ABSTRACT
Domestic microgeneration is the onsite generation of low- and zero-carbon heat and electricity by private households to meet their own needs. In this paper we explore how an everyday household routine -- that of doing laundry -- can be augmented by digital technologies to help households with photovoltaic solar energy generation to make better use of self-generated energy. This paper presents an 8-month in-the-wild study that involved 18 UK households in longitudinal energy data collection, prototype deployment and participatory data analysis. Through a series of technology interventions mixing energy feedback, proactive suggestions and direct control the study uncovered opportunities, potential rewards and barriers for families to shift energy consuming household activities and highlights how digital technology can act as mediator between household laundry routines and energy demand-shifting behaviors. Finally, the study provides insights into how a "smart" energy-aware washing machine shapes organization of domestic life and how people "communicate" with their washing machine.
Supplemental Material
- Alan, A., Costanza, E., Fischer, J., Ramchurn, S. D., Rodden, T. and Jennings, N. R. A Field Study of Human-Agent Interaction for Electricity Tariff Switching. AAMAS, 2014. Google ScholarDigital Library
- Banerjee, N., Rollins, S., and Moran, K. Automating energy management in green homes. In Proc. SIGCOMM HomeNets '11, ACM Press (2011), 19--24. Google ScholarDigital Library
- Bourgeois, J., van der Linden, J., Kortuem, G. and Price, B. A. Using Participatory Data Analysis to Understand the Social Constraints and Opportunities of Electricity Demand-Shifting. ICT for Sustainability (ICT4S). 2014Google Scholar
- Costanza, E., Fischer, J. E., Colley, J. E., Rodden, T., Ramchurn, S. and Jennings, N. R. Doing the Laundry with Agents: A Field Trial of a Future Smart Energy System in the Home. In Proc. CHI 2014, ACM Press (2014), 813--822. Google ScholarDigital Library
- Costanza, E., Ramchurn, S. D. and Jennings, N. R. Understanding Domestic Energy Consumption through Interactive Visualisation: A Field Study. In Proc. of the 2012 ACM Conference on Ubiquitous Computing, 216--225. ACM, 2012. Google ScholarDigital Library
- Crabtree, A. and Rodden, T. Domestic routines and design for the home. Computer Supported Cooperative Work (CSCW), 2004: 191--220. Google ScholarDigital Library
- Crabtree, A., Rodden, T., Hemmings, T. and Benford, S. Finding a Place for UbiComp in the Home. In UbiComp 2003: Ubiquitous Computing, 208--226. Springer, 2003.Google Scholar
- Davidoff, S., Lee, M. K., Yiu, C., Zimmerman, J. and Dey, A. K. Principles of smart home control. Ubicomp, 2006. 19--34. Google ScholarDigital Library
- Derijcke, E. and Uitzinger, J. Residential Behavior in Sustainable Houses. In User Behavior and Technology Development, 119--26. Springer, 2006.Google Scholar
- Fischer, C. Feedback on Household Electricity Consumption: A Tool for Saving Energy? Energy Efficiency 1, no. 1 (May 6, 2008): 79--104.Google ScholarCross Ref
- Finn, P., Fitzpatrick, C. and Connolly, D. Demand side management of electric car charging: Benefits for consumer and grid, Energy, Vol. 42, Issue 1, June 2012, 358--363Google ScholarCross Ref
- Finn, P., O'Connell, M. and Fitzpatrick, C. Demand side management of a domestic dishwasher: Wind energy gains, financial savings and peak-time load reduction, Applied Energy, Vol. 101, 2013. 678--685Google ScholarCross Ref
- Gill, Z. M., Tierney, M. J., Pegg, I. M. and Allan, N. Measured Energy and Water Performance of an Aspiring Low Energy/carbon Affordable Housing Site in the UK. Energy and Buildings 43, no. 1 (January 2011): 117--25.Google ScholarCross Ref
- Gleerup, M., Larsen, A, Leth-Petersen, S. and Togeby, M. The Effect of Feedback by Text Messages (SMS) and Email on Household Electricity Consumption: Experimental Evidence. The Quarterly Journal of the IAEE's Energy Economics Education Foundation 31, no. 3 (2010): 113--132.Google Scholar
- He, H. A., Greenberg, S. and Huang, E. M. One Size Does Not Fit All: Applying the Transtheoretical Model to Energy Feedback Technology Design. In Proc. CHI 2010, ACM Press (2010), 927--936. Google ScholarDigital Library
- Hondo, H. and Kenshi B. Socio-psychological impacts of the introduction of energy technologies: change in environmental behavior of households with photovoltaic systems. Applied Energy 87.1 (2010): 229--235.Google ScholarCross Ref
- Keirstead, J. Behavioural responses to photovoltaic systems in the UK domestic sector. Energy Policy, 35/8, Aug. 2007.Google Scholar
- Kobus, C. B. A., Mugge, R. and Schoormans, J. P. L. Washing When the Sun Is Shining! How Users Interact with a Household Energy Management System. Ergonomics 56, no. 3 (March 2013): 451--462.Google ScholarCross Ref
- Lim, B. Y. and Dey, A. K. Evaluating Intelligibility Usage and Usefulness in a Context-Aware Application. HCI (5) 2013: 92--101Google Scholar
- Lovins, A. B. and Rocky Mountain Institute. Reinventing Fire. Chelsea Green, 2011.Google Scholar
- Mennicken, S., and Huang, E. M. Hacking the natural habitat: an in-the-wild study of smart homes, their development, and the people who live in them. 2012: 143--160. Google ScholarDigital Library
- Meier, A., Aragon, C., Peffer, T., Perry, D. and Pritoni, M. Usability of residential thermostats: Preliminary investigations. 46 (Oct 2011): 1891--1898.Google Scholar
- Palensky, P. and Dietrich, D. Demand side management: Demand response, intelligent energy systems, and smart loads. Industrial Informatics, IEEE Transactions on 7.3 (2011): 381--388.Google Scholar
- Pierce, J. and Paulos, E. Beyond Energy Monitors: Interaction, Energy, and Emerging Energy Systems. In Proc. ACM SIGCHI 2012, 665--674, 2012. Google ScholarDigital Library
- Pierce, J. and Paulos, E. The Local Energy Indicator: Designing for Wind and Solar Energy Systems in the Home. In Proceedings of the Designing Interactive Systems Conference, 631--634, 2012. Google ScholarDigital Library
- Price, B. A., van der Linden, J., Bourgeois, J., Kortuem, G. When Looking out of the Window is not Enough: Informing The Design of In-Home Technologies for Domestic Energy Microgeneration. ICT for Sustainability (ICT4S). 2013Google Scholar
- Shove, E. Converging Conventions of Comfort, Cleanliness and Convenience. Journal of Consumer Policy 26, no. 4 (2003): 395--418.Google ScholarCross Ref
- Stevenson, F. and Leaman, A. Evaluating Housing Performance in Relation to Human Behaviour: New Challenges. Building Research & Information 38, no. 5 (October 2010): 437--441.Google ScholarCross Ref
- Woodruff, A., Hasbrouck, J. and Augustin, S. A bright green perspective on sustainable choices. In Proc. CHI 2008, ACM Press (2008), 313--322. Google ScholarDigital Library
- Yang, R., Newman, M. W., and Forlizzi, J. Making Sustainability Sustainable: Challenges in the Design of Eco-Interaction Technologies. In Proc. CHI 2014, ACM Press (2014), 823--832. Google ScholarDigital Library
Index Terms
- Conversations with my washing machine: an in-the-wild study of demand shifting with self-generated energy
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