The application of the concept of circular economy thinking in construction, which is in its infancy, has been largely limited to construction waste minimisation and recycling. Little research on circular economy from a systems perspective including how new business models might enable materials to retain high residual values has been undertaken. Utilising the results from a survey and a follow-up workshop, this paper provides an analysis of an industrywide perspective of circular economy awareness, challenges and enablers. The survey results indicate that while there is industrywide awareness of the concept, clients, designers and subcontractors are the least informed and this is a key challenge for greater adoption. The absence of incentives to design products and buildings for disassembly and reuse at their end of life is a significant challenge. To encourage greater implementation of circular economy principles throughout the supply chain, a clear economic case is paramount, supported by metrics, tools and guidance.
A spherical three‐dimensional triboelectric nanogenerator (3D‐TENG) with a single electrode is designed, consisting of an outer transparent shell and an inner polyfluoroalkoxy (PFA) ball. Based on the coupling of triboelectric effect and electrostatic effect, the rationally developed 3D‐TENG can effectively scavenge ambient vibration energy in full space by working at a hybridization of both the contact‐separation mode and the sliding mode, resulting in the electron transfer between the Al electrode and the ground. By systematically investigating the output performance of the device vibrating under different frequencies and along different directions, the TENG can deliver a maximal output voltage of 57 V, a maximal output current of 2.3 μA, and a corresponding output power of 128 μW on a load of 100 MΩ, which can be used to directly drive tens of green light‐emitting diodes. Moreover, the TENG is utilized to design the self‐powered acceleration sensor with detection sensitivity of 15.56 V g‐1. This work opens up many potential applications of single‐electrode based TENGs for ambient vibration energy harvesting techniques in full space and the self‐powered vibration sensor systems.
For the last 12 years, Building Research Establishment (BRE) has been working on developing better data in terms of the amount and type of waste being produced as a result of construction activity. The means of collecting and aggregating these data have been refined over the years to arrive at the current large-scale and long-term benchmarking exercise being undertaken by way of BRE’s site waste management planning tool – Smartwaste Plan. Concurrently, a 3 year project ‘Understanding and predicting construction waste’ has been funded by Defra to develop robust reporting procedures and detailed waste benchmarks. A further objective is to demonstrate the use of such benchmarks as a means of predicting the amount and type of waste likely to be produced as a result of construction activity on a local and regional basis. This is potentially useful in working out gaps in suitable resource management facilities or under/over capacity relating to reprocessing specific waste materials. Interim results from these activities, conclusions and future/ongoing work are summarised in this paper. A range of performance indicators for waste arisings from new build construction were produced for a variety of different project types and for different waste types. These performance indicators have been use to produce benchmarks for standard, good and best practice.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.