阅读说明：本技术 用于能源网的改善的利用率的方法 (Method for improved utilization of an energy grid ) 是由 佩尔·罗森 于 2018-12-20 设计创作，主要内容包括：提出了一种局部供热系统。该局部供热系统包括：第一热源(10),其可连接到供热网(110),并且被布置为从供热网(110)提取热；第二热源(20),其可连接到电能网(120),并且将通过电能网(120)供给的电能转换为热量；发热装置(30)；分配系统(40),其用于使传热流体在发热装置(30)与第一热源和第二热源(10、20)之间循环；以及控制器(50),其被配置为分别控制第一热源和第二热源(10、20)的从供热网(110)和电能网(120)的相对热量输出。(A local heating system is presented. This local heating system includes: a first heat source (10) connectable to a heating network (110) and arranged to extract heat from the heating network (110); a second heat source (20) connectable to the electrical energy grid (120) and converting electrical energy supplied through the electrical energy grid (120) into heat; a heat generating device (30); a distribution system (40) for circulating a heat transfer fluid between the heat generating device (30) and the first and second heat sources (10, 20); and a controller (50) configured to control the relative heat output from the heating and electrical networks (110, 120) of the first and second heat sources (10, 20), respectively.)

1. A method for controlling a primary local heating system, the primary local heating system comprising: a first heat source (10) connected to a heating network (110); a second heat source (20) connected to the electrical grid (120); one or more heat generating devices (30) for providing comfortable heating; and a distribution system (40) for circulating a heat transfer fluid between the one or more heat generating devices (30) and the first and second heat sources (10, 20), the method comprising:

(S202) determining a time-resolved heating control parameter indicative of time-resolved total heating consumption demands of a plurality of local heating systems related to a time-resolved total available heating capacity of the heating network (110), the plurality of local heating systems being connected to the heating network (110),

(S204) determining a time-resolved electric power control parameter indicative of a time-resolved total electric power demand related to a time-resolved total available electric power of the electric power grid (120), the electric power grid (120) being connected to the second heat source (20), and

(S206) controlling the relative heat output from the first and second heat sources (10, 20) based on the comparison of the time-resolved heating control parameter and the time-resolved electric power control parameter such that the product of the time-resolved heating control parameter and the heat output from the first heat source (10) plus the product of the time-resolved electric power control parameter and the heat output from the second heat source (20) is minimized.

2. The method according to claim 1, wherein the time-resolved heating control parameters comprise information on greenhouse gas emissions per unit of heat provided via the heating network (110).

3. The method according to claim 1 or 2, wherein the time-resolved heating control parameter comprises information about the efficiency of the first heat source (10) of a heat transfer fluid capable of transferring heat from the heating network (110) to the distribution system (40).

4. The method according to any of claims 1-3, wherein the time-resolved heating control parameter comprises information on the cost per unit of heat provided via the heating network (110).

5. The method according to any one of claims 1-4, wherein the time-resolved electric power control parameter comprises information related to greenhouse gas emissions per unit of electric energy of the electric power grid (120).

6. The method according to any one of claims 1-5, wherein the time-resolved electrical power control parameter comprises information related to an efficiency of the second heat source (20) capable of converting electrical energy from the electrical power grid (120) into heat in a heat transfer fluid of the distribution system (40).

7. The method according to any one of claims 1-6, wherein the time-resolved electrical power control parameter comprises information related to a cost per unit of electrical energy of the electrical power grid (120).

8. The method according to any one of claims 1-7, wherein the first heat source (10) is a heat exchanger or a heat pump connected to the heat supply network (110).

9. The method according to any one of claims 1-8, wherein the second heat source (20) is an electrical resistance heater.

10. A local heating system comprising:

a first heat source (10) connectable to a heating network (110) and arranged to extract heat from the heating network (110);

a second heat source (20) connectable to an electric power grid (120) and converting electric energy supplied through the electric power grid (120) into heat;

a heat generating device (30);

a distribution system (40) for circulating a heat transfer fluid between the heat generating device (30) and the first and second heat sources (10, 20); and

a controller (50) configured to control the relative heat outputs from the heating network (110) and the electrical energy network (120) of the first and second heat sources (10, 20), respectively.

11. A local heating system according to claim 10, wherein the controller (50) is configured to control based on a comparison of a time-resolved heating control parameter and a time-resolved electric power control parameter, wherein the time-resolved heating control parameter is indicative of a time-resolved total heating consumption demand of a plurality of local heating systems related to a time-resolved total available heating capacity of the heating network (110), the plurality of local heating systems being connected to the heating network (110), and wherein the time-resolved electric power control parameter is indicative of a time-resolved total electric power demand related to a time-resolved total available electric power of the electric power network (120).

12. A district heating system according to claim 11, wherein the controller (50) is further configured to control the relative heat output from the first and second heat sources (10, 20) such that the product of the time-resolved heating control parameter and the heat output from the first heat source (10) plus the product of the time-resolved electric power control parameter and the heat output from the second heat source (20) is minimized.

13. A local heating system according to any one of claims 10-12, wherein the second heat source (20) is arranged in the distribution system (40).

14. A local heating system according to any one of claims 10-13, wherein the second heat source (20) is an electrical resistance heater.

15. A district heating system according to any of claims 10-14, wherein said first heat source (10) is a heat exchanger or a heat pump.

16. A controller configured to control relative heat output from a first heat source (10) connected to a heating network (110) and a second heat source (20) connected to an electrical energy network (120), the first and second heat sources belonging to a district heating system (1);

wherein the controller (50) is configured to control the relative heat output from the first heat source (10) and the second heat source (20) such that the product of a time-resolved heating control parameter and the heat output from the first heat source (10) plus the product of a time-resolved electric power control parameter and the heat output from the second heat source (20) is minimized,

wherein the time-resolved heating control parameter is indicative of a time-resolved total heating consumption demand of a plurality of local heating systems in relation to a time-resolved total available heating capacity of the heating network (110), the plurality of local heating systems being connected to the heating network (110),

wherein the time-resolved electric power control parameter is indicative of a time-resolved total electric power demand related to a time-resolved total available electric power of the electric power grid (120), the electric power grid (120) being connected to the second heat source (20).

17. The controller of claim 16, further configured to locally determine the time-resolved heating control parameter and/or the time-resolved electrical power control parameter.

18. The controller of claim 16 or 17, further configured to control the heat output from the heating network (110) of the first heat source (10) by controlling a control valve (12).

Technical Field

The invention relates to a method of controlling a district heating system comprising a first heat source connected to a heating network and a second heat source connected to an electric energy network.

Background

Almost all large developed cities in the world have at least two types of energy distribution networks contained in their infrastructure: one for heating and one for supplying power. A net for heating may for example be used for providing comfort and/or industrial heat and/or hot tap water preparation. The power supply network may be used to supply power to home appliances, electric vehicles, lighting devices, and the like.

A common network for heating is a gas supply network that provides combustible gas, typically fossil fuel gas. The gas supplied by the gas supply network is burned locally in the building to provide comfort and/or industrial heat and/or hot tap water preparation. An alternative network for heating is the district heating network. District heating networks are used to provide heated heat transfer liquid, usually in the form of water, to buildings in cities. A centrally located heat supply and pumping apparatus is used to heat and dispense the heat transfer liquid. The heat transfer liquid is delivered to the buildings of the city via one or more supply pipes and returned to the heating and pumping equipment via one or more return pipes. Locally in the building, heat from the heat transfer liquid is extracted via a heat exchanger to a local heating system. Further alternatively, the electrical energy of the electrical energy network may be used for heating. The electrical energy may for example be used for heating tap water or for heating local heat transfer liquids for comfort and/or industrial heat.

The use of energy for heating is steadily increasing, with negative environmental impact. By improving the utilization of the energy distributed in the energy distribution network, the negative impact on the environment can be reduced. Therefore, there is a need to improve the utilization of the energy distributed in an energy distribution network.

Disclosure of Invention

The object of the present invention is to alleviate the above mentioned drawbacks by improving the utilization of multiple energy networks.

According to a first aspect, the object has been achieved by a method for controlling a primary district heating system. The primary local heating system comprises: a first heat source connectable to a heating network; a second heat source connectable to an electrical grid; one or more heat generating devices for providing comfortable heating; and a distribution system for circulating a heat transfer fluid between the one or more heat generating devices and the first and second heat sources. In operation of the method, the first heat source is connected to a heating network and the second heat source is connected to an electrical energy network. The method comprises determining a time-resolved heating control parameter (temporal resolved heating control parameter) indicative of a time-resolved total heating consumption demand (temporal resolved heating consumption communicated) of a plurality of local heating systems in relation to a time-resolved total available heating capacity of the heating network, the plurality of local heating systems being connected to the heating network. The method also includes determining a time-resolved electric power control parameter (temporal resolved electric power control parameter) indicative of a time-resolved total electric power demand (temporal resolved electric power) related to a time-resolved total available electric power of the electrical power grid to which the second heat source is connected. In addition, the method includes controlling relative heat output (heat) from the first and second heat sources based on a comparison of the time-resolved heating control parameter and the time-resolved electrical power control parameter. Controlling the relative output such that the product of a time-resolved heating control parameter and the heat output (out of heat) from the first heat source plus the product of the time-resolved electric power control parameter and the heat output from the second heat source is minimized.

Time-resolved total heating consumption demand can be predicted by collecting historical data from attributes of heat consumed. This historical data may be attributed to temporal data, such as the time of day and the day of the year. The historical data may be further attributed to weather data such as wind attributes, rainfall, snowfall, outdoor temperature, outdoor humidity, and the like. A time-resolved total heating consumption demand can then be predicted from this historical data, time data and/or weather forecast data. In addition, data relating to different properties of the consumed heat may be used in order to predict a time-resolved total heating consumption demand.

Time-resolved total electrical power demand can be predicted by collecting historical data from electrical consumers. This historical data may be attributed to temporal data, such as the time of day and the day of the year. The historical data may be further attributed to weather data such as wind attributes, rainfall, snowfall, outdoor temperature, outdoor humidity, and the like. Time-resolved total electrical power demand can then be predicted from the historical data, time data, and/or weather forecast data.

Each of the plurality of local heating systems comprises: a heat source connectable to a heating network; one or more heat generating devices for providing comfortable heating; and a distribution system for circulating a heat transfer fluid between the one or more heat generating devices and a heat source. The plurality of local heating systems may comprise a primary local heating system.

It will be appreciated that the energy input, transfer efficiency and/or capacity of the heating and electrical power networks, respectively, varies over time.

For example, the temporal variation of the total available electrical power of the electrical power grid may be due to the temporary use of additional energy production equipment and/or due to the use of power plants whose production varies over time, such as solar power generation, wind power generation and/or tidal power generation. The use of power plants whose production varies with time will certainly increase in the future. In addition, the variation may be due to a variation in the water level in the reservoir of the hydropower station. Furthermore, the total available electrical power may vary due to damage to the electrical energy grid or the shutting down of the power plant supplying the electrical energy grid.

Similarly, the total available heating capacity of the heating network may vary over time. This is due to the temporary use of additional energy production equipment for supplying power to the heating network, to the increased availability of geothermal energy for supplying power to the heating network, or to the excess of material for combustion in the combustion power plant used for supplying power to the heating network. Furthermore, the total available heating capacity of the heating network may vary over time due to damage to the heating network or the shutting down of one or more power plants supplying power to the heating network.

The total heating consumption demand may vary over time. Factors that affect the overall heating consumption demand include cold outdoor temperature, wind conditions, occupancy of the building where the local heating system delivers comfortable heating, radiation from the sun, time of day, days of week and/or time of year. For example, during periods of no wind and/or relatively high outdoor temperatures, the total heating consumption requirements may be reduced. According to another example, the total heating consumption demand may be reduced during weekends when certain office buildings are controlled to a lower indoor temperature. According to yet another example, the total heating consumption demand may be increased during periods of windy conditions and/or relatively low outdoor temperatures.

The total electrical power demand may vary over time. Factors that affect the total electrical power demand include outdoor temperature, wind conditions, occupancy of the building in which the electrical power grid delivers electrical power, radiation from the sun, time of day, days of the week, and/or time of year.

The time-resolved heating control parameter may indicate a time-resolved relationship between supply and demand of heating energy, giving a "virtual cost" of a heating network consuming a certain capacity.

The time-resolved electrical power control parameter may indicate a time-resolved relationship between supply and demand for electrical power, giving a "virtual cost" of consuming a capacity of the electrical power grid.

The heating control parameter and the electric power control parameter may be normalized to a common scale. Therefore, they can be more easily compared with each other.

By introducing the heating control parameter and the electric power control parameter and determining their values, and then controlling the relative heat output from the first and second heat sources based on these values, an imbalance between the total demand compared to the total available capacity/power can be compensated. For example, if there is a relatively high total demand in the total heating consumption demand, it may be beneficial to control the relative heat output from the first and second heat sources such that heat is drawn primarily or entirely from the second heat source connected to the electrical power grid. On the other hand, if there is a relatively high total demand in the total electric power demand, for example, it may be beneficial to control the relative heat output from the first and second heat sources such that heat is drawn primarily or entirely from the second heat source connected to the electric power grid.

In addition to the pure overall demand versus available capacity relationship, the heating control parameter and the electric power control parameter may also be used to take into account other factors. These parameters may also take into account the environmental impact of generating thermal and electrical energy. These parameters may also take into account predictions. If the total heating demand reaches a critical point where another heating apparatus almost needs to be started, the heating control parameter may be determined and then set to indicate an even larger total heating consumption demand than the actual situation, thereby directing the output of heat such that mainly the second heat source connected to the electric heating network is used. Thus, the need for heating capacity from the heating network may be reduced, hopefully avoiding the activation of additional heat generating equipment configured to input heat to the heating network.

The heating control parameter and the electric power control parameter may be expressed as a price per unit energy. These control parameters may be expressed as numerical index values having no direct relation to energy.

By the method, the energy output between the heat supply network and the electric energy network can be dynamically adjusted. Thus, an output from the energy distribution grid can be made that currently proves to be the most efficient use of the energy of the resource. This may enable a reduction of environmental impact. For example, energy may be taken from only the electrical energy grid or only the heat supply grid or partially from both grids in different proportions. Thus, the output may depend on what is optimal at the current time period.

According to one example, the relative output may be optimized such that the product of the time-resolved heating control parameter and the heat output from the first heat source plus the product of the time-resolved electric power control parameter and the heat output from the second heat source is minimized. In this context, minimization is not limited to a practical minimum of function relative to the output. A value close enough to the actual minimum value is sufficient. For example, within 20% of the actual minimum. Preferably within 10% of the actual minimum.

If the environment is such that the capacity of the heating network in relation to the current heat demand is limited or insufficient, this will be a specific situation in which only the electric energy network for heating is used. Alternatively, energy may only be taken from the heating network if the environment is such that the production capacity of the electrical power network in relation to the present demand for electricity in the entire electrical power network is very limited.

Furthermore, by providing the above method in a plurality of primary local heating systems connected to the same heating and power grid, respectively, a greater number of local heating systems can be connected to a grid of a specific capacity to allow for greater variation in the heating demand of different users, allowing for more intermittent production of thermal and/or electrical energy.

The time-resolved heating control parameter may comprise information about greenhouse gas emissions per unit of heat provided via the heating network. Also by using information about the amount of greenhouse gas emissions per unit of heat provided via the heating network, the relative heat output from the heating network of the district heating system can be controlled, so that, for example, the greenhouse gas emissions are reduced by taking this heat when the resource producing less greenhouse gas produces heat.

The time-resolved heating control parameter may include information related to an efficiency of a first heat source capable of transferring heat from the heating network to a heat transfer fluid of the distribution system. By also utilizing information about the efficiency of the first heat source, which is capable of transferring heat from the heating network to the heat transfer fluid of the distribution system, the energy efficiency output or heat can be further improved, whereby the environmental impact can be reduced.

The time-resolved heating control parameter may comprise information about the cost per unit of heat provided via the heating network. Also by utilizing information about the cost per unit of heat provided via the heating network, the cost of using each heat source can be more easily compared, so that the cost can be more easily used to control the relative output of heat.

The time-resolved electric power control parameter may comprise information related to greenhouse gas emissions per unit of electric energy of the electric power grid. By also utilizing information about greenhouse gas emissions per unit of electrical energy of the electrical power network, the relative heat output from the electrical power network of the local heating system can be controlled, such that, for example, greenhouse gas emissions are mitigated by capturing such heat energy at the time of electrical power production from a resource that produces less greenhouse gas.

The time-resolved electrical power control parameter may include information related to an efficiency of a second heat source capable of converting electrical energy from an electrical power grid to heat in a heat transfer fluid of the distribution system.

The time-resolved electric power control parameter may comprise information about the cost per unit of electric energy of the electric energy grid, and by also using the information about the cost per unit of electric energy of the electric energy grid, the cost of using electricity for heating can be more easily compared, so that the cost can be more easily used for controlling the relative output of heat.

The first heat source may be a heat exchanger or a heat pump connected to the heating network.

The second heat source may be an electrical resistance heater.

According to a second aspect, the above object(s) has/have been achieved by a local heating system. The local heating system includes: a first heat source connectable to a heating network and arranged to extract heat from the heating network; a second heat source connectable to an electric power grid and converting electric power supplied through the electric power grid into heat; a heat generating device; a distribution system for circulating a heat transfer fluid between the heat generating device and the first and second heat sources; and a controller configured to control the relative heat outputs from the heating and electrical power grids of the first and second heat sources, respectively.

The controller may be configured to control based on a comparison of a time-resolved heating control parameter and a time-resolved electric power control parameter, wherein the time-resolved heating control parameter is indicative of a time-resolved total heating consumption demand of a plurality of local heating systems related to a time-resolved total available heating capacity of the heating network to which the plurality of local heating systems are connected, and wherein the time-resolved electric power control parameter is indicative of a time-resolved total electric power demand related to a time-resolved total available electric power of the electric power network.

The controller is further configured to control the relative heat output from the first and second heat sources such that the product of the time-resolved heating control parameter and the heat output from the first heat source plus the product of the time-resolved electric power control parameter and the heat output from the second heat source is minimized.

According to one example, the relative output may be optimized such that a product of the time-resolved heating control parameter and the heat output from the first heat source plus a product of the time-resolved electric power control parameter and the heat output from the second heat source is minimized. In this context, minimization is not limited to a practical minimum of function relative to the output. A value close enough to the actual minimum value is sufficient. For example, within 20% of the actual minimum. Preferably within 10% of the actual minimum.

The second heat source may be disposed in the distribution system.

The second heat source may be a resistive heater.

The first heat source may be a heat exchanger or a heat pump.

The above-described features of the method apply also to this second aspect, where applicable. To avoid unnecessary repetition, please refer to the above.

According to a third aspect, the above object(s) has/have been achieved by a controller. The controller is configured to control a relative heat output from a first heat source connected to the heating network and a second heat source connected to the electrical energy network, the first and second heat sources belonging to a local heating system. The controller is further configured to control the relative heat output from the first and second heat sources such that the product of the time-resolved heating control parameter and the heat output from the first heat source plus the product of the time-resolved electric power control parameter and the heat output from the second heat source is minimized. The time-resolved heating control parameter is indicative of a time-resolved total heating consumption demand of a plurality of local heating systems in relation to a time-resolved total available heating capacity of the heating network to which the plurality of local heating systems are connected. The time-resolved electrical power control parameter is indicative of a time-resolved total electrical power demand related to a time-resolved total available electrical power of an electrical power grid to which the second heat source is connected.

The controller is further configured to locally determine a time-resolved heating control parameter and/or a time-resolved electric power control parameter.

The controller may accordingly be further configured to control the heat output of the first heat source from the heating network by controlling the control valve.

The above-mentioned features of the method and the local heating system apply, where applicable, also to this third aspect. To avoid unnecessary repetition, please refer to the above.

Further scope of applicability of the present invention will become apparent from the detailed description given hereinafter. It should be understood, however, that the detailed description and the specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the scope of the invention will become apparent to those skilled in the art from this detailed description.

It is to be understood, therefore, that this invention is not limited to the particular components of the devices described, or to the steps of the methods described, as such devices and methods may vary. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting. It must be noted that, as used in the specification and the appended claims, the articles "a," "an," "the," and "said" are intended to mean that there are one or more of the elements, unless the context clearly dictates otherwise. Thus, for example, reference to a "unit" or "the unit" may include several means or the like. Furthermore, the words "comprising", "including" and similar referents do not exclude other elements or steps.

Drawings

The above and other aspects of the invention will now be described in more detail, with reference to the appended drawings showing embodiments of the invention. The drawings should not be taken to limit the invention to the specific embodiments, but are for explanation and understanding of the invention.

As shown in the drawings, the sizes of layers and regions are exaggerated for illustrative purposes, and thus, the drawings are provided to show a general structure of an embodiment of the present invention.

Fig. 1 is a schematic view of a district heating system comprising a first heat source and a second heat source.

Fig. 2 is a block diagram of a method 200 for controlling relative heat output from a first heat source and a second heat source of the local heating system of fig. 1.

Detailed Description

The present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which a presently preferred embodiment of the invention is shown. This invention may, however, be embodied in different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.

Referring to fig. 1, a district heating system 1 will be discussed. The local heating system 1 comprises a first heat source 10, a second heat source 20, a heat generating device 30 and a distribution system 40 for circulating a heat transfer fluid between the heat generating device 30 and the first and second heat sources 10, 20.

The first heat source 10 is connected to the heating network 110. The heating network 110 is configured to distribute heat to the first heat source 10.

The heating network 110 may be a district heating system. The district heating system comprises a hydraulic network comprising a district supply conduit for an inflow of the district heat transfer fluid and a district return conduit for a return flow of the district heat transfer fluid. In district heating systems, the driving pressure difference between the district supply and return conduits of the hydraulic network creates a so-called "pressure cone", whereby the pressure in the district supply conduit is higher than the pressure in the return conduit. The pressure differential causes a district heat transfer fluid in the hydraulic network to circulate between a central heat-generating device connected to the district heating system and the local heating system. In addition, one or more district network circulation pumps are arranged in the district heating system in order to provide a driving pressure difference. In case the heating network 100 is a district heating system, the first heat source 10 is a heat exchanger. Again, this is the embodiment shown in fig. 1.

Alternatively, the heating network 110 may be a district thermal energy distribution system as defined in WO 2017/076868. In this case, the first heat source 10 is a thermal energy consuming heat exchanger as defined in WO2017/076868 and/or WO 2017/076866.

Further alternatively, the heating network 110 may be a gas distribution network configured to distribute combustible gas. In this case, the first heat source 10 is a gas burner.

The distribution system 40 includes a supply line 42 and a return line 44. The dispensing system 40 may also include a circulation pump 46. The first heat source 10 is fluidly connected to a supply line 42 and a return line 44 for flowing a heat transfer fluid from the return line 44 into the supply line 42 via the first heat source 10. When doing so, the first heat source 10 is configured to heat a heat transfer fluid flowing through the distribution system 40 of the first heat source 10. Thus, the first heat source 10 is configured to transfer heat from the heating network 110 to the heat transfer fluid of the distribution system 40.

The second heat source 20 is connected to an electrical grid 120. The second heat source 20 is typically a resistive heater. The second heat source 20 is disposed in the distribution system 40. Preferably, the second heat source 20 is arranged on the supply line 42.

The heat generating device 30 is configured to provide comfortable heating. The heat generating device 30 may be a radiator. The local heating system 1 may comprise a plurality of heat generating devices 30. The heat generating device 30 is configured to radiate heat to its surroundings. Generally, the heat generating device 30 is disposed in a room of a building.

The first heat source 10 may transfer heat from the heat transfer fluid of the heating network 110 to the heat transfer fluid in the distribution system 40 of the district heating system 1. In this manner, heat can be generated remotely in a large-scale heat-producing device (not shown) and dissipated locally away from the device. For example, these devices may use geothermal energy or energy from other processes, such as the combustion of household waste. The generated heat is then distributed through the heating network 110 to a plurality of local heating systems where the heat is taken away by heat sources connected to the heating network 110.

In addition to using heat from the first heat source 10, or instead of using heat from the first heat source 10, heat may be locally generated in the local heating system 1 using the second heat source 20 by supplying electricity from the electrical energy grid 120 to the second heat source 20 which will then heat the heat transfer fluid of the distribution system 40 of the local heating system 1.

Since the electrical power grid 120 operates differently from the heating grid 110, the negative effects of a defect or failure of the heating grid 110 or the electrical power grid 120 can be mitigated by increasing the utilization of the other respective heat sources 10, 20. The decision as to which heat source to use and to what extent may be controlled locally at each local heating system 1 or centrally by a controller connected to each respective local heating system 1 connected to the heating network 110 and/or the electrical energy network 120.

The local heating system may further comprise a controller 50 configured to control the heat output of the first and second heat sources 10, 20. The controller 50 is configured to control the relative heat output from the heating and electrical power networks 110, 120 of the first and second heat sources 10, 20 respectively. Relative control does not mean that the first heat source 10 and the second heat source 20 must be used one at a time; rather, they may be used one at a time or simultaneously, and to varying degrees from the relative energy output of each heat source 10, 20.

The controller 50 is configured to control the relative heat output from the first and second heat sources 10, 20. The controller 50 is configured to control based on a comparison of the time-resolved heating control parameter and the time-resolved electric power control parameter. The time-resolved heating control parameter is indicative of a time-resolved total heating consumption demand of a plurality of local heating systems connected to the heating network 110 in relation to a time-resolved total available heating capacity of the heating network 110. The controller 50 may be configured to locally determine time-resolved heating control parameters. Alternatively, the controller 50 may be provided with time-resolved heating control parameters from a central server (not shown) configured to determine the time-resolved heating control parameters. The time-resolved electric power control parameter is indicative of a time-resolved total electric power demand related to a time-resolved total available electric power of the electric power grid 120. The controller 50 may be configured to locally determine time-resolved electrical power control parameters. Alternatively, the controller 50 may be provided with time-resolved electric power control parameters from a central server (not shown) configured to determine the time-resolved electric power control parameters.

The controller 50 is further configured to control the relative heat output from the first and second heat sources 10, 20 such that the product of the time-resolved heating control parameter and the heat output from the first heat source plus the product of the time-resolved electric power control parameter and the heat output from the second heat source is optimized. According to one example, the relative output may be optimized such that a product of the time-resolved heating control parameter and the output of heat from the first heat source plus a product of the time-resolved electrical power control parameter and the output of heat from the second heat source is minimized. In this context, minimization is not limited to a practical minimum of function relative to the output. A value close enough to the actual minimum value is sufficient. For example, within 20% of the actual minimum. Preferably within 10% of the actual minimum.

The heat output of the first heat source 10 from the heating network 110 can be controlled by controlling the control valve 12. The flow of heat transfer fluid of the heating network into the first heat source 10 is controlled by controlling the control valve 12. The controller 50 may be configured to control the control valve 12. The control valve 12 may in the embodiment shown in fig. 1 be positioned at a return line arranged to return heat transfer fluid from the first heat source 10 to the heating network. For example, the setting may be used where the heating network 110 is a network configured to heat a thermal transfer fluid in a network configured to transfer heat. Alternatively, the control valve 12 may be positioned at a supply line arranged to supply heat transfer fluid from the heating network 110 to the first heat source 10. This setting may be used, for example, if the heating network 110 is a network providing combustible gas and the first heat source 10 is a gas burner.

Accordingly, control of the relative output of heat from the first and second heat sources 10, 20 may be based on data analysis. Alternatively, control of the relative output of heat from the first and second heat sources 10, 20 may be based on data analysis combined with manual decision making and override.

Referring to fig. 2, a method 200 for controlling the relative output of heat from the first and second heat sources 10, 20 of the district heating system 1 according to the above will be discussed. The method 200 comprises S202 determining a time-resolved heating control parameter indicative of a time-resolved total heating consumption demand of a plurality of local heating systems related to a time-resolved total available heating capacity of the heating network, the plurality of local heating systems being connected to the heating network. The time-resolved total heating consumption demand of the plurality of local heating systems may comprise information about how much energy is required for heating the plurality of local heating systems during the predetermined period of time. This may be based on historical data, but also on predictions. For example, the time-resolved total available heating capacity of the heating network may be determined based on historical data, but also based on predictions (such as based on weather forecasts). Local sensors for each local heating system may be used to report local weather data (such as outdoor temperature, wind, and outdoor humidity) which may then be used to help determine time-resolved total or local heating consumption requirements.

The method 200 further includes S204 determining a time-resolved electric power control parameter indicative of a time-resolved total electric power demand with respect to a time-resolved total available electric power of an electrical power grid to which the second heat source is connected.

Additionally, the method 200 includes S206 controlling relative heat output from the first heat source and the second heat source based on a comparison of the time-resolved heating control parameter and the time-resolved electrical power control parameter. The output is controlled such that the product of the time-resolved heating control parameter and the heat output from the first heat source plus the product of the time-resolved electric power control parameter and the heat output from the second heat source is optimized. According to one example, the relative output may be optimized such that a product of the time-resolved heating control parameter and the heat output from the first heat source plus a product of the time-resolved electric power control parameter and the heat output from the second heat source is minimized. In this context, minimization is not limited to a practical minimum of function relative to the output. A value close enough to the actual minimum value is sufficient. For example, within 20% of the actual minimum. Preferably within 10% of the actual minimum.

The predetermined time period for the time analysis depends on the condition of each energy distribution network, such as the resolution and delay of data collected from local heating systems, heat production plants or power plants. For example, the predetermined period of time may be 1 hour, 2 hours, 6 hours, or 24 hours. Other time periods are also possible within the scope of the present disclosure.

The total available heating capacity is related to all generated heating, i.e. the consumed heating is not taken into account. Similarly, the total available electrical power is related to all generated electrical power, i.e. without regard to the consumed electrical power.

The time-resolved heating control parameter may comprise information about greenhouse gas emissions per unit of heat provided via the heating network.

The time-resolved heating control parameter may include information related to an efficiency of a first heat source capable of transferring heat from the heating network to a heat transfer fluid of the distribution system.

The time-resolved heating control parameter may comprise information about the cost per unit of heat provided via the heating network.

The time-resolved electric power control parameter may include information related to greenhouse gas emissions per unit of electric energy of the electric power grid.

The time-resolved electrical power control parameter may include information related to an efficiency of a second heat source capable of converting electrical energy from an electrical power grid to heat in a heat transfer fluid of the distribution system.

The time-resolved electrical power control parameter may include information related to the cost per unit of electrical energy of the electrical power grid.

The person skilled in the art realizes that the present invention by no means is limited to the preferred embodiments described above. On the contrary, many modifications and variations are possible within the scope of the appended claims.

For example, the controller 50 may be implemented in many different forms. According to one example, the controller 50 may be a single controller configured to control both the first heat source 10 and the second heat source 20. According to another example, the controller 50 may be a distributed controller including two or more controller modules. For example, a first controller module may be configured to control the first heat source 10 and a second controller module may be configured to control the second heat source 20. The first controller module and the second controller module are configured to communicate with each other and exchange data. The communication may be wired or wireless.

In addition, variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed invention, from a study of the drawings, the disclosure, and the appended claims.