DE102012219837A1 - Power supply of a consumer - Google Patents

Abstract

The invention relates to a method for controlling a power consumption of a consumer from a power network. This determines that the consumer has a need for electricity and what price is currently to be paid for electricity from the power grid. The consumer is supplied with electricity from the power grid if the electricity price is below a predetermined threshold.

Description

The invention relates to a technique for controlling a power supply of a consumer. In particular, the invention relates to the control of the power supply of the consumer as a function of a current supply situation with electricity.

In a power supply network, it is common for power to be provided in a power plant, distributed to a plurality of households via a power grid and removed there. Distributed households are therefore supplied with electricity from a central power station. It is the responsibility of the operator of the power plant to ensure that sufficient electricity can be withdrawn from the supply network for each household at all times. An average consumption of all households together is usually subject to a certain fluctuation.

As the use of intermittent energy sources, such as wind turbines or solar plants, increases, the availability of electricity in the power grid may be subject to additional fluctuations whose magnitude is significant. A control of a power plant to always feed the amount of electricity in the power grid, which is taken by the households, this can be expensive.

More recently, it has been proposed to collect detailed power consumption information of households and to transmit it to the utility company. Such a power grid is sometimes referred to as smart ("smart grid"). An operator of the power plant can then control the supply of energy in the power grid based on this information. The disadvantage here is that a large amount of information is collected, which requires a large administrative and processing effort. In addition, data protection problems can arise if information allowing a conclusion to an individual household is stored or processed.

The invention is therefore based on the object to provide a simplified technique for controlling the power consumption of a consumer, which allows an improved balance between supply and demand of electricity in a power grid. The invention solves this object by means of a method, a computer program product and a device having the features of the independent claims. Subclaims give preferred embodiments again.

An inventive method for controlling a power consumption of a consumer from a power grid comprises steps of detecting that the consumer has a power requirement, detecting a current electricity price for electricity from the power grid and supplying the consumer with power from the power grid, if the electricity price below a predetermined threshold is.

According to the invention, the circuit reflects an availability of electricity. If more electricity is fed into the grid than is taken by consumers through the grid, the price drops. If the power supply of the consumer is coupled to the price, the consumer consumes electricity, especially when the supply of electricity is large and the electricity is cheap. Thus, the amount of current drawn can be adjusted to the amount of available or fed current. An over or under supply of electricity, which usually requires a power plant to lower or higher power, can thus be reduced. Fluctuations in the electricity supply, which may be caused by intermittent power plants, for example, which convert renewable energy into electricity, can thus be better compensated. It is not necessary to forward consumption data and collection and processing to an operator of a power plant or to another central office. Rather, it is sufficient if the operator determines the availability of electricity, maps it to an electricity price and publishes it. The publication of the electricity price can for example be done via the Internet.

In one embodiment, in addition, an urgency of the consumer's power demand is detected and the predetermined threshold is increased with increasing urgency. While some consumers, such as room lighting, there is little practical scope to make the current consumption or the operation of the current electricity price, other consumers are well suited to take the required power too early or late. The urgency may indicate how much scope there is for a temporal shift in power consumption. For example, an increasing urgency freezer may require power consumption as its internal temperature approaches 0 ° C from below. By considering the urgency, the operability of the consumer can be ensured.

In one embodiment, a history of the electricity price is predicted and powering the consumer is withheld when a falling circuit has been predicted. The current consumption of the consumer can therefore be done at the time that is optimal in terms of the price and thus with respect to the supply of electricity in the power grid. Here, the forecast of the price of electricity by an energy supplier, the electricity into the electricity grid, from a household that draws electricity for the consumer from the electricity grid, or from a third party.

If the course of the electricity price is predicted, then electricity can also be taken from the electricity network and stored in an intermediate store, if the electricity price is low, with electricity from the intermediate store at a later time, for which the electricity price is predicted to be high to supply. Caching the cache can help reduce oversupply of electricity in the grid, even when no consumer with power needs is available. The buffer may in particular comprise an electric battery or an accumulator. In one embodiment, the accumulator is stationary, in another embodiment it is comprised of an electric motor vehicle connected to the mains. The accumulator can also be considered as a consumer and charged from the mains, whereby a later operation of another consumer from the energy of the accumulator is possible.

In one embodiment, the consumer should have taken a predetermined energy at a predetermined time, the urgency being determined based on a remaining time until the predetermined time. For example, a night storage oven can be operated as a consumer, wherein a thermal storage mass is to have a predetermined temperature at a predetermined morning hour. The less time remains at the approach of the predetermined time for electrically heating the thermal storage mass, the higher the urgency of the power requirement of the night storage heater.

In a variant, the urgency can additionally be determined on the basis of an energy still to be absorbed by the consumer. Thus, it can be taken into account that a quantity of energy required by the consumer may possibly require a longer absorption of electricity from the power grid. This may concern, for example, the above-mentioned accumulator of a motor vehicle with electric drive, the accumulator can only be quickly charged with energy.

In one embodiment, a generator may be provided for feeding power into the grid and the load may be powered directly from the generator if a current gain for the generator is below the electricity price of the grid. As a result, the above-described procedure with regard to the power-price-controlled recording can also be extended to a local power generator, in particular a micro-power station, a biogas plant, a photovoltaic system or a similar device.

In a further embodiment, a feed-in price for electricity fed into the grid from the generator is determined and the consumer is supplied with electricity if the feed-in price is negative. In particular, a negative feed-in price may arise if a large number of small and medium-sized producers connected to the electricity grid feed in changing amounts of energy into the grid. This can lead to periods of strong oversupply, where no financial incentive is offered to feed further electricity into the grid. By consuming the locally generated electricity, a fee-based feed of electricity into the power grid can be avoided.

A computer program product according to the invention comprises program code means for carrying out the method described above when the computer program product runs on a processing device or is stored on a computer-readable data carrier.

A device according to the invention for controlling a current consumption of a consumer from a power network comprises a first interface for detecting that there is a power demand of the consumer, a second interface for detecting a current electricity price for electricity from the mains and a control device for supplying the consumer with electricity from the Power grid, if the electricity price is below a predetermined threshold.

By means of the apparatus, the method described above can be carried out without requiring complex processing or extensive investment by a power station operator. The device can be used in particular for controlling consumers in a household or an industrial plant.

In one embodiment, the second interface is connected to the power grid and the information of the electricity price is modulated onto the power. As a result, a separate connection for transmitting the electricity price from the producer to the consumer can be saved.

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 description of the embodiments which will be described in connection with the drawings

1 a power supply system;

2 a flowchart of a first method;

3 a flowchart of a second method;

4 Gradients on the power supply system of 1 , and

5 a course of a feed-in price for electricity in the power system of 1
represents.

1 shows a power system 100 , The power supply system 100 includes a power generator 105 and a power grid 110 , The power generator 105 converts another form of energy into electricity that is in the electricity grid 110 is provided. The power grid 110 transports electricity from the generator 105 to a variety of households 115 of which one in 1 is shown. The household 115 can also be an industrial or public institution.

On the part of the household 115 is at least one electrical consumer 120 ready to supply by electricity from the mains 110 is set up. Illustrated are a washing machine or dishwasher 125 , an accumulator 130 , which may be set up in particular for the operation of a motor vehicle with electric drive, a cooling system 135 , a storage heater 140 and a pumping device 145 ,

Furthermore, on the part of the budget 115 a device 150 ("Broker box") for controlling the consumption of electricity consumers 120 from the mains 110 intended. The device 150 includes a number of first interfaces 155 each for connection to one of the consumers 120 , a second interface 160 and a processing device 165 , The second interface 160 is set up to be connected to a data line that has a current price for off the grid 110 taken Storm can be obtained. In the presentation of 1 is the second interface 160 with the data network 170 connected, for example, may include a portion of the Internet, wherein the power generator 105 preferably also with the data network 170 connected to provide the pricing information. In an alternative embodiment, data is related to the electricity in the grid 110 modulated, for example by means of long waves, and the second interface 160 is connected to the electricity grid 110 connected to the information from the mains 110 to demodulate. The data network 170 is not required in this case. The price information can in any case by the power generator 105 or provided by third parties.

The device 150 is designed to meet a need for electricity of each consumer 120 to determine and the consumer 120 with electricity from the mains 110 to supply, if the over the second interface 160 received electricity price is below a predetermined threshold. Different approaches can be used to form the predetermined threshold. The following are the consumers exemplified 120 in this regard briefly described by way of example.

Of the washing machine 125 may be assigned a fixed predetermined threshold to the washing machine 125 then to let go when a reduction in the price of electricity occurs, as is to be expected, for example during the hours of the night.

The accumulator 130 can then get out of the power grid 110 be charged when the electricity price is below another assigned predetermined threshold. It can be considered that the charging of the battery 130 may require a longer time, for example several hours. To control the charging start of the accumulator 130 Therefore, it may be useful to predict the course of the electricity price in order to carry out as much as possible the entire charging process during a phase of a low electricity price. If the charging process is not started in time, a higher electricity price may have to be accepted in order to ensure sufficient charging of the battery at a predetermined time.

In one embodiment, a low current price, regardless of its duration, may charge the accumulator 130 effect if it is receptive. Is the accumulator 130 connected to a motor vehicle with electric drive, so this loading can also take place, for example, when the state of charge of the accumulator 130 a planned operation of the motor vehicle already allows. In both cases, at a later time one of the other consumers 120 of the household 115 from the accumulator 130 be powered. This approach is particularly useful if it can be assumed that after a phase of low electricity prices one of the consumers 120 to operate at a phase of high electricity prices.

The cooling system 135 cools with the help of electric current a refrigerator. In this case, an exact temperature of the refrigerator can be of minor importance, as long as they are below a predetermined threshold is. The cooling system 135 For example, it may cool the cold room to below the predetermined cooling temperature while the price of electricity is low, so that the temperature is subsequently removed without removing electricity from the power grid 110 can be kept below the cooling temperature. If the temperature approaches the predetermined temperature after some time, the urgency of the cooling system increases 135 , the refrigerator by means of electricity from the mains 110 to cool again.

The storage heater 140 comprises a thermal mass, which can be heated by means of electricity and discharged at a later time, for example by means of a blower to an environment. In order to carry out a sufficient heating of the environment, it can be provided that the storage heater 140 their thermal mass regularly heated at a predetermined time to a predetermined temperature. The urgency of a power consumption of the storage heater 140 can be determined from a still aufzunehmenden energy of the thermal mass, which can be read from a difference of the predetermined temperature and the current temperature. Additionally or alternatively, the urgency may be determined based on a remaining time until the predetermined time.

The pumping device 145 For example, it may comprise a sewage lifting plant which is operated not only when a predetermined level is reached, but also when the price of electricity is favorable. If there is no wastewater to be lifted, then the pumping device 145 turned off in any case. If the wastewater reaches a predetermined level, then the pumping device 145 operated regardless of the price of electricity.

Additionally or alternatively to the described consumers 120 Other household electrical appliances can also be used 115 be supplied in a corresponding manner with electricity. Includes the household 115 an industrial plant, such as cooling in the food industry or in the hotel industry, an industrial dishwasher or washing machine, a ventilation or electric heating as a consumer 120 operate.

Optional includes the household 115 a producer 175 for feeding electricity into the power grid 110 , The producer 175 may in particular include a wind turbine, a solar system, a biogas plant or a hydroelectric power plant. For in the power grid 110 fed electricity will go to the household 115 usually a feed-in price paid. The feed-in price is usually below the electricity price and can be particularly vulnerable to short-term price fluctuations. Non-constant electricity supplies from a large number of producers 175 that are on the power grid 110 can be the same or swell each other, so that in the short term there is a strong over- or under-supply of electricity in the power grid 110 may be present. The feed-in price can reflect this supply situation. Is the oversupply of electricity in the electricity grid 110 especially large, so the feed-in price can be negative, so the budget 115 net for fed electricity from the producer 175 must pay. In this case, to stop the generator 175 to avoid the locally generated electricity by any of the consumers 120 consumed. This situation can be treated as a particularly low electricity price of electricity from the grid 110 ,

2 shows a flowchart of a first method 200 , in particular for the process on the processing device 165 the device 150 in 1 is set up. In a first step 205 is the electricity price for off the grid 110 removed current determined. In this case, information can be used by means of the second interface 165 were received. In addition, the feed-in price can also be determined if a producer 175 on the part of the household 110 is provided.

In an optional step 210 becomes the urgency of a consumer's power needs 120 certainly. As described above, the urgency may be dependent on or based on a time, energy, or other device parameter. On the basis of the urgency or, for example, a user-controlled specification is then in one step 220 A maximum price is determined for electricity to the operation of the consumer 120 is acceptable.

In one step 225 Checks whether the current electricity price is below the specified maximum price. If this is the case, so will the consumer 120 in one step 230 with electricity from the mains 110 provided. Otherwise, the procedure returns 200 to the step 205 back and can go through again.

3 shows a flowchart of a second method 300 for controlling a current consumption of a consumer 120 out 1 , The procedure 300 is similar in part to the process 200 and build on this. Also the procedure 300 is for execution on the processing device 165 out 1 suitable.

In one step 305 that's the step 205 out 2 the electricity price and, if applicable, the feed-in price are determined. In one step 310 a course of the electricity price is predicted. The forecast can be made by the household 115 for example, by using historical data or extrapolating a past trend. Alternatively, the prediction can be combined with the current electricity price via the second interface 160 be obtained. The prediction can be made by the power generator 105 be provided or third party.

In the following step 315 will, as in step 210 out 2 , the urgency of a consumer's electricity needs 120 certainly. After that, in one step 320 a temporal prediction of the course of urgency created. The prediction is usually done by the household 115 and can also be based on historical data from consumers' electricity consumption 120 be performed.

In one step 325 a maximum waiting time until power consumption is determined. The maximum waiting time represents the time that the consumer 120 can do without electricity at most. Like the urgency in step 315 For example, the maximum waiting time can be determined on the basis of different parameters, for example, an energy level or a device parameter of the consumer 120 ,

In one step 330 will check if the in step 325 certain waiting time has expired. If this is the case, waiving further optimizations, the consumer 120 directly powered, as shown below. Otherwise, in one step 335 a minimum electricity price is determined during the maximum waiting period.

In one step 340 a maximum acceptable price is determined on the basis of the determined minimum electricity price and a predetermined security. In a following step 345 Checks whether the current electricity price in the step 340 certain maximum price has fallen below. If this is not the case, the process branches 300 to the step 305 back and can go through again. Otherwise, the consumer will 120 in one step 350 with electricity from the mains 110 provided.

For some of the provisions of the procedure 300 especially in the steps 315 . 320 . 325 . 335 or 340 , different heuristics can be applied. In one embodiment, at least one of these heuristics can be influenced by a user. Different heuristics can also be selected by the user. In one embodiment, heuristics may also be reassigned and in the method 300 be installed. For example, a device-related heuristic, such as the urgency determination of a consumer's power needs 120 in step 315 , to be determined by a heuristic, by the manufacturer of the consumer 120 delivered or updated.

4 shows exemplary processes on the power supply system 100 from 1 , In the horizontal direction, a time is applied and in the vertical direction, an electricity price is charged, which is negatively dependent on the availability of electricity in the power grid 110 , A first course 405 represents the electricity price. The higher the electricity price, the lower the availability of electricity in the power grid 110 , Usually, the electricity price moves within a fluctuation range 410 whose limits are determined empirically or, for example, by the power generator 105 can be promised.

A second course 415 reflects the urgency of a current consumption of a first consumer 120 and a third course 420 the urgency of a current consumption of a second consumer 120 , The two courses 415 and 420 are given in the form of the maximum acceptable electricity price, which was determined by the urgency.

At a time T0 exceeds the maximum acceptable price of electricity of the second course 415 the current electricity price 405 , In a non-predictive strategy, the corresponding consumer may 120 be powered at this time. But at least a prediction of the price of electricity 405 carried out, it is known at the time T0 that the electricity price will fall even further. The current consumption by the consumer 120 can therefore be suspended until the urgency of its power consumption is an uppermost limit 425 which must not be exceeded in order to prevent malfunction or inadequate performance of the consumer 120 to avoid. This condition occurs at time T2. A time span between a present time and the time T2 corresponds to that in the step 325 of the procedure 300 from 3 certain maximum waiting time. As the course 405 the price of electricity between the times T0 and T2 strictly monotonous falls, it is advantageous to the first consumer 120 as late as possible, that is, only at time T2 to provide power.

In one embodiment, a prediction is associated with a confidence interval that indicates an area around the predicted value, the predicted value having a predetermined probability in the confidence interval. The further the forecast for the future, the greater the confidence interval. Confidence intervals for different time periods in the future can also be determined. In one embodiment, a "worst case" prediction of the electricity price is performed by always the upper bound of the confidence interval for the predicted electricity price of the first run 405 Is accepted. Other approaches, such as "best case", where the lower bound of the confidence interval for the predicted electricity price is always used, are also possible.

The third course 420 the urgency of a current consumption of the second consumer 120 increases strictly monotonically and exceeds the value of the first course at time T1 405 the price of electricity. In a non-predictive strategy, the second consumer may be started at time T1 120 to supply electricity. In a predictive strategy, there is a prediction for the first course 405 before, so that it is known that the price of electricity will fall even further. Without waiting until a time T4 to which the third course 420 the highest limit 425 has reached and must be supplied regardless of the price of electricity, as the optimal time to supply the second consumer 120 be identified with power the time T3, at which the electricity price is minimal.

5 shows an exemplary course 505 a feed-in price for electricity of the producer 175 of the household 115 out 1 , The average of the feed-in price shown by a dashed line 505 qualitatively corresponds to the first course 405 of the electricity price in 4 , It is good to see that short-term peaks in the positive and negative directions significantly exceed the average price. In two places, the feed-in price falls 505 even in the negative.

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

Claims (11)

Procedure ( 200 . 300 ) for controlling a current consumption of a consumer ( 120 ) from a power grid ( 110 ), comprising the following steps: - detecting ( 210 . 315 ) that the consumer ( 120 ) has a power requirement; - To capture ( 205 . 305 ) of a current electricity price for electricity from the power grid ( 110 ), and - Supply ( 230 . 350 ) of the consumer ( 120 ) with electricity from the power grid ( 120 ) if the electricity price falls below a predetermined threshold ( 415 . 420 ) lies. Procedure ( 200 . 300 ) according to claim 1, wherein additionally an urgency of the electricity demand is detected ( 210 . 315 ) and the predetermined threshold ( 415 . 420 ) is increased with increasing urgency. Procedure ( 200 . 300 ) according to one of the preceding claims, wherein a course ( 405 ) of the price of electricity ( 310 ) and supplying ( 415 . 420 ) of the consumer with electricity, if a falling electricity price was predicted. Procedure ( 200 . 300 ) according to one of the preceding claims, wherein a course ( 405 ) of the price of electricity ( 310 ) and electricity from the power grid ( 110 ) and stored in a buffer ( 130 ), when the electricity price is low, to the consumer ( 120 ) be supplied with power from the buffer at a later time for which the electricity price is predicted to be high ( 230 . 350 ). Procedure ( 200 . 300 ) according to any one of the preceding claims, wherein the consumer ( 120 ) has taken a predetermined energy at a predetermined time and determines the urgency on the basis of a remaining time until the predetermined time ( 210 . 315 ) becomes. Procedure ( 200 . 300 ) according to claim 5, wherein the urgency additionally determines on the basis of an energy still to be absorbed by the consumer ( 210 . 315 ) becomes. Procedure ( 200 . 300 ) according to any one of the preceding claims, wherein a producer ( 175 ) for feeding electricity into the power grid ( 110 ) and the consumer ( 120 ) directly from the producer ( 175 ), if a current gain for the electricity from the producer ( 175 ) is below the electricity price of the power grid. Procedure ( 200 . 300 ) according to any one of the preceding claims, wherein a producer ( 175 ) for feeding electricity into the power grid ( 110 ) is available to the consumer and a feed-in price ( 505 ) for injected electricity and the consumer ( 120 ) ( 230 . 350 ), if the feed-in price is negative. Computer program product with program code means for carrying out a method ( 200 . 300 ) according to one of the preceding claims, if the computer program product is stored on a processing device ( 165 ) or stored on a computer-readable medium. Contraption ( 150 ) for controlling a current consumption of a consumer ( 120 ) from a power grid ( 110 ), comprising the following elements: A first interface ( 155 ) to record that a consumer's electricity needs ( 120 ) is present; A second interface ( 160 ) for recording a current electricity price for electricity from the power grid ( 110 ), and - a control device ( 165 ) for the supply of the consumer ( 120 ) with electricity from the power grid ( 110 ), if the electricity price is below a predetermined threshold. Contraption ( 150 ) according to claim 10, wherein the second interface ( 160 ) with the power grid ( 110 ) is connected and the information of the electricity price is modulated on the stream.

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