EP2837077A1 - Power control - Google Patents

Abstract

The invention relates to a power allocation method which already in the procurement of electricity takes account of network congestion and simultaneously enables logical and physical separation of network control and power allocation. This is achieved in that an allocation component and a network monitoring component separately from one another detect tasks relating to the allocation of power and via predetermined interfaces exchange information or intermediate states relating to the allocation before the allocation is actually implemented for power control. This enables adaptive power control of power sources and consumer units and the flexible implementation of a plurality of requirements of a modern power distribution network.

Description

description

Energy control The invention relates to a method and devices for energy control and to a corresponding system. The invention enables efficient allocation of electrical energy. The increasing feed-in of regenerative fluctuating energies at the distribution grid level can lead to network bottlenecks that can only be compensated for by a significant expansion of the grid infrastructure or by maintaining high balancing energy levels. Both the network expansion and the Provision of balancing power would be extremely expensive, contrary to the host ^{¬-scientific} and sustainable operation of renewable energy.

The liberalization of the electricity markets requires a decoupling of the various roles in the electricity market. Thus, functionalities for grid operation are provided separately from power generation and delivery by various actors. Ins ^¬ particular is hampered by a statutory separation of network operation and electricity supply optimal Netzfüh- tion with maximum economic efficiency. For example, the distribution system operator takes care of the line restrictions in the distribution network (eg by load reduction in an emergency), but has no influence on the allocation of energy in the electricity markets.

In order to facilitate a smooth integration of fluctuating feed-in at the distribution grid level, local electricity markets can be introduced to ensure an efficient allocation of feed-in and consumption rights. While capacity constraints receive a lot of attention at the transmission grid level, approaches to distribution grids assume that sufficient network capacity exists or a network management takes place through control energy use during operation.

An explicit trade in power transmission rights is well-known: in addition to the market-based coordination of the allocation of power, transmission rights are explicitly acquired, ie the free capacities of the transmission lines are sold on a second market. An implicit consideration of transmission line capacities in the allocation is also known (pool-based electricity markets, zone-based pricing): In such a market model, the transmission network limits are already taken into account when allocating allocations in the electricity market. This can be done for the entire network area (nodal pricing) or for individual homogenous network areas that are abstracted as copper plates (zonal pricing). Be ^¬ dingung here is that the electricity market operator and the transmission system operator one and the same actors are and can combine information from both areas. This approach is used inter alia in the USA (PJM Interconnection, ERCOT, New York, New England) and in New Zealand.

However, such allocation methods can not easily be used in the distribution network area because

- no market-based allocation has yet been made in the distribution network (the allocation is coordinated by means of long-term generation ^plans and load profiles);

- in the distribution network no player has a complete knowledge of the network topology and utilization and refreshes ^¬ economic allocation needs of producers and consumers;

- In the transmission network, unlike in the distribution network, short-term changes in supply and demand play no or only a subordinate role and thus remain largely unconsidered; In contrast to the distribution network, the transmission network is typically relatively easily divided into separate zones, whereas distribution networks are more closely meshed and it is difficult to divide them into independent zones.

Basically, there is the problem that in distribution networks a strict separation of network control component and market ^¬ component should be complied with. This makes existing purchase rates for distribution unfit as central regulatory requirements are not met, but also complete coverage of areas with respect. Mains control and market access ^¬ permanence must be provided. The object of the invention is to avoid the above disadvantages and in particular ge ^¬ called provide an effi cient ^¬ solution to a power allocation method for a distribution network. This object is achieved according to the features of the independent claims. Preferred embodiments are insbesonde ^¬ re the dependent claims.

To solve the problem, a method for energy control is proposed,

 in which an allocation of the electrical energy is determined by an allocation component based on bids,

 - in which the allocation of a network monitoring component is provided,

- is checked at the network monitoring component is a Mach ^¬ bility of allocation,

 - where the network monitoring component provides an audited allocation of the allocation component based on the feasibility of the allocation,

- where energy control is initiated based on the audited allocation. The solution presented here is applicable to differing ^¬ che energy networks, such as power grids, heating networks or gas networks.

The components mentioned here may be hardware or software units. In particular, the components can be located in the form of programs in different or in a common hardware. It is also possible for each of the components mentioned to be implemented in one or more physical units; For example, the components may be partially or fully distributed out ^¬ supplies its corresponding communication links and to exchange data with each other () have. For example, the components may exchange data over a communications network, such as the Internet. These statements for the components also apply to the agents explained below. Such an agent is, for example, a process or a component, in particular a software program that runs on a hardware or is executable.

It is presented thus an energy allocation procedure that eg supply bottlenecks be taken into ^¬ already in electricity procurement, while providing logical and physical separation of network control and energy allocation. The approach presented meets in particular the following requirements:

 - Rewarding short term reactions to changes in terms of

 - supply and demand and / or

 - Network topology

 - Preference for allocations that allow an improvement in network utilization

- transparency of the allocation process (this should mög ^¬ lichst undesirable strategic behavior be prevented)

- Applicability of the allocation procedure for the TOTAL ^¬ th grid area (eg is to avoid breakdown into homogeneous regions) - Support for continuous allocation method: Preferably, each time (or nearly ever ^¬ currently) purchase or sale requests should be processed without collecting it and then work off together at some point

 - Compliance with regulatory requirements for the separation of grid operation and energy supply

A further development is that the bids include at least one buy bid and / or at least one sell bid.

Another development is that the feasibility of the allocation will be reviewed by the Netzüberwa ^¬ monitoring component, by a validation of acquired line capacity, especially based is performed on ei ^¬ ner power flow calculation of the network monitoring component.

In particular, it is a further development that the Zutei ^¬ development component ermit- the allocation of electric energy telt is based on the statutes and based on Minim ^¬ least one of the following factors, which are determined by the network monitoring component:

 a power flow calculation,

 - available capacities,

 - Power transfer distribution factors.

Also, it is a continuing education that

- based on the checked allocation energy ^¬ control is caused by checking of the allocation component, a condition whether the ge ^¬ considered allocation of network monitoring component of the allocation of the allocation component corresponds to and / or the capacity of the network is not compromised,

- where the audited allocation is taken over by the allotment component, if the condition applies to ^¬ - where the allocation is made if the condition does not apply.

The allocation can be adjusted by the allocation component, whereby the network monitoring component can again check whether the adapted allocation complies with predetermined parameters (eg network capacity, etc.). So ^¬ with the method can be performed iteratively until you find a suitable allocation.

Furthermore, it is a development that at least one bid is provided by at least one agent.

The agent is e.g. a component for which the above statements also apply with regard to possible exemplary implementations.

As part of an additional development, the agent determines an allocation requirement for at least one locally connected device.

A next development is that is performed by the agent, the power control of the at least one locally ^¬ closed device.

The locally connected device may be an energy generator (eg a wind turbine, a solar system, a power plant, etc.), energy storage (eg a battery, a pumped storage, etc.) or a consumer. In particular, the connected device may be partially act as energy ^¬ supplier and partly as a consumer (eg in Fal ^¬ le an energy store, the load in a first operating mode from the power grid, and in a second operating mode providing the power supply line voltage).

One embodiment is that the power control is performed based on an arbitration notification provided by the arbitration component. Such an allocation notification can be evaluated and implemented by the agent accordingly. An additional embodiment is that

- is provided to ^¬ distribution of grant component of the network monitoring component tested,

- based on the audited allocation, an adjustment of the allocation in the allocation component is performed.

An alternative embodiment is that

- is from the network monitoring component Examined provided to ^¬ distribution of the allocation component - is performed based on the audited allocation adjustment of allocation in the network monitoring component.

It should be noted that the steps of the method can be carried out in principle in any order.

The above object is also achieved by means of unit ei ^¬ ner apparatus for power control to a processing which is set up such that

 an allocation of the electrical energy can be determined based on bids of at least one agent,

 - the allocation of a network monitoring component is preparable,

- a checked by the network monitoring component can be received to ^¬ division,

- Based on the audited allocation an energy ^¬ control is ^veranladbar .

In particular, the device is a distribution ^component . Furthermore, the above object is achieved by means of a device for energy control with a processing unit which is set up such that

 - an allocation of an allocation component is receivable,

 - a feasibility of the allocation is verifiable,

- on the feasibility of allocating a ge ^¬ considered allocation of grant component is be ^¬ reitstellbar based, wherein based on the audited allocating an energy control is veranlassbar.

For example, the device is a network monitoring component. Furthermore, a system for power control is proposed for achieving the above object

 - with an allocation component based on which an allocation of the electrical energy can be determined,

- with a network monitoring component, which is the Zutei ^¬ lung providable, wherein the network monitoring component, a feasibility of the allocation is prüf ^¬ bar and wherein the network monitoring component an approved allocation of the allocation component can be provided,

 - based on the allocation being audited, a

 Energy control is veranlassbar.

A further development is that the system comprises at least one agent, wherein at least one bid on the Minim ^¬ least providable an agent.

The statements made above regarding the method also apply correspondingly to the devices and the system.

The presented solution further comprises a Computerpro ^¬ program product which results, directly in a digital memory Computer is loadable, comprising program code parts which are adapted to perform steps of the method described herein.

Furthermore, the above problem is solved by means of a computer-readable storage medium, e.g. any memory comprising computer-executable instructions (e.g., in the form of program code) adapted for the computer to perform steps of the method described herein.

The above-described characteristics, features and advantages of this invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following schematic description of exemplary embodiments, which will be explained in more detail in connection with the drawing.

It shows:

Fig.l is a schematic flow diagram of a Energiezutei ^¬ development method, divided into the components agents, allocation component and network monitoring component.

Subsequently, the components are by way of example of a described Ener ^¬ giezuteilungsverfahrens (in the context of a method for Ener ^¬ giesteuerung), are taken into account by means of which already at the current procurement network bottlenecks and allows logical and physical separation of network ^¬ control and energy allocation simultaneously.

(a) An agent ( "Personal Energy Agent") is a component that takes for a network connection in the distribution functions of information collection, processing and -weitergäbe regarding energy allocation and exchange of information with the allocation component reali ^¬ Siert. It does not have to be represented by an agent every junction in the United ^¬ subnet. Of the Agent determines the allocation requirement for locally managed devices and controls them according to the allocation result.

(b) an allocation component ( "balancing master") coordi ^¬ ned supply the Energieerzeu by market-based method and energy extraction within the distribution network. The agents share the allocation component with their energy requirements or the planned energy production along with an appreciation or cost. Preferably, the allocation component receives (only) information from an ^{access point} which is also provided with an agent.

(c) A network monitoring component ("Network Transport

 Agent ") monitors a network state, aggregates (e.g., available) measurements and network parameters, and estimates the current network state or load of network resources, and, in particular, checks the allocation component allocations for network edge constraints.

(d) A Network Control Component (Area Administrator)

intervenes as soon as a critical network condition is reached. Possible actions include a load shedding, an increase / decrease of the power supply, a switching on / off of producers, a supply of reactive power, or a change in the network topology, the network control component is optional, as it performs in particular ^¬ sondere a downstream monitoring of Netzrandbe ^¬ conditions. The transport capacity-based allocation takes place, for example, in a higher-level control loop and is overwritten by the network control component if necessary.

The following is an exemplary sequence of Energiezutei ^¬ averaging method is shown: (1) An energy demand determination or a power generation determination takes place on the basis of an operating state of locally managed devices, the result of prognosis ^¬ procedures and / or load or generation profiles. The result of energy demand calculation are purchase bids for energy, which indicate quantity and maximum price (according to the estimate) for a given period. Result of the power generation calculation are sales deals on energy, indicating for a given period amount and minimum price (according to the generation cost ^¬). Bids such as sales bids are sent by the agent to the allocation component.

- Actor: Agent

 Input (Input): e.g. Weather forecasts as

 Basis for the prediction of production and consumption

 - Output: Bids (Quantity, Maximum Price), Bid (Quantity, Minimum Price)

(2) detecting the bids as unallocated bids: The received purchase bids and offers sale are detected in egg ^¬ nem appropriate data storage, comprises the possibly not yet allotted bids from previous processing steps ^¬. The amount of previously ^unapproved bids is made tangible for later processing ^steps .

 - Actor: Allocation component

 - Input: Bids, Bids, Unassigned Bids (Orderbook)

 - Output: unassigned bids

(3) Optional: Initial power flow calculation: The network monitoring component calculates, based on the already existing allocation, the power flow to be expected at the given time of the allocation. It transmits the allocation component, standing still for Availability checked ^¬ supply line capacities in the distribution system, and so-called Power Transfer Distribution Factors (PTDFs).

 - Actor: Network control component

 - Input: existing allocation vectors

Output: Available line capacities in the

Distribution Network, PTDFs

Allocation method based on the volume and price information: The allocation component creates a provisional front ^¬ allocation based on the prices and quantities in ^¬ formation of the previously allocated bids of the agents. Two variants can be distinguished:

(i) the allocation component incrementally expands the existing allocation by the most economically meaningful allocation of a bid with one or more offers to sell. This preliminary allocation is supplied to the further processing ^¬ steps. As soon as a final decision on the admissibility of the preliminary allocation, determining the next econometric ^¬ mixing most appropriate allocation is made.

 (ii) the allocation component extends the existing allocation by all possible bid / offer pairs. The total amount of provisional allocations will be validated in one step, and the set of allowable allocations will be adopted as an existing allocation.

Optional: If the initial power flow calculation according to (3) is performed, the allocation can be performed taking into account the ^¬ still available line capacities as well as the PTDFs. The result of this allocation ^¬ He represents, for example, the end ^¬ valid allotment result.

- Actor: Allocation component

- Input: Kaufgeböte, offers sale, existing Zutei ^¬ development vectors optional cable capacities. - Output: existing and provisional allocation vectors

(5) Power flow calculation: The provisional allocations, combined with the existing allocations, provide the basis for determining network utilization at a given time.

 - Actor: Network Monitoring Component

 - Input: existing and provisional allocation vectors

- Output: Power flow

(6) Validation according to line capacities: The most reasonable assignment from an economic point of view is validated according to the line capacities. Since the necessary network-specific information is present in the network monitoring component, the validation is preferably carried out there. On the basis of the power flow and the known line capacities, violations of the line limitation are determined. For the further procedure there are two alternatives:

(i) The provisional allocations are already adapted in the network monitoring component, ie the amount allocated to ^¬ is reduced, so that the Lei ^¬ tungskapazitäten are not exceeded. This modified, injury-free allocation is sent back to the allocation component.

 (ii) The network monitoring component communicates to the allotment component information on line line violations and which allocations are affected. The adjustments of the allocations then take place in the allocation component itself.

- Actor: Network Monitoring Component

 - Input: Power flow

- Output: adapted preliminary allocation vectors, which together with the already existing allocations power flow, which lies within the Capa ^¬ zitätsgrenzen (alternatively: Capacity injuries) (7) Adjustment of the provisional allocation vectors on the basis of the price information: The allocation component uses the price information transmitted by the agents and the allocation vectors validated by the network monitoring ^component (or the information on capacity violations) to calculate a new, economically reasonable allocation. Thus, for the portion of the provisional allocation that the network component has removed from the allocation due to capacity violations, a new matching buyer / seller pair is searched for according to the pricing information. The new provisional Zutei ^¬ development in turn is transmitted with the existing allocation vectors to the power control component that performs a re-examination.

 - Actor: Allocation component

 - Input: adapted allocation vectors (alternatively: capacity violations)

 - Output: validated provisional allocation vectors

(8) Pickup as existing allocation: Could one or more full or partial allocations between the sale and purchase bids be produced which does not violate the conduction limits the allocation ^¬ component takes the appropriate allocation in the amount of internally stored existing allocations. Already existing allocations preferably remain unchanged. If only a partial allocation could be made, the corresponding buy and sell bids will be adjusted. ^¬ to additionally allocating component notifies the be ^¬ teiligten agents by sending allocation notifications.

 - Actor: Allocation component

 - Input: validated provisional allocation vectors

 - Output: Allocation Notification

(9) Local adaptive power control: The agent controls the power generation or power consumption of its (locally) managed devices according to the allocation that it has in the allocation averaging the allocation component Sustainer ^¬ th has.

 • Actor: Agent

 • Input: Allocation Notification

 · Output: not required

1 shows a schematic flow diagram of such an energy allocation method, subdivided into the components agent 101, allocation component 102 and network monitoring component 103.

The agent 101 carries out an energy requirement determination 104 and determines a result from this as a purchase offer 105 (with parameters quantity and maximum price) to the allocation component 102.

Further, the agent 101 performs a power generating Determined ^¬ lung 106, from which it transmits a bid auction 107 determines (with Parame ^¬ tern amount and minimum amount) and development component to the grant date 102nd

The allocation component 102 detected in a step 110, the bids as not yet allocated bids (order book), umfas ^¬ send existing unallocated bids 109 and the Bids 105 and the offers sale 107th

In a step 111, an initial allocation procedure is performed by the allocation component 102 based on the Preisin ^¬ formations. Step 111 results in existing and provisional allocation vectors 112; In advance, allocations 108 existing by the allocation component 102 can be predefined in the form of producer vector and / or consumer vector.

Optionally, the existing allocations 108 can be transmitted to the network monitoring component 103 and stored there in one

Step 118 may be used for the initial power flow calculation. This step 118 results in available transfer capacity. activities and PTDFs which optionally can be found riding ^¬ turn to step 111th

The existing and provisional allocation vectors 112 are transmitted to the network monitoring component 103 and used there as part of a power flow calculation 120. Subsequently, in the network monitoring component 103, a validation of the line capacities is carried out in a step 121. The result of step 121 results in adjusted allocation vectors 122 that are validated according to predetermined capacity limits; Alternatively, a capacity violation can also be determined.

In a query 114, the allocation component 102 checks whether the provisional allocation is equal to the adjusted allocation or whether the capacity is not violated (eg exceeded). If the query is answered in the negative 114, branches to a step 113, it is performed an adjustment of the provisional division vectors on the basis of price information is to ^¬ by the allocation component 102. The query in the affirmative 114, he ^¬ follows in a step 115 the allocation component 102, the acquisition than existing allocation, it is transmitted to a ^¬ allocation notification 116 to the agent 101, there is performed in a step 117, a local adaptive energy control.

Example:

In the following, an exemplary embodiment of the processes in the allocation component and the network monitoring component is provided, after which a verification of each possible allocation (each individual buyer / seller pair) stattfin ^¬ det. Depending on the market mechanism more from ^¬ versions are possible.

Gathering the bids as unallocated bids ^(¬ allocation component): The storage of the bids and offers it ^¬ follows in two separate data structures (purchase bid list, Sales bid list). The elements of both data structures are sorted according to the price information of the bids. Kaufgebö ^¬ te be here in descending order, sales, bids are sorted in ascending order.

All algorithms of allocation component can access the As ^¬ tenstrukturen.

Allocation method based on the volume and price information (allocation component): The allocation algorithm works iteratively from all elements of the purchase bid list and the sale ^¬ commanded list.

Method for the allocation procedure (in pseudo-code notation): for all bids in the bid list do

 Purchase bid: Purchase bid-> Price == maximum purchase bid-> Price in the purchase bid list

 for all Bid in Sales Bid List do

 if Bid-> Price> = Bid-> Price:

 (1) formulate provisional allocation with content

^• Bid-> Agent

^• Sales Bid-> Agent

^• min (Bid -> Quantity, Bid -> Quantity)

(2) Capacity-based allocation = calls to:

 • Power flow calculation (existing allocations, provisional allocation)

^• changed buy / sell bid = calls to:

 • Adjustment allocation vectors (allocation taking into account capacity)

 (3) if changed purchase bid-> Quantity == 0: break end if

 iron break end if

 end for

end for Adjustment of Preliminary Allocation Vectors Based on Price Information (Allocation Component): Since in this embodiment validation of capacity limits is performed by the power flow calculation for exactly one buyer / seller allocation, the allocation taking into account the capacity limits can be directly adopted in this step. The economic efficiency is guaranteed by the iterative determination of the allocation. Method AdaptationAssignment vectors (capacity-allocating allocation) in pseudo-code notation: if allocation taking into account capacity limits ->quantity> 0:

 (1) send allotment notice to the bidder

> Agent and Sales Bid-> Agent with Content Allotment-> Quantity

 (2) store allocation in quantity of existing allocations

 (3) Change the bid and offer as follows:

 if Bid-> Quantity> Allotment-> Quantity:

 • changed buy bid: buy bid-> quantity_neu = buy bid-> quantity_old - allotment-> quantity

 end if

 if sales bid-> quantity> allotment-> quantity:

 • changed sales offer: sales offer-> quantity_neu = sales offer-> quantity_old - allotment-> quantity

 end if

 end if

 return changed sales offer, changed purchase bid

Power flow calculation (network monitoring component): The power flux calculation method (with parameters existing allocations provisional allocation) based on the sliding ^¬ monitoring the power balance \ Vi \\ V _k \ (G _ik cose _ik + B _ik sine _ik where

P _{i is} a fed power into a node i,

V _{l is} a voltage in a node i,

G _jk one of the active components in an admittance matrix for an element ik,

B _ik an imaginary part in the admittance matrix for the element ik,

0 _jk a difference in the phase angle between the

 Node i and a node k

and on the equation of reactive power equilibrium

N

0 = -Qi + ^ \ V _i \ \ V _lc G _ik cose _ik - B _ik sine _ik )

where Q _{t is} the injected reactive power

There are a number of solution methods for this problem, e.g.

 - Stromiteration

 - Newton-Raphson procedure

 - Gauss-Seidel method

 - Fast-decoupled load flow method

In this connection, reference is made by way of example to Oeding et al., Electric Power Plants and Networks, 2004.

Return of the power flow calculation is the allocation taking into account capacity limits. It corresponds to the maximum quantity that can be considered in addition to the existing allocations. Other advantages:

The approach presented here enables a Energiezutei ^¬ averaging method, the fit already at the current sourcing Netzeng- taken into account and at the same time allowing or taken into account and a logical phy ^¬ forensic separation of network monitoring component and Energiezu ^¬ distribution.

Advantageously, the approach adopts capacity constraints, without the allocation component having to have information about the network topology. The presented Energiezuteilungsver ^¬ drive allows economically efficient control actions, it can be used dispersed to an energy allocation and network monitoring by the local energy market handenen actors upstream allocation component to allow Netzüberwachungskompo ^¬ nent and agents.

Furthermore, it is advantageous that the presented approach enables a separation of the network monitoring component and the allocation component or an independent design of network control ^sections and the electricity market. Thus, multiple network sections (with individual network monitoring components) can be covered by an allocation component. It is also an advantage that the energy allocation process meets regulatory requirements and is therefore ver ^¬ reversible for practice.

In addition, the presented energy allocation method can be used as a continuous or periodic Zuteilungsverfah ^¬ ren and thus supports all common energy market mechanisms.

Thus, an energy allocation method is proposed, which already takes into account network bottlenecks during power procurement and at the same time allows a logical and physical separation of network control and energy allocation. This he will ^¬ ranges by an allocation component and a Netzüberwa- separately from each other tasks relating to the allocation of energy perceived and over predetermined

Interfaces exchange information or intermediate statuses regarding the allocation before it is actually used for energy control. This allows adaptive Ener ^¬ giesteuerung of energy sources and consumers and the flexible implementation of a number of requirements of a modern power distribution. Although the invention in detail by a ge ^¬ showed embodiment has been illustrated and described in detail at least, so the invention is not limited to this and other variations can be derived therefrom by the skilled artisan without departing from the scope of the invention.

Claims

claims

Method of energy control

 in which an allocation of the electrical energy is determined by an allocation component based on bids,

 - in which the allocation of a network monitoring component is provided,

- is checked at the network monitoring component is a Mach ^¬ bility of allocation,

- in which on the feasibility of allocating a tested is provided to ^¬ distribution of grant component of the network monitoring component based,

- where energy control is initiated based on the audited allocation.

The method of claim 1, wherein the bids hold at least a purchase offer and / or at least one sale bid by ^¬.

Method according to one of the preceding claims, the feasibility of the allocation is checked at the network monitoring component by, carried out on a bill from the Leistungsflussbe ^¬ Netzüberwa ^¬ monitoring component, a validation of Leitungskapazitä ^¬ th, in particular based.

Method according to one of the preceding claims, wherein the allocation of the electrical energy is determined by the allocation component based on the bids and based on at least one of the following factors that are determined by the network monitoring component ^¬ :

 a power flow calculation,

 - available capacities,

 - Power transfer distribution factors.

5. The method according to any one of the preceding claims, in which the energy control is initiated on the basis of the checked allocation, by the allocation component checking a condition as to whether the checked allocation of the network monitoring component corresponds to the allocation of the allocation component and / or the capacity of the network is not jeopardized,

- where the audited allocation is taken over by the allotment component, if the condition applies to ^¬

 - where the allocation is made if the condition does not apply.

6. The method according to any one of the preceding claims, wherein at least one bid is provided by at least one agent.

7. The method according to claim 6, ^wherein the agent determines an allocation requirement for at least one locally connected device.

8. The method of claim 7, wherein the power control of the at least one locally Schlos ^¬ Senen device is performed by the agent.

9. The method of claim 8, wherein the power control is based on a Runaway ^¬ performs allocation notification that is provided by the assignment component.

10. The method according to any one of the preceding claims,

- in which the ge ^¬ checked by the network monitoring component allocation of the allocation component bereitge ^¬ represents,

in which, based on the audited allocation, an adjustment of the allotment is made in the allotment component. Method according to one of claims 1 to 9,

- in which the ge ^¬ checked by the network monitoring component allocation of the allocation component bereitge ^¬ represents,

 in which, based on the checked allocation, an adaptation of the allocation is performed in the network monitoring component.

A power control apparatus comprising a processing unit configured such that

 an allocation of the electrical energy can be determined based on bids of at least one agent,

- the allocation of a network monitoring component is be ^¬ reitstellbar,

- a checked by the network monitoring component can be received to ^¬ division,

- Based on the audited allocation an energy ^¬ control is ^veranladbar .

A power control apparatus comprising a processing unit configured such that

- an allocation of an allocation component emp ^¬ catchable,

 - a feasibility of the allocation is verifiable,

- on the feasibility of allocating a ge ^¬ considered allocation of grant component is be ^¬ reitstellbar based, wherein based on the audited allocating an energy control is veranlassbar.

System for energy control

 - with an allocation component based on which an allocation of the electrical energy can be determined,

- with a network monitoring component, which can be provided to the Zutei ^¬ lung, wherein the network monitoring component is a feasibility of the allocation prüf ^¬ bar and wherein the network monitoring component an approved allocation of the allocation component be ^¬ is reitstellbar,

- based on the allocation being audited, a

 Energy control is veranlassbar.

A system for controlling energy with at least one agent, wherein at least one bid is provided by the at least one agent.