For love and money: Navigating values at the antiques roadshow event

Antiques Roadshow Events are held in historic locations across the United Kingdom. On site, experts evaluate objects brought in by attendees, who are often cast as passive recipients, while edited highlights make up the long-running BBC TV program. Through Collaborative Event Ethnography at one Roadshow Event we show how object stories are navigated through “value talk” between attendees and experts in front of live audiences. Value is not a measurement but a dimension of the thing and its context. Stories and money are both integral in understanding worth, and final valuations are only partially shaped by given expertise

Effect of Nanopowder Addition on the Sintering of Water-Atomized Iron Powder

A promising method of improving the densification of powder metallurgical steel components is to blend nanopowder with the otherwise typically used micrometre-sized powder. The higher surface-to-volume ratio of nanopowder is hypothesized to accelerate the sintering process and increase the inter-particle contact area between the powder particles. This is supposed to enhance the material transport and improve the densification. In the present investigation, water-atomized iron powder (−\ua045 μm) was mixed separately with pure iron and low-carbon steel nanopowder, each at a ratio of 95 to 5 pct. These powder mixes were compacted at different pressures (400, 600 and 800 MPa) and then sintered at 1350 \ub0C in a pure hydrogen atmosphere. The sintering behavior of the powder blend compacts was compared to that of the compact with micrometre-sized powder only. Densification commenced at much lower temperatures in the presence of nanopowder. To understand this, sintering at intermittent temperatures such as 500 \ub0C and 700 \ub0C was conducted. The fracture surface revealed that the nanopowder was sintered at between 500 \ub0C and 700 \ub0C, which in turn contributed to the densification of the powder mix at the lower temperature range. Based on the sintering experiments, an attempt was made to calculate the activation energy and identify the associated sinter mechanism using two different approaches. It was shown that the first approach yielded values in agreement with the grain-boundary diffusion mechanism. As the nanopowder content increased, there was an increase in linear shrinkage during sintering