling a heat network to which one or more heat consumers and/or one or more heat generators are connected, and for which heat network provision is made for a defined operating schedule at least within a time interval, having the following steps: - (S1) ascertaining a differential amount of heat within the heat network through measured values in relation to the defined operating schedule; - (S2) transmitting the differential amount of heat to a local energy market platform; - (S3a) determining the heat consumers and a compensation amount of heat to be consumed, this being associated with the respective determined heat consumer and intended to compensate the differential amount of heat, by way of the local energy market platform; and/or - (S3b) determining the heat generators and a compensation amount of heat to be provided, this being associated with the respective determined heat generator and intended to compensate the differential amount of heat, by way of the local energy market platform; and (S4) - transmitting a data signal from the local energy market platform to the heat consumers and/or heat generators determined for compensating the differential amount of heat, wherein the data signal triggers the consumption and/or the provision of the determined respective compensation amount of heat. The invention furthermore relates to a control unit and to a heat exchange system.

Description

description

Method for controlling a heating network, control unit and heat exchange system

The invention relates to a method for controlling a heating network according to the preamble of claim 1, a control unit for controlling a heating network according to the preamble of claim 14 and a heat exchange system according to the preamble of claim 15.

Within network-based energy supply systems, in particular in distribution networks, problems can arise due to a deviation from a forecast in the sense of an operating schedule. In particular, a deviation from planned generation, consumption and storage is possible so that, for example, there is insufficient generation and thus the planned consumption cannot be covered.

For electrical distribution networks, so-called control power / reserve power is held or called up to solve the above-mentioned problem.

For heating networks, such as local heating networks or district heating networks, attempts are made to remedy the problem mentioned by measures that are not very efficient at the moment, or such problems are completely ignored. There is no known coordinated procedure for solving such problems for heating networks.

Particularly with regard to a local trade in heat, a technical solution to the problem mentioned for heat networks is desirable.

The present invention is based on the object of providing and using reserve power or reserve heat for a heating network. The object is achieved by a method with the features of independent claim 1, by a control unit with the features of independent claim 14 and by a heat exchange system with the features of independent claim 15. In the dependent patent claims, advantageous configurations and developments of the invention are given.

The method according to the invention for controlling a heating network, to which one or more heat consumers and / or one or more heat generators are connected, and for which heating network a specified operating schedule is provided at least within a time range, is characterized at least by the following steps:

- Determination of a differential amount of heat within the heating network by means of measured values with regard to the established operating schedule;

- Transmission of the differential heat quantity to a local energy market platform;

- Determination of the heat consumer and an associated heat consumer to be consumed to be consumed, which is provided to compensate for the differential amount of heat, by the local energy market platform; and or

- Determination of the heat generator and an associated heat generator to be provided to be provided from the same amount of heat, which is provided to compensate for the differential amount of heat, by the local energy market platform; and

- Transmission of a data signal from the local energy market platform to the heat consumers and / or certain heat generators intended to compensate for the difference in heat, the data signal triggering the consumption and / or the provision of the respective amount of equalization heat.

The method according to the invention and / or one or more functions, features and / or steps of the method according to the invention can be computer-aided. In the present case, the term control includes regulation.

Heat consumption is any type of consumption of heat from the heating network, in particular heat storage by means of a thermal energy store, for example by means of a heat store.

Heat supply is any type of feed of heat into the heating network, in particular by generating heat and / or feeding in from a thermal energy store, for example from a heat store.

A heat consumer is in particular an energy system that has a heat consumption, for example a building, a residential building, an office building and / or an industrial plant.

A heat generator is in particular an energy system that has a heat supply, for example a building, a residential building, an office building and / or an industrial plant.

The heating network is preferably a local heating network and / or a district heating network.

The heat consumers and / or the heat generators are connected to the heat network for heat exchange, typically via a heat exchanger that enables a respective heat output (heat consumption) and / or a respective heat feed from or into the heat network. The heat consumers and / or heat generators thus form the connection participants of the heating network.

A difference in heat quantity is characterized, for example, by a deviation from required and / or permissible temperatures and / or heat deficits compared to the heat quantities planned according to the operating schedule. Such a deviation can be described as a problem within the heating network. A differential heat quantity is characterized in particular by a lack of heat consumption or by a lack of heat generation.

A compensation amount of heat is provided to compensate for the amount of differential heat if this at least partially contributes to the compensation, typically to reducing the amount of differential heat.

According to the present invention, there is a difference between planned heat consumption and / or planned heat provision within the time range and within the heating network. The planning is determined by the operating schedule of the heating network, which is typically established, determined or calculated in advance of the time range mentioned. Such an operating schedule thus forms a forecast with regard to the operation of the heating network for the time range mentioned.

The difference or the difference between planning, which is formed by the operating schedule, and the actual state of the heating network typically represents a technical problem that is at least partially solved or eliminated by the present invention.

For this purpose, the differential amount of heat is determined in a first step. The differential amount of heat is the amount of heat that is missing with regard to the operating schedule to cover the heat load, i.e. to cover the heat consumption, or which has been provided, in particular generated, too much with regard to the operating schedule. In other words, the determined differential heat quantity indicates a heat deficit or a heat surplus within the heating network. In this case, the heat deficit or the heat surplus can only be present locally in part of the heating network (subnetwork or subnetwork). The entire heating network does not have to be affected. The differential amount of heat is determined based on measured values, for example a temperature. In order to determine the differential amount of heat, it is particularly sufficient to determine a temperature difference with respect to a planned operating temperature, possibly in an area or a point of the heating network, and the measured temperature. In other words, temperature and heat can be viewed as equivalent in the present case. Furthermore, heat consumed or provided within the time range corresponds to an associated heat output within the time range, so that heat or heat quantity and heat output are also equivalent in the present case.

The determined differential heat quantity, which marks a problem within the heating network, is transmitted to the local energy market platform. In particular, the local energy market platform is designed as a local heat market platform that enables an exchange between locally consumed and locally generated heat. For the local exchange of electrical energy, such a local energy market platform is known, for example, from document EP 3518369 A1.

Through the local energy market platform, the heat consumers and heat generators (energy systems) can exchange and trade locally generated energy, in particular thermal energy or additional electrical energy (electricity). Thanks to its decentralized technical design, the local energy market platform enables the locally generated heat to be efficiently coordinated with the local heat consumption. The local energy market platform is therefore particularly advantageous with regard to renewable energies, which are typically obtained locally.

In a further step or in further steps of the method according to the invention, those heat consumers and those A certain amount of heat is determined, including the associated heat quantities, which use or provide a respective amount of equalization heat to compensate for the difference in heat. In other words, the heat consumers and / or heat generators contributing to the reserve power / reserve heat are determined by the local energy market platform. For example, for this purpose, each heat consumer and / or each heat generator transmits a balance heat quantity in the form of an offer to the local energy market platform, which brings the offers into agreement, typically based on an optimization (market algorithm), whereby the contributing heat consumers and / or heat generators and their respective associated Equalization heat quantity can be determined.

After the contributing heat consumers and / or heat generators have been determined by the local energy market platform, the local energy market platform transmits a data signal to the contributing, i.e. specific heat consumers or heat generators, which is designed in such a way that the specific compensation heat quantity is consumed or provided. By means of the data signal, for example, the heat consumer and / or heat generator are switched on, switched on, switched off and / or changed in their operation, the actual direct operational control of the systems here being the respective heat consumer / heat generator and / or an energy management system of the respective heat consumer chers / heat generator can be left. The data signal of the local energy market platform only forms the trigger for the operational processes mentioned, which then ultimately lead to heat exchange, that is to say to consumption and / or to the provision of the respective balance heat quantity. In particular, the data signal is a price signal, that is to say a data signal which characterizes a cost-effective provision and / or a cost-effective consumption. The problem within the heating network is advantageously reduced and, at best, solved by the amounts of equalization heat. The method of the present invention is possible because heating networks, in contrast to electrical networks, are sluggish. As a result, the equalization heat quantities, which in total correspond to a reserve heat quantity and act analogously to the reserve energy in electrical networks, can be determined and made available in real time. The present invention uses precisely this inertia of heating networks and thus forms the technical basis for real-time trading of reserves within a thermal network. As a result, the present invention forms an advantageous addition to day-ahead trading for heat, which is preferably likewise provided or carried out by the local energy market platform.

Another advantage of the present invention is that no control power or control energy (reserve heat quantity) has to be kept available in advance of a problem. However, problems can advantageously be responded to efficiently at short notice. Overall, this advantageously improves the energetic efficiency of the heating network. Furthermore, technical and ecological problems within heating networks can advantageously be improved or avoided.

By means of the present invention, forecast deviations / planning deviations or even short-term problems within the heating network can thus be improved or mitigated or eliminated as efficiently as possible. For this we ken the inertia of the heating network and the determination of the equilibrium heat quantities by the local energy market platform in an advantageous way synergistically together.

The control unit according to the invention for controlling a heating network is characterized in that it is designed to carry out a method according to claims 2 to 13. Similar and equivalent advantages and configurations result for the method according to the invention.

The heat exchange system according to the invention comprises one or more heat consumers and / or one or more heat generators, a heating network, the heat consumers and / or the heat generators being connected to the heating network, a control unit and a local energy market platform. The heat exchange system according to the invention is characterized in that the heat consumers and / or the heat generators, the control unit and the local energy market platform are designed to carry out a method according to claims 2 to 13.

Similar and equivalent advantages and configurations result for the method according to the invention.

According to an advantageous embodiment of the invention, the heating network is controlled by a central control unit with regard to the heat consumers and / or heat generators, with the central control unit determining the difference in heat and transmitting the determined difference in heat to the local energy market platform.

In other words, the heating network is controlled in a centralized manner by the control unit. Such a central control unit is typically operated by an operator of the heating network, for example a local heating supplier and / or a district heating supplier. Such a heating network operator advantageously already has the technical systems, for example measuring devices, in order to determine a problem within the heating network, for example a temperature drifting away within part of the heating network, and to determine the associated differential amount of heat. The control unit can be designed to process the measured values. The control unit then gives this information information / data / measured values - collected, so to speak, with regard to the subscribers of the heating network - to the local energy market platform.

In an advantageous development of the invention, the determination of the differential amount of heat and the transmission of the determined differential amount of heat to the local energy market platform are carried out by at least one of the heat consumers and / or by at least one of the heat generators.

In other words, the determination and transmission of the differential amount of heat to the local energy market platform takes place alternatively or in addition directly by the subscribers to the heating network. Advantageously, the heat consumers and / or heat generators can determine a problem within the heating network, in particular in the area of their connection point to the heating network, by independently determining the difference in heat. Some of the subscribers could communicate directly with the local energy market platform via the control unit and some of the subscribers could communicate directly with the local energy market platform.

According to an advantageous embodiment of the invention, in order to determine the contributing heat consumers through the local energy market platform, each heat consumer transmits a maximum amount of heat that can be consumed by it within the time range to the local energy market platform.

As a result, a technically feasible offer from the respective heat consumer is advantageously transmitted to the local energy market platform. This offer advantageously takes into account the technical framework conditions of the respective heat consumers. This advantageously ensures that the balancing heat quantities determined by the local energy market platform can be technically implemented by the respective specific heat consumers. In an advantageous development of the invention, to determine the contributing heat generator by the local energy market platform, each heat generator transmits a minimum amount of heat that can be provided by this within the time range to the local energy market platform.

As a result, a technically feasible offer from the respective heat generator is advantageously transmitted to the local energy market platform. This offer advantageously takes into account the technical framework conditions of the respective heat generator. This advantageously ensures that the balancing heat quantities determined by the local energy market platform can be technically implemented by the respective specific heat generators.

According to an advantageous embodiment of the invention, the maximum amount of heat that can be consumed and / or the minimum amount of heat that can be provided is determined by an energy management system of the respective heat consumer or the respective heat generator and transmitted to the local energy market platform.

In other words, at least some of the heat consumers and / or at least some of the heat generators have an energy management system. The energy management system is designed at least to control the internal operation, in particular with regard to heat consumption and heat generation, of the respective heat consumer or heat generator. The respective energy management system is designed to exchange data / information with the local energy market platform, for example via the Internet and / or cloud-based.

It is particularly preferred here if the energy management system optimizes the respective operation of the heat consumer or of the respective operation of the heat generator for the determination. As a result, the problem within the heating network can advantageously be resolved as efficiently as possible, with the heat consumers and / or heat generators participating in the equalization heat quantity symbolically optimizing themselves. For this purpose, short-term predictions for heat loads, heat generation, heat storage and the like can be taken into account and transmitted to the local energy market platform in the form of an offer.

In an advantageous development of the invention, when determining the contributing heat consumers and / or heat generators, a respective specific carbon dioxide emissions value, a respective value of the primary energy input and / or a respective remuneration of the heat consumers and / or heat generators by the local energy market platform is taken into account.

Here, the specified characteristics, such as the specific carbon dioxide emission value, primary energy use and / or remuneration, are transmitted by the respective heat consumer or heat generator to the control unit or directly to the local energy market platform. As a result, further technically sensible criteria, such as the lowest possible carbon dioxide emissions and / or the most cost-effective possible solution to the problem, can advantageously be taken into account. In particular, this ensures that no emission limit values are exceeded for the amount of compensation heat. For example, a heat generator must shut down its gas boiler generation and ramp up its heat pump generation accordingly.

According to an advantageous embodiment of the invention, to determine the differential amount of heat

- Measured values relating to a temperature drift of the heating network with respect to the specified operating schedule, in particular within a part of the heating network; - Measured values relating to temperature, in particular flow temperature and / or return temperature, amount of heat, heat output of the heat consumers and / or heat generators; and or

- Measured values with regard to storage states of thermal energy storage, in particular of heat storage; used.

This advantageously improves the determination of the difference in the amount of heat. Overall, a problem within the heating network can advantageously be determined by the measures / measured values mentioned.

It is also advantageous if the differential heat quantity is determined by comparing the measured values with historical measured values, with defined threshold values and / or with mathematical models and / or simulations.

This advantageously further improves the determination of the difference in the amount of heat. The better the differential heat quantity and thus the condition of the heating network can be recorded, the more efficiently the countermeasures can be determined in the form of the compensatory heat quantities.

In an advantageous development of the invention, the data signal is transmitted to the contributing heat consumers and / or contributing to the heat generator via the central control unit of the Wärmenet zes.

In other words, the local energy market platform first transmits the contributing heat consumers and / or the contributing heat generators as well as the associated compensatory heat quantities to the central control platform, which then informs the contributing heat consumers or heat consumers and thus triggers a corresponding heat consumption and / or a corresponding heat supply. Before geous enough, a centralized coordination of the elimination of the problem with respect to the heating network is made possible. According to an advantageous embodiment of the invention, after the consumption and / or generation of the respective compensation heat quantity, a measured value-based determination takes place as to whether the operation of the heating network is in accordance with the operating schedule.

This advantageously ensures the success of the measure, that is to say that the heating network can then be operated according to the operating schedule. If a problem persists during this check, the procedure can be carried out again according to the present invention and / or one of its refinements. Alternatively or in addition, the local energy market platform could control the heat consumption of the heat consumers and / or the heat generation of the heat generators directly until the problem is essentially completely eliminated.

In an advantageous development of the invention, those heat consumers and / or those heat generators are determined by the control unit which are the cause of the difference in heat quantity with respect to the specified operating schedule of the heating network.

As a result, future problems can advantageously be reduced, mitigated and / or avoided.

Furthermore, the contributing heat consumers and / or heat generators are remunerated for their contribution (heat consumption or heat generation) to solving the problem, in particular based on the transferred fees, for example marginal prices. It is provided that the causing heat consumers and / or causing heat generators bear the corresponding fee.

Further advantages, features and details of the invention he will play from the Ausführungsbei described below and based on the drawing. It shows the only one FIG. 1 shows a flow chart of a method according to an embodiment of the present invention.

Identical, equivalent or equivalent elements can be provided with the same reference symbols in the figure.

The subject of the exemplary embodiment is a heating network with several connection participants, that is to say with several heat consumers and heat generators. For example, a local heating network or district heating network that supplies several residential buildings with heat. The residential buildings are heat consumers and can, for example, also feed heat into the heating network, in particular by means of a heat pump, that is to say provide or generate it. The residential buildings can also have one or more heat accumulators. Thus, an energy system, in the present case the residential buildings, can form a heat consumer and a heat generator.

Furthermore, the subscribers to the heating network can exchange information / data via a central control unit or directly with a local energy market platform, which coordinates the exchange of heat via the heating network and enables heat trading between the subscribers. In other words, the connection participants are also participants in the local energy market platform.

In a first step S1 of the method, a differential amount of heat within the heating network is determined by means of measured values in relation to the established operating schedule.

In other words, there is a problem within the heating network, in particular special within a sub-area of the heating network, that is, a deviation from the established operating schedule. This problem is technically characterized by determining the difference in heat. In a second step S2 of the method, the differential amount of heat is transmitted to the local energy market platform.

This can be done by the heat consumers or heat generators directly or via the central control unit. This means that the local energy market platform is aware of the differential heat quantity.

In a first, third step S3a of the method, the heat consumers and an amount of compensation heat to be consumed belonging to the particular heat consumer, which is provided to compensate for the differential amount of heat, are determined by the local energy market platform.

This can take place particularly preferably based on offers from the heat consumers to the local energy market platform.

In a second, third step S3b of the method, the heat generator and a corresponding to the respective specific heat generator to be provided de compensation heat quantity, which is intended to compensate for the difference heat memenge, determined by the local energy market platform alternatively or in addition.

This can take place particularly preferably based on offers from the heat consumers to the local energy market platform.

The third steps S3a and S3b can take place in parallel, so that the determination of the heat generator and heat consumer takes place essentially at the same time. By means of an optimization, the steps S3a and S3b are typically carried out in a common step, that is to say by solving the optimization problem. This is carried out by the local energy market platform. In a fourth step S4 of the method, a data signal is transmitted from the local energy market platform to the heat consumers and / or certain heat generators intended to compensate for the differential heat quantity, the data signal triggering the consumption and / or the provision of the specific respective compensatory heat quantity.

This will alleviate the problem within the heating network and, at best, eliminate it. The transmission can take place via the central control unit.

The described method or the method according to the present invention thus utilizes the inertia of the heating network in a targeted and advantageous manner in order to technically enable real-time trading of reserve heat or compensation heat for a heating network.

Although the invention has been illustrated and described in more detail by the preferred exemplary embodiments, the invention is not restricted by the examples disclosed, or other variations can be derived therefrom by the person skilled in the art without departing from the scope of protection of the invention.

List of reference symbols

51 first step

52 second step S3a first third step

S3b second third step

S4 fourth step

Claims

Claims

1. A method for controlling a heating network to which one or more heat consumers and / or one or more heat generators are connected, and for which heating network, at least within a time range, a specified operating schedule is provided, characterized by the steps:

- (Sl) Determination of a differential amount of heat within the heating network by means of measured values with respect to the established operating timetable;

- (S2) transmission of the differential amount of heat to a local energy market platform;

- (S3a) Determination of the heat consumers and a corresponding to the particular heat consumer associated to be consumed compensation heat, which is provided to compensate for the differential amount of heat, by the local energy market platform; and or

- (S3b) Determination of the heat generator and a corresponding to the respective specific heat generator to be provided compensation amount of heat, which is provided to compensate for the differential amount of heat, by the local energy market platform; and

- (S4) Transmission of a data signal from the local energy market platform to the heat consumers and / or certain heat generators intended to compensate for the differential heat quantity, the data signal triggering the consumption and / or the provision of the specific respective compensation heat quantity.

2. The method according to claim 1, characterized in that the heating network is controlled by a central control unit with regard to the heat consumers and / or heat generators, the determination of the differential amount of heat and the transmission of the determined differential amount of heat to the local energy market platform being carried out by the central control unit.

3. The method according to claim 1 or 2, characterized in that the determination of the differential amount of heat and the transfer of the determined differential amount of heat to the local energy market platform is carried out by at least one of the heat consumers and / or by at least one of the heat generators.

4. The method according to any one of the preceding claims, characterized in that in order to determine the contributing heat consumers by the local energy market platform, each heat consumer transmits a maximum amount of heat that can be consumed by this within the time range to the local energy market platform.

5. The method according to any one of the preceding claims, characterized in that to determine the contributing heat generator by the local energy market platform, each heat generator transmits a minimum amount of heat that can be provided by this within the time range to the local energy market platform.

6. The method according to claim 4 or 5, characterized in that the maximum consumable amount of heat and / or the minimum amount of heat that can be provided is determined by an energy management system of the respective heat consumer or the respective heat generator and transmitted to the local energy market platform.

7. The method according to claim 6, characterized in that the energy management system performs an optimization of the respective operation of the heat consumer or se of the respective heat generator to determine.

8. The method according to any one of the preceding claims, characterized in that when determining the contributing heat consumers and / or heat generators, a respective specific carbon dioxide emission value, a respective value of the primary energy input and / or a respective fee the heat consumer and / or heat generator is taken into account by the local energy market platform.

9. The method according to any one of the preceding claims, characterized in that to determine the differential heat amount

- Measured values relating to a temperature drift of the heating network with respect to the specified operating schedule, in particular within a part of the heating network;

- Measured values with regard to temperature, in particular flow temperature and / or return temperature, amount of heat, heat output of the heat consumers and / or heat generators; and or

- Measured values with regard to storage states of thermal energy storage, in particular of heat storage; can be used.

10. The method according to claim 9, characterized in that the differential amount of heat is determined by comparing the measured values with historical measured values, with defined threshold values and / or with mathematical models and / or simulations.

11. The method according to any one of claims 2 to 10, characterized in that the data signal is transmitted via the central control unit of the heating network to the contributing heat consumers and / or contributing heat generators.

12. The method according to any one of the preceding claims, characterized in that after the consumption and / or the generation of the respective amount of compensation heat, a measurement-based determination takes place as to whether the operation of the heating network is in accordance with the operating schedule.

13. The method according to any one of claims 2 to 12, characterized in that those heat consumers and / or those heat generators determined by the control unit which are the cause of the differential heat quantity with regard to the specified operating schedule of the heating network.

14. Control unit for controlling a heating network, characterized in that it is designed to carry out a method according to claims 2 to 13.

15. Heat exchange system, comprising one or more heat consumers and / or one or more heat generators, a heat network, wherein the heat consumers and / or the heat generators are connected to the heat network, a control unit and a local energy market platform, characterized in that the Heat consumers and / or the heat generators, the control unit and the local energy market platform are designed to carry out a method according to claims 2 to 13.