PRE2023 1 Group1
Name | Student number | Major |
---|---|---|
Sven Bendermacher | 1726803 | BAP |
Marijn Bikker | 1378392 | BAP |
Jules van Gisteren | 1635530 | BAP |
Lin Wolter | 1726927 | BAP |
Problem statement
With the emerging of more renewable energy and of more energy intensive technologies, like airconditionings needed due to rising temperatures and more extreme weather, the electricity landscape has changed. The increase in load on the electricity net has to be counteracted by either improvements of the network or measures to decrease the peakload on the net. Next to this consumers often pay high prices for electricity due to producers having to power on fossil fuel plants to reach the electricity production needed for the peak times of the day, while sometimes renewable electricity is lost due to lack of use during high sun low use times. To fix this problem producers and governments have turned to introducing dynamic electricity contracts, where consumers pay different amounts of money depending on the time of consumption, thus making it more financially wise to use electricity on the low peak times. This usage of the electricity on different times can even lead to profits on the end of the consumer, and helps the planet and producers to increase the share of renewable sources of electricity. The dynamic electricity contract needs, at the moment, still a large amount of effort and input from the consumer to achieve the promised savings on electricity bills. Which thus leads to less people switching over to a dynamic electricity contract hampering the decrease of load on the net and inclusion of renewable electricity sources. A system is thus needed to decrease the effort needed to be done by the consumer, such a system would in the best case automate all appliances based on the before set operation times and the known electricity prices. This automation would need a house full of smart appliances, which are connected to the internet and can thus be turned on remotely. Research done into these systems has shown that consumers need direct messages in order to be reminded of the time to turn on the appliances, which then leads to a efficient use of the dynamic electricity contract, but this research has also shown that consumers would rather have everything automated. This automation however is still very hard due to the lack of smart appliances in most households. Research also shows that consumers benefit from an overview of their electricity usage. The system to solve this problem would thus need at minimum an overview of electricity usage, a time window input, to determine the times the consumer would accept and be able to turn on the appliances, a message that is send at the prime-time the consumer has to turn on the appliance which could include the savings achieved by the to be undertaken action and in best case a direct link to the smart appliances to automate the activation of the appliances.
Furthermore, if the automated connection of smart appliances is not yet a possibility to be developed or the user still has appliances which are not smart the info about the appliances is still needed. In order for the system to work well the input parameters of the appliances is needed as well as the information about the length of washing programs or other time related variables. Without this data the system would not be optimized, since it would have many unkowns that would lead to problems for the consumer. With this data however the best time to turn on the appliances can be chosen thus leading to no lapses in judgement by the system. It is for example important that when a program takes 3 hours the to be done task by the appliance is completed on time before the maximum finish time set by the user. Another important factor to take into account for the system is that solar panel users need other advice than people without solar panels, since the solar panels can sometimes cost money, due to negative prices, or can save much money due to times of high solar intensity. The negative prices are caused by overcongestion on the electricity grid, which if not handled would lead to failure of the grid, this is especially caused by the large amount of renewable, unstable sources of electricity. Even the minister of energy of the Netherlands states that it is sometimes more beneficial for consumers with solar panels to turn them off in times of high negative prices, this is something that the system could also control or atleast mention to the consumer. In times of no negative prices the use of solar electricity is always free, thus the system must take this into account. The price of electricity might be lowest in the morning but when the solar intensity is higher in the afternoon it would be more cost benificial to turn on the appliances during times that the consumers' solar panels are peaking in electricity generation. One final part of the problem is the possibility for people to use their electric cars as electricity storage, for this to work however many things have to be kept in mind. The electric car has to still be charged for the travel to be done by the user, thus another input is needed where the minimum charge can be set by the user, this in turn then enables the system to better optimize electricity use since the car could be charged at times of low prices and then discharged at peak times thus leading to even more savings for the user. The health of the car battery however has also to be taken into account, since the savings on electricity bills would need to counteract the degredation of the batteries well enough to be worth it. This is dependent on the age of the car as well as the type of car. The system would thus need much more info and should in the best case be directly connected to the software of the electric car.
The system that is then developed has to be easily accesible for users, this could be either done with a website or an app, the app will probably lead to the best possible integration since the messages that have to be send would in case of the website require the phone number of the user. This app would then contain options to give all information and inputs stated above to be required, able to be put in automatically with a connection to a database, for example of appliances, or manually by the user. The app would then also be connected to the other systems the user has such as their electricity providers app, the app of smart appliances and app of the electric car. With all this the system, most likely in app form, would then become a hub for all the users electricity based needs. Where the system even optimizes dynamic electricity pricing to be as profitable as possible, in turn helping the electricity network by deloading the network at peak times enabling the better inclusion of renewable forms of electricity.
Hypotheses
Our product will keep electricity costs of households with a dynamic contract below the electricity costs the same households would have with a variable contract.
Our product will keep electricity costs of households with a dynamic contract below the electricity costs the same households would have with a fixed contract.
- +assumption that it starts NOW +price does not fluctuate that much
Our product will reduce the network congestion caused by households with 30%.
- Will be based on literature study. This might not be explained using percentages, but that's something we'll look up
~~~~Our product will reduce the green energy wasted due to differences in supply and demand on the energy network by 10%.
Our product will make sure households will make use of green energy rather than fossil fueled energy
- See minutes
Project Requirements, Preferences, and Constraints
Creating RPC criteria
Setting requirements
It is necessary to work for the algorithm that it has access to the prices of the electricity per hour for the coming 24 hours. This way the algorithm can do its math and calculate the best moments for the electric devices. Therefore, the algorithm will need connection to Wi-Fi, to download the most up to date data. Algorithm should be reliable. Not too many bugs should occur, since this would decrease the user-experience drastically.
Setting preferences
The app would ideally be connected to the electric devices. This way a human would not have to interfere with the process and would not be bothered by manually planning the start of the dishwashing or washing machine. Furthermore an app that is easy to use ensures all people can profit from it, also elderly with less expertise regarding mobile phones. Ideally the app has options to personalise, so someone can decide which features of the app are shown on the homescreen.
Setting constraints
The app should not be too expensive. Since we are working with small ranges of profit, a too expensive app would not be worth the costs. Another constraint could be the reliance on an electric device being ready. If the dish washer is not ready for use yet, the app can not be used.
RPC-list
Requirements
- Implementable
- Relatively cheap
- No infrastructural changes in the electric circuit for a device that is able to turn on electric device
- Algorithm should be reliable
- Access to data regarding electricity prices
Preferences
- User feedback/interaction
- App should be easy to use
- App is personalisable
- App is looking good
- App tracking the total amount of saved money
- App should be able to make connection to smart devices
- If no connection is possible with an electric device, it should be an option to manually add the device.
Constraints
- Environment (house)
- Not-smart electric devices
- Moments the electric devices are not ready to be used.
Users
The possible users for the algorithm for low energy pricing are quite vast, ranging from private homeowners to businesses. Private homeowners can use this app to lower their expenses on energy, which is especially important due to the surge in energy prices due to everything happening in geopolitics. Homeowners could thus use this to turn on their appliances at the right times leading to huge chances on saving large sums of money. Next to private homeowners even factories or businesses could look into using the algorithm, their sometimes-intensive use of energy could then also be better placed at more beneficial times. Energy intensive procedures needed to for example fabricate a certain product could then be done at better times lowering the costs of production leading to higher profits, which is in capitalism of course one of the main drivers in business. Thus, the users for the algorithm spread almost everyone, since almost no one lives without using electricity in this current era.
Private homeowners
As described above one of the most important users would be private homeowners, since the developed app/algorithm would enable them to save large sums of money. This users most important wish would encompass mostly a good working app which is easy to navigate as well as a trustable algorithm. The algorithm should be trustable since if the algorithm is wrong very often there would be no need to use the app, some errors can be accepted though since in no case would using the app cost more money than when using electricity on chosen times, only a perfect human being would be able to spread the electricity usage better than the algorithm.
Companies
The companies would similarly to the homeowners also want a good working app, with again a huge focus on the accuracy of the algorithm. Companies would also benefit from other built in functions such as overviews of electricty use as well as a method to make sure the responsible people are informed, which should thus need everyone to be connected to a single account. Companies would thus make profit from the use of the app/algorithm but would not need major alterations to the normal version for private homeowners.
Other institutions
Since the use of electricity is such a general thing in life, any group of people, company or institution having control over their electricity use could use the app to lower their electricty prices. An important question that then arises however is, in the case that many people start using the app, can the algorithm adapt to correctly spread the use of electricity. Since the increase in usage would also lead to an increase in electricity use on times that would otherwise be seen as off peak.
Other uses
Next to the intended uses done by users as desribed above it is important to mention that with a app based on a great algorithm other interests could also arise. If the algorithm is made to be very accurate with forecasts further into the future, as little as one day, people could start to make money using the app, since some platforms may enable users to trade electricity. This trading of electricity would increase prices and is in the scope of the perceived app not to be wished, since the proposed function of the app is to reduce costs and increase sustainability not to create profits for certain people.
Electricity companies / Network operators
The electricity producers and network operators are also users that have to be taken into account when it comes to the app. While they may not be direct users of the app it is in their best interest to have as many consumers use the app since this would lead to an increase in dynamic electricity pricing users and make the existing users more efficient. This would then lead to a decrease in load on the net on peak times and a more even spread which is positive for the network operators. The electricity companies would also have to spend less on expensive sources of electricity such as gas to fullfill peak demands since cheaper forms of electricity like solar and wind would be better used during low peak times.
User interview
In order to get a clear view on the opnion of potential users of our product, we are going to conduct the interviews below. We created two interviews to be able to interview two different kind of groups: those with a dynamic contract and those without. Note that the interviews are in Dutch, as the interviewees are Dutch as well. (we might add this later) Prior to the interview, we will inform the interviewees about the subject using the explanation below, such that each one has sufficient knowledge to form an opinion on the subject.
Explanation before interview
Een dynamisch contract is een vorm van energiecontract waarbij (in het geval van de Nederlandse variant) één dag van tevoren de energieprijzen voor de volgende dag worden vrijgegeven. Deze prijzen verschillen per uur, waarbij de prijzen vaak hoger liggen bij rond piek uren waar mensen over het algemeen veel stroom gebruiken - denk aan de tijd rond het avondeten -, maar waar de prijzen stukke lager - of zelfs negatief zijn! - rond de tijd waarop weinig stroom wordt gebruikt en veel groene energie wordt opgewekt.
https://www.dynamisch-tarief.nl/stroom/ (The site doesn't allow images to be uploaded at this time, so I'm putting this in)
Interview mensen met een dynamisch contract:
1. Heeft u het informed consent form begrepen gelezen?
2. Heeft u apparaten waar je de tijd op kunt instellen voor gebruik? De vaatwasser en wasmachine bijvoorbeeld?
3. Heeft u een veelgebruiker (elektriciteit) die ‘smart’ is? Dat wil zeggen met wifi verbinding maakt en met een app te bedienen is?
4. Heeft u een elektrische auto?
5. Heeft u zonnepanelen?
6. Wat zou u vinden van een app die automatisch apparaten aanzet op de goedkoopste momenten?
7. Wat zou u vinden van een app die elke dag 1 of 2 meldingen stuurt over wanneer de stroom het goedkoopst is?
8. Heeft u een dynamisch contract, zo ja wat voor soort?
9. Wat zou u belangrijk vinden aan de app, gebruikersgemak, looks of mogelijkheid tot personalisatie?
10. Wat zou u vinden van een feature die bijhoud hoeveel geld er dit jaar is bespaard?
Beantwoord de volgende vragen van een schaal van één tot vijf, waarbij één zeer oneens is en vijf zeer mee eens.
11. “Ik ben overgestapt op een dynamisch contract vanwege financiële overwegingen”
12. “Ik ben overgestapt op een dynamisch contract vanwege milieu overwegingen”
Interview mensen met een vast of variabel contract:
1. Heeft u het informed consent form begrepen gelezen en ingevuld?
2. Heeft u apparaten waar je de tijd op kunt instellen voor gebruik? De vaatwasser en wasmachine bijvoorbeeld?
3. Heeft u een veelgebruiker(elektriciteit) die ‘smart’ is? Dat wil zeggen met wifi verbinding maakt en met een app te bedienen is?
4. Heeft u een elektrische auto?
5. Heeft u zonnepanelen?
6. Wat zou u vinden van een app die automatisch apparaten aanzet op de goedkoopste momenten?
7. Zou u een app interessant vinden die elke dag 1 of 2 meldingen stuurt over wanneer de stroom het goedkoopst is?
9. Wat zou u belangrijk vinden aan de app, gebruikersgemak, looks of mogelijkheid tot personalisatie?
10. Wat zou u vinden van een feature die bijhoud hoeveel geld er dit jaar is bespaard?
Beantwoord de volgende vragen van een schaal van één tot vijf, waarbij één zeer oneens is en vijf zeer mee eens.
11. “Als ik zou overstappen op een dynamisch contract, dan zou ik dit doen vanwege financiële overwegingen”
12. “Als ik zou overstappen op een dynamisch contract, dan zou ik dit doen vanwege milieu overwegingen”
Deliverables
The deliverables of this project will exist of an app which enables users to more easily make efficient use of a dynamic electricity pricing contract. This app will allow users to input available times and get an overview of electricity usage. In case of rapid progress the addition of automation is also wished to be developed even if it is only in a proof of concept form.
State-of-the-art
Papers on algorithms for optimal energy consumption.
- Dynamic energy scheduling and routing of a large fleet of electric vehicles using multi-agent reinforcement learning.[1]
- Residential demand response: Dynamic energy management and time-varying electricity pricing.[2]
- Implementation of a dynamic energy management system using real time pricing and local renewable energy generation forecasts.[3]
- Impact of dynamic energy pricing schemes on a novel multi-user home energy management system.[4]
- Research on consumer risks and benefits of dynamic electricity price contracts A risk or an opportunity to save?[5]
- Asset Study on Dynamic retail electricity prices by European commission[6]
Research on consumer risks and benefits of dynamic electricity price contracts A risk or an opportunity to save?
This research states that there is serious risk involved in switching from fixed prices to dynamic prices. It concludes that there is only little room for flexible electric consumption, and that the average dynamic prices in France and Austria were higher in 2021 than the fixed price. Furthermore it is said that for households with an electric vehicle(EV) a dynamic electricity bill could be beneficial, since a EV is the biggest consumer within the flexible electricity consumption activities. However, in this paper it is stated that most of the electric consumption is used for space heating and water heating. In the Netherlands we use natural gas to warm up our homes, so the situation might be different and more profitable for Dutch households.
Asset Study on Dynamic retail electricity prices by European commission
This research says that consumers can significantly decrease their electricity bill by shifting to low price moments. It evaluates different kinds of dynamic pricing options, Real time pricing, time of use up till critical peak pricing. Real time pricing and time of use pricing are the riskiest but yield the highest reward, the critical peak pricing has the lowest risk but yield a lower reward. This research also states that a dynamic pricing leads to a more efficient electric grid, since lower peak demand reduces the losses in the electricity grid. This also results in a lower electricity bill. Additionally, dynamic prices incentivise demand shifting to times of lower prices which usually indicate times of high intermittent renewable energy resources (RES) feed-in. The use of excess electricity can reduce local congestion and therefore facilitate the integration of RES in the energy system. Therefore it would also be in the interest of the government to promote switching to dynamic prices.
Furthermore it gives an overview of the potential customers for dynamic pricing. With a premium on the electricity prices reducing the maximum prices, up to 90 percent of the costumers could profit from dynamic pricing.
Most important points found in study on consumer preferences of electricity pricing programs[7]
TOU vs RTP. RTP is real time pricing where the user pays based on the real time market prices which change every hour. TOU is time of use pricing where the price is fixed long in advance on a timetable.
Consumers are fine with using dynamic electricity pricing as long as their daily routine is not affected by it or lead to reductions in their comfort level. When asked about electricity contracts people seem to still prefer a static contract. People tested in a dynamic pricing situation proposed multiple insights. Things like lights, tv, stove were things where the price at that point was not really taken into consideration, since the people thought it would affect their lifestyle too much. Things like dishwashers, washing machines and tumble dryers were used much more at low price times. Due to work however the participants of the test could not always benefit from the low prices and seemed to be less willing to turn on the appliances very early or very late in the day. People also preferred RTP over TOU since RTP made the users feel that they could save more money.
Via a questionnaire it was found out that most people prefer a constant rate even though the advantages of a dynamic contract were explained thoroughly. The cost-saving expectation was 50 – 150 euro but turned out to only be 20 to 60 euro. Therefore, it is necessary that the other advantage of dynamic pricing, the load shifting, to be explained thoroughly. And the participants expressed a wish for demand automation, thus turning on the appliances at low price times automatically in order to make the dynamic pricing seem worthwhile.
Most important points found in study on influencing residential electricity consumption with tailored messages[8]
Persuasive technologies are an important method to alter consumer behaviour next to financial benefits. Personalized persuasive technologies work better to stimulate people into doing what is wanted of them. Things like tailored information, personalized content, cooperation and competition are known to be good design principles. Messages to the user should be send at appropriate times and should be managed to not create irritation.
In a trial done with real household many insights were found by the authors. The program where users could gain more insights next to only SMS messages stating the best time to turn on the appliances was used quite little by the users, the users that did at first often use it proceeded to use it less as the trial went on. The users were happy with being able to see achieved savings as well as being able to see a comparison between real and optimal consumption curves. Users say that an in-home display could have stimulated them even more. Also, next to time and possible savings the rate should also be included in the message sent to the users. It was seen that the washing machines and dryers were shifted most often to accompany electricity savings, while dishwashers the least. Users again brought up a preference for automation. Users finally also mentioned that while they were willing to alter their behaviour it was often hard to do this due to work or other unavailability.
The authors state that their personalized approach did not lead to a higher willingness to use the program than other untailored approaches used in other experiments. The schedules of the users could be taken into account to better approach users for effective savings. If the savings are only very small other incentives should be possibly used such as a widespread reduction in CO2 emissions.
Most important points found in study on integration of electric vehicles in the electricity grid[9]Bidirectional V2G, vehicle to grid, has many advantages such as reduce power grid losses, prevent power grid overloading, minimize emissions, maximize profits and help intermittent renewable energy. The drawbacks however are battery degradation, the need for more complex hardware, a high investment cost and social barriers, because people want their car to be charged in case of emergency. Next to cost advantages the vehicle to grid also gives the owners backup power in case of a blackout. The article states that due to battery degradation V2G has to either be completely avoided or correctly optimized in order to only discharge the batteries slowly and till at max 60 percent of full capacity. This maximal percentage also works well taking into account social barriers where car owners want a certain battery level at all times. Finally, the authors state that an incentive-based system is needed for V2G to be taken up by many electric vehicle owners.
Short summary of most important points made in study on the effects of household automation and dynamic electricity pricing on consumers and suppliers[10]
The article states that the amount of savings done by household automation depends on the household's energy consumption and production through the day. It also depends on the size of the household how much savings can be done and if they are done at all. The presence of solar panels can in fact lead to less profits for a single person household. The automation of households leads to savings in both TOU and RTP pricings, with more savings with RTP. Especially profits made with solar panels can be a great incentive for the households. The suppliers however have a decrease in profits due to the increase in solar panels and automation of the households. Thus, suppliers should tailor their contracts to the consumers if the suppliers want to maximize their own profits.
A paper from 2021 analysing many papers on electricity price forecasting[11] sets out to find the state-of-the-art electricity price forecasting models, it describes problems that make comparing of different models hard and also state that there is no clear benchmark to check the performance of models to. The paper states that there are three main models, statistical models, machine learning models and hybrid models. The comparison of these 3 is very hard thus leading to the authors stating not one single state-of-the-art method but choosing multiple. For the statistical models the authors decide that the LEAR model is very accurate, while for the machine learning models the DNN model is most state-of-the-art. The hybrid models they state to be not compared enough to other models thus they decide to leave them out of consideration.
LEAR stands for Lasso Estimated Auto Regressive, where Lasso is a regression analysis method that performs both variable selection as well as regularization, which is useful to increase the quality of the dataset used for the model. Auto regressive just points to the type of model being based on time series analysis.
DNN stand for Deep Neural Network, which is a type of machine learning with the objective of trying to replicate the way a human brain thinks. The deep part stands for it being multiple levels of machine learning. These models can be better in analysis and prediction than the statistical models but do use much more computing power.
Research on profit of dynamic contract
To get costumers to switch to a dynamic contract, it is important to study the possible profit of switching to such a contract.
We look at a period of at least a year, since the price one pays in the dynamic case differs a lot in the summer and winter because of the difference in electricity consumption. To compare a fixed contract with a dynamic contract, some assumptions have to be made. The most important assumption is that the market price of the electricity stays more or less the same throughout the years. The market price can change due to global (in)stability or big events, such as wars or pandemics affecting the financial market. For our comparison we assume we are dealing with a stable market price.
The business works as follows. The energy suppliers sell the electricity to the customers with a fixed price, whilst they buy the electricity on the market for fluctuating prices. In general the price the costumer pays is higher than the price the energy suppliers pay, since the energy suppliers have to make profit. But for the fixed or variable contracts the energy suppliers work with an additional safety margin for the case of rising prices. In the case of the dynamic contract there is only the small addition in price for the energy suppliers to make profit.
Then there is a risk involved in switching to a dynamic contract. You have to pay more when the market prices increase, whereas someone with a fixed contract is not affected by this, until the moment his contract expires and he has to sign a new contract.
The costumer with the dynamic contract can thus profit from the moments the market price is lower than the price the fixed contracts offer. To profit from this, the costumer must be active and use these moments to use electric devices or load their laptops and phones. The study of the European commission gives insight into the possible costumers that use a dynamic contract profitably.
Scenarios
Single family household consisting of 2 adults and 1 child:
They turn on the dishwasher, dryer and washing machine 1 time per day. They have no electric car and no solar panels. Between 20:00 and 1:00 the TV is on. From 21:00 to 24:00 the child runs a Playstation 5. The freezer and fridge are on at all times. There is no miscellaneous electricity use in this perfect scenario.
A fixed contract would at the moment cost around 0.345 euro per kWh, a variable contract would cost around 0.37 euro per kWh. For the dynamic contract the prices of September 28 were used, these prices are in comparison to other days quite poor for dynamic contract consumers.
Let's say that the household has appliances that are quite average when it comes to electricity use. The Samsung dishwasher is always run on the eco program leading to a use of 1.053 kWh for 195 minutes, where we will assume that this is spread evenly over the time. For the dryer it is assumed that a ‘mix’ cycle is always used and that the data from 2016 is accurate for the dryer owned by this household. Thus, the dryer will use 0.66 kWh over an assumption time span of 2 hours. For the washing machine it is assumed that 0.8 kWh is used, spread also over 2 hours. For the TV it is assumed that it uses 0.2 kWh per hour. The PS5 with TV combo uses 0.3 kWh per hour. The fridge uses 0.015 kWh per hour and the freezer also uses 0.015 kWh per hour. For the dynamic contract it is assumed that the appliances are turned on at the best possible times and that the electricity use of appliances is spread evenly over the time.
Adding the entire electricity usage up found is a total use of 5.11 kWh. Thus, the cost of this electricity usage can be easily calculated for the fixed and variable contract. With a fixed contract this electricity use would cost the household 1.76 euro and with a variable contract it would cost 1.89 euro. For the dynamic case the calculation is a bit trickier since the price is different for every hour. In order to spend the least amount of money with the dynamic contract with the electricity prices of 28 September the dishwasher should be turned on at 02:00 thus it is assumed that the appliances in this case are ‘smart’ enough to be turned on automatically. The dishwasher uses 0.0054 kWh per minute. The costs of running the dishwasher from 02:00 to 05:15 is then 0.279 euro. The cost of the washing machine turns out to be 0.208 euro, for the dryer 0.172. The TV is run during fixed times and would cost for this specific day 0.332 euro. The PS5 and TV combo would cost 0.297 euro. For the fridge and freezer, the total cost is 0.228 euro. Thus, the total cost with the dynamic contract is 1.52 euro. This would mean that on a very average day the savings are 0.24 euro in comparison to a fixed contract and 0.37 euro in comparison to a variable contract. Which, assuming this is an average amount of savings, would save this household 87.6 euro on year basis comparing to a fixed contract and 135 euro comparing to a variable contract.
Single person household:
This person lives alone in a small apartment, the dishwasher, washing machine and dryer are turned on once every 3 days. This person also owns an electric car which is used for commuting from and to work, needing to only be charged a small amount at home since most of the charging is done while the person is at work. In this case the electric car is a Tesla model 3 which needs to be charged 20 percent during the night. The person also powers on a TV from 20:00 to 24:00 and cooks using induction for 30 minutes at 18:00. The electricity pricing data from Oktober 1 is used where it is assumed that today is the day the person turns on their appliances.
The person uses a washing cycle costing 1 kWh spanned over 2 hours; the dryer is put on the ‘mix’ cycle and uses 1 kWh since this dryer is quite old and thus less energy efficient. For the dishwasher the quick cycle is used, using 0.75 kWh in 30 minutes. Charging the Tesla 20% will cost 10 kWh, which takes approximately 1 hour. The induction cooktop will use 0.75 kWh. Finally, the TV will use 0.15 kWh per hour.
For the fixed contract a price of 0.345 euro per kWh is taken and for a variable contract 0.37 euro per kWh. The total kWh consumption is 14.1 kWh, which costs with the fixed contract 4.87 euro and with the variable contract 5.22 euro.
Choosing the best time for the dynamic contract we assume that the appliances are ‘smart’ and can thus be turned on at all times during the day. The charging of the car however has to take place during the night. The appliances are turned on at 13:00, leading to a cost of 0.51 euro for the dishwasher, dryer and washing machine. The cooking would cost 0.25 euro and the TV would cost 0.2 euro. Finally, the charging of the car will be done at 03:00 leading to a cost of 2.9 euro. This is in total a day cost of 3.86, which saves 1.01 euro in comparison to the fixed contract and 1.36 euro in comparison to the variable contract. This can however be highly influenced by geopolitics and the weather.
Appendix
Planning and logbook
Planning
Week 1 | Week 2 | Week 3 | Week 4 | Week 5 | Week 6 | Week 7 | Week 8 | |
---|---|---|---|---|---|---|---|---|
Decide on subject of the course | All | |||||||
Preparing meeting agendas and
make minutes |
J | |||||||
State-of-the-art section | L | |||||||
RPC section | M | |||||||
Deliverables section | S | |||||||
Logbook and planning | J | |||||||
Study on cost difference between
energy contracts |
S | |||||||
Study on the impact of our product on
network congestion |
J | |||||||
Study on consumer behaviour | L/M | |||||||
Ideation of the design of the product | S | |||||||
Construct the problem statment | L | |||||||
Interviewing potential users | M | |||||||
Contact companies involved in network
congestion |
J | |||||||
Finalize the algorhythm needed for the product | S | |||||||
Summaries of literature studies on the wiki | L | |||||||
Make the final decicion on the programming
language used for the product |
S | |||||||
Analyse the interviews of users | M | |||||||
Analyse the contact of companies | J | |||||||
Discussion | - | |||||||
Future research | - | |||||||
Appendix | - | |||||||
Bibliography | - | |||||||
Prepare presentation | - | |||||||
Process feedback on presentation and
finalize presentation |
- | |||||||
Finalization of the wiki | - | |||||||
Final presentation | All |
"-"s are yet to be assigned in upcoming meeting (25-9-2023)
Logbook
Week | Name | Break-down of hours | Total hours spent |
---|---|---|---|
1 | Sven Bendermacher | Searing for ideas (2h), Meeting about subject (1h), Writing deliverables section and mail teachers (0.5h), finding/scanning some promising literature [1-4] (2.5h). | 6 |
Marijn Bikker | Introductory lecture, research into problems and possible technical solution, Meeting about subject, writing problem statement and RPC's. | 6 | |
Jules van Gisteren | Searching for ideas (1.5h), Preparing meeting (0.5h), Meeting about subject (1h), Creating the logbook and planning (2h) | 5 | |
Lin Wolter | Searching for ideas (2.5h), Looking into possible users (2h), Start of literature study with writing of State-of-the-art (3.5h) | 8 | |
2 | Sven Bendermacher | Meeting on Monday (2.5h), Looking at possible devices and how to use (2h), Working at the layout and design of the app (4h) | 8.5 |
Marijn Bikker | Meeting with tutors, working together on problem, literature study, meeting, literature research, user study | 7,5 | |
Jules van Gisteren | Meetings (2.5h), Literature study (3h), Research on possible parties involved in subject (1.5h) | 7 | |
Lin Wolter | Working in group (2h), Finding research on consumer wishes and summarising (4h), Writing problem statement and some other alterations of wiki (1.5h) | 7.5 | |
3 | Sven Bendermacher | Meetings (3h), Finding energy data on house appliances (2h), Finding information about smart devices connections protocols (2h), Programming a working convolution cost algorithm (3h), starting on learning to code a android app in python (2h). | 12 |
Marijn Bikker | Discussing the project, discussing the website, finishing interviews, writing informed consent form, meeting, interviewing. (more hours planned next week) | 5.0 | |
Jules van Gisteren | Meeting on monday (2h), Meeting on thursday+preparations (1.5h), Creating planning (1h), Creating mail to Enexis and processing feedback on the mail (0.5h) | 5 | |
Lin Wolter | Meetings on monday and thursday (3h) Expansion of problem statement (1h) More literature research (1.5h) Finding of data on electricity usage of appliances (2h) | 7.5 | |
4 | Sven Bendermacher | Meetings on today and working in group (3h), Meeting Thursday (1h), learning app-loading (1h), automating data fetching for the algorithm (2h). (Due to illness I didn't do anything during the weekend) | 7 |
Marijn Bikker | Meeting on monday and working in group (3h), Writing transcript interview(0.5h), Meeting thursday(1h), learning app-coding(2,5h) | 7 | |
Jules van Gisteren | Meeting on monday and working in group (3h) | 3 | |
Lin Wolter | Meeting on monday and working in group (2h), Doing interview (0.5h), Meeting thursday(1h), Writing scenarios and finding needed information(3.5h) | 7 | |
5 | Sven Bendermacher | ||
Marijn Bikker | |||
Jules van Gisteren | |||
Lin Wolter | |||
6 | Sven Bendermacher | ||
Marijn Bikker | |||
Jules van Gisteren | |||
Lin Wolter | |||
7 | Sven Bendermacher | ||
Marijn Bikker | |||
Jules van Gisteren | |||
Lin Wolter | |||
8 | Sven Bendermacher | ||
Marijn Bikker | |||
Jules van Gisteren | |||
Lin Wolter |
Approach
- Literature study
- Contacting involved parties, interviews
Informed consent interviews users
You have been asked to participate in a study for the course 0LAUK0 Project robots everywhere(2023) of Eindhoven University of Technology. This document gives you information about this study and your rights as a participant. Please read it carefully.
About the study
The aim of this study is to test the need for an algorithm and app using a dynamic electricity contract to steer the user towards low-use hours. The study will last approximately 20 minutes. In this study, you will be asked some questions about your opinion and preferences for such a tool. The experiment leader will make notes of what you are saying.
Voluntary
Your participation is completely voluntary. You can refuse to participate without giving any reasons and you can stop your participation at any time during the study. You can also withdraw your permission to use your data up to 24 hours after the study is finished. All this will have no negative consequences whatsoever.
Confidentiality
All research conducted at the Human-Technology Interaction Group adheres to the Code of Ethics of the NIP (Nederlands Instituut voor Psychologen – Dutch Institute for Psychologists). We will not be sharing personal information about you to anyone outside of the research team. No video recordings are made that could identify you. Only an audio recording will be made. The information that we collect from this study is used for writing scientific publications and will only be reported at group level. It will be completely anonymous and it cannot be traced back to you
Further information
If you want more information about this study you can ask Marijn Bikker (contact email: m.w.a.bikker@student.tue.nl). If you have any complaints about this study, please contact the supervisor, m.j.g.v.d.molengraft@tue.nl.
Certificate of Consent
I, (NAME)……………………………………….. have read and understood this consent form and have been given the opportunity to ask questions. I agree to voluntarily participate in this study carried out by group 1 of the course 0LAUK0 Project robots everywhere(2023).
Participant’s Signature: .........
Date: ...........
Transscripts
Interview 1
interviewer: Marijn Bikker
Interviewee: Floris Bikker
Interview mensen met een dynamisch contract:
1. Heeft u het informed consent form begrepen gelezen?
Ja die is gelezen en begrepen.
2. Heeft u apparaten waar je de tijd op kunt instellen voor gebruik? De vaatwasser en wasmachine bijvoorbeeld?
Ja die hebben we.
3. Heeft u een “veelgebruiker“ (elektriciteit) die ‘smart’ is? Dat wil zeggen met wifi verbinding maakt en met een app te bedienen is?
Nee dat hebben we niet.
4. Heeft u een elektrische auto?
Nee
5. Heeft u zonnepanelen?
Nee
6. Wat zou u vinden van een app die automatisch apparaten aanzet op de goedkoopste momenten?
Handig, maar het zou een probleem kunnen zijn op de momenten wanneer de apparaten niet klaar zijn voor gebruik. En bovendien als je al bezig bent met de apparaten, dan is het nog maar een kleine moeite om zelf ook de tijd in te stellen wanneer hij moet draaien.
Voor elektrische auto echt handig.
Nu is het zelf in de energie-app kijken een klein beetje gedoe en gereken, een app die dat zelf doet zou misschien makkelijk zijn. Nu is het nog nieuw en leuk om in die app het even op te zoeken en uit te rekenen, misschien dat dat over een tijd minder leuk om te doen is.
7. Wat zou u vinden van een app die elke dag 1 of 2 meldingen stuurt over wanneer de stroom het goedkoopst is?
Best handig.
8. Heeft u een dynamisch contract, zo ja wat voor soort?
Ja, per uur variërende prijs.
9. Waarom bent u overgestapt op een dynamisch contract, voor besparing van geld, het milieu of een andere reden?
Beiden wel. Geld en milieu. Tijdens piek uren wordt er natuurlijk elektriciteit opgewekt met fossiele brandstoffen, als wij dan elektriciteit kunnen gebruiken tijdens uren waarop er meer groene stroom is dan scheelt dat voor het milieu.
10. Wat zou u belangrijk vinden aan de app, gebruikersgemak, looks of mogelijkheid tot personalisatie?
Gebruikersgemak het belangrijkst. Hoe de app eruit ziet niet zo.
11. Wat zou u vinden van een feature die bijhoud hoeveel geld er dit jaar is bespaard?
Ja leuk.
Literature
- ↑ Alqahtani, M., Scott, M. J., & Hu, M. (2022). Dynamic energy scheduling and routing of a large fleet of electric vehicles using multi-agent reinforcement learning. Computers & Industrial Engineering, 169, 108180.
- ↑ Muratori, M., & Rizzoni, G. (2015). Residential demand response: Dynamic energy management and time-varying electricity pricing. IEEE Transactions on Power systems, 31(2), 1108-1117.
- ↑ Elma, O., Taşcıkaraoğlu, A., Ince, A. T., & Selamoğulları, U. S. (2017). Implementation of a dynamic energy management system using real time pricing and local renewable energy generation forecasts. Energy, 134, 206-220.
- ↑ Abushnaf, J., Rassau, A., & Górnisiewicz, W. (2015). Impact of dynamic energy pricing schemes on a novel multi-user home energy management system. Electric power systems research, 125, 124-132.
- ↑ Iakov Frizis, Stijn Van Hummelen (Cambridge Econometrics), February 2022, Research on consumer risks and benefits of dynamic electricity price contracts.
- ↑ Sil Boeve (Guidehouse), Jenny Cherkasky (Guidehouse), Marian Bons (Guidehouse) and Henrik Schult(Guidehouse), Asset Study on Dynamic retail electricity prices
- ↑ Elisabeth Dütschke, Alexandra-Gwyn Paetz, Dynamic electricity pricing—Which programs do consumers prefer?, Energy Policy, Volume 59, 2013, Pages 226-234, ISSN 0301-4215, https://doi.org/10.1016/j.enpol.2013.03.025.
- ↑ Schrammel, J., Diamond, L.M., Fröhlich, P. et al. Influencing residential electricity consumption with tailored messages: long-term usage patterns and effects on user experience. Energ Sustain Soc 13, 15 (2023). https://doi.org/10.1186/s13705-023-00386-4
- ↑ Kang Miao Tan, Vigna K. Ramachandaramurthy, Jia Ying Yong, Integration of electric vehicles in smart grid: A review on vehicle to grid technologies and optimization techniques, Renewable and Sustainable Energy Reviews, Volume 53, 2016, Pages 720-732, ISSN 1364-0321, https://doi.org/10.1016/j.rser.2015.09.012. (https://www.sciencedirect.com/science/article/pii/S136403211500982X)
- ↑ Marija Miletić, Mirna Gržanić, Ivan Pavić, Hrvoje Pandžić, Tomislav Capuder, The effects of household automation and dynamic electricity pricing on consumers and suppliers, Sustainable Energy, Grids and Networks, Volume 32, 2022, 100931, ISSN 2352-4677, https://doi.org/10.1016/j.segan.2022.100931. (https://www.sciencedirect.com/science/article/pii/S235246772200176X)
- ↑ Jesus Lago, Grzegorz Marcjasz, Bart De Schutter, Rafał Weron, Forecasting day-ahead electricity prices: A review of state-of-the-art algorithms, best practices and an open-access benchmark, Applied Energy, Volume 293, 2021, 116983, ISSN 0306-2619, https://doi.org/10.1016/j.apenergy.2021.116983. (https://www.sciencedirect.com/science/article/pii/S0306261921004529)