In the remote Andes mountains, thousands of indigenous Peruvians are impacted by Heladas, or extreme frost, contributing to thousands of respiratory illnesses and hundreds of related fatalities each year, especially among children and the elderly. Climate change is intensifying the adverse effects, putting more than half a million Peruvians at risk. A contributing factor to these adverse health outcomes is the traditional Andean family dwelling, which is unable to maintain a safe and healthy temperature when temperatures drop below 20 degrees Celsius.
To futureproof hundreds of thousands of people, the solution needs to be sustainable, social, and durable, which is easy to say but much harder to do. The more we examined the factors complexifying the wider problem, the more clear-eyed we became. And because this is a national issue, at the end of the day, the government, PUCP, local businesses, and the communities will be the “eco-system” to sustain this effort beyond the project.
Our approach
As we approached the project, we had the benefit of an intuitive “Peruvian plus global team” with backgrounds in engineering, construction, logistics, law, social development, and political science who could break down the challenge into clusters of issues and make connections. We also benefitted from Bechtel’s long presence in Peru, enabling us to leverage relationships, resources, and cultural knowledge.
During the ideation phase, human design (putting people at the center of the innovation) and systems thinking (connecting institutions and relationships that will affect the innovation) became more apparent as an overall method. To put it into perspective, we considered a range of issues. For example, how do we localize the solution? This includes appropriate technology to capture, store, and transfer heat energy; using native materials; gaining social acceptance and adoption by families; and ensuring preventive maintenance of the technology. Then, how do we logistically and sustainably deliver this? The families are in some of the most remote places in the Andes. If you are manufacturing the system in Lima and transporting to Cusco or Puno, it can take up to 30 hours by truck. How do we scale to reach everyone? There’s currently no standardization of the system or value chain to support it. The total cost of the system also needs to be cost prohibitive. Finally, we need to internalize external events like frequent changes in political and government leadership, along with community issues related to these transitions. Disruptions, delays, and “starting over” with new government officials are just some of the effects.
Besides the technical connection we all have to the project, we also have an emotive one. This was a common thread among the bechtel.org team and our partners that helped us to stay the course during the project’s many twists and turns.
A “pilot-test-position for scale” framework was devised to guide the project’s implementation. We felt it was the best way to position a new solar harvesting system as a national-level solution. Three strategies continue to steer our work:
Reorient the conventions of “appropriate technology” (i.e., simple, small scale, localized). A new solar harvesting system to keep families safe and healthy not only must be fit-for-purpose, but also scalable and replicable to meet a broader societal need.
Keep the stakeholder eco-system integrated, engaged, and enabled – not just people, but also institutions. NRHP is delivering the houses in which the system will be installed. They are involved with budgeting, planning, implementation, quality assurance, etc., and will oversee this effort beyond the immediate project.
Don’t put the impact at risk. We need to ensure the human design and systems thinking is integral throughout the project’s delivery and part of the overall playbook for scale-up.
Positioning for impact
In the pilot phase, we worked closely with PUCP and NRHP to engage many affected families to demonstrate early proof of concept for a new solar harvesting system. The system not only achieved the living temperature of 16-18 Celsius (61-64 degrees Fahrenheit) when –20Celsius (-4 degrees Fahrenheit) outside, but it’s close to being pre-validated by the NRHP as the technical standard for Peru. The design and performance of the system was based on family input and early acceptance and adoption, as well as the capabilities and resources of local institutions. Safe trials were conducted at the PUCP’s Lima campus before piloting in Cusco over 11,000 feet above sea level. The system uses native materials and local supplies, but the design continued to be enhanced to optimize the capture, storage, and transfer of thermal heat. The design is now the basis for fabrication by a Peruvian manufacturer to determine the true cost of the system, as well as generate alternatives to improve cost efficiencies and sustainability. Finally, given the remoteness of the families, preventive maintenance training is being developed so that adult family members can understand how it operates and perform basic upkeep to prolong the system’s performance.