At Rinnai, we have invested in a wide range of white papers that assess pragmatic ways to reduce carbon emissions. Our extensive collection of white papers reflects our commitment to providing innovative solutions that help reduce carbon emissions, offering in-depth analysis and practial insights into various aspects of hot water systems and their environmental impact.
Below is a selection of these papers that cover Hydrogen blending, low temperature hot water systems, BioLPG, hybrid systems and connectivity, and more.
If you have any further questions regarding the energy saving capability of Rinnai systems, then click the link below to get in touch.
Direct continuous flow systems for lower onsite carbon: This module looks at continuous flow water heating systems and how they can offer reduced energy consumption compared to traditional system.
Condensing, continuous flow hot water heaters: This module considers the role of condensing continuous flow hot water heating in helping to reduce carbon emissions, as part of a low carbon future.
A review of lifecycle cost and operational carbon: A study was carried out to revisit some of the widely-applied conventions of system solutions to identify opportunities for improvement. This paper describes a joint-study to review the various heating systems typically encountered in the industry today.
Limescale reduction for continuous flow hot water: This module explores what causes limescale and how it can be addressed in modern continuous flow hot-water systems.
Lifecycle costs of DHW in commercial applications: This module expands on previous CPDs, with a more extensive example of how net present value analysis can be undertaken to calculate the life-cycle cost of heating and domestic hot water systems.
Interoperability as a means of reducing onsite carbon: This module examines the common protocols that are allowing building automation and control systems to converge.
Delivering value engineered hot water solutions: This module focuses on some of the drivers for ‘value’ in building services engineering, and considers the application of the comparative net present value technique.