Applying Sensor-Based Technology to Improve Construction Safety Management

Construction sites are dynamic and complicated systems. The movement and interaction of people, goods and energy make construction safety management extremely difficult. Due to the ever-increasing amount of information, traditional construction safety management has operated under difficult circumstances. As an effective way to collect, identify and process information, sensor-based technology is deemed to provide new generation of methods for advancing construction safety management. It makes the real-time construction safety management with high efficiency and accuracy a reality and provides a solid foundation for facilitating its modernization, and informatization. Nowadays, various sensor-based technologies have been adopted for construction safety management, including locating sensor-based technology, vision-based sensing and wireless sensor networks. This paper provides a systematic and comprehensive review of previous studies in this field to acknowledge useful findings, identify the research gaps and point out future research directions

The Effect of Cooling Layer Thickness and Coolant Velocity on Crystal Thermodynamic Properties in a Laser Amplifier

Laser diode pumped solid-state lasers (DPSSLs) have been widely used in many fields, and their thermal effects have attracted more and more attention. The laser diode (LD) side-pumped amplifier, as a key component of DPSSLs, is necessary for effective heat dissipation. In this paper, instead of the common thermal analysis based only on a crystal rod model, a fluid–structure interaction model including a glass tube, cooling channel, coolant and crystal rod is established in numerical simulation using ANSYS FLUENT for the configuration of an LD array side-pumped laser amplifier. The relationships between cooling layer thickness, coolant velocity and maximum temperature, maximum equivalent stress, inlet pressure and the convective heat transfer coefficient are analyzed. The results show that the maximum temperature (or maximum equivalent stress) decreases with the increase in the coolant velocity; at low velocity, a larger cooling layer thickness with more coolant is not conductive enough for improved heat dissipation of the crystal rod; at high velocity, when the cooling layer thickness is above or below 1.5 mm, the influence of the cooling layer thickness on the maximum temperature can be ignored; and the effect of the cooling layer thickness on the maximum equivalent stress at high velocity is not very significant. The comprehensive influence of various factors should be fully considered in the design process, and this study provides an important reference for the design and optimization of a laser amplifier and DPSSL system

Anticancer activity and mechanisms of action of Taisui fermentation broth in human colorectal cancer HCT116 cells in vitro and in vivo

Taisui, an unclassified biological object, is considered as a functional food with rich medicinal value in ancient Chinese books. However, there are few studies on Taisui, particularly on its anticancer activity and underlying mechanisms. Herein, we evaluated the anticancer potential of Taisui fermentation broth using HCT116 cells and nude mice xenografts in vitro and in vivo. Taisui fermentation broth inhibited HCT116 cells proliferation by inducing S-phase arrest, apoptosis, and autophagy, by regulating related proteins. Taisui fermentation broth-induced HCT116 cells death was reversed by inhibiting apoptosis and autophagy. Autophagy inhibition suppressed Taisui fermentation broth-induced apoptosis, whereas apoptosis inhibition attenuated Taisui fermentation broth-induced autophagy. Taisui fermentation broth induced apoptosis and autophagy by regulating reactive oxygen species-mediated c-Jun NH2-terminal kinase/p38 signaling in HCT116 cells. Additionally, Taisui fermentation broth inhibited tumor growth in a mouse xenograft model. Taisui fermentation broth may be a promising anticancer agent for the treatment of colorectal cancer

High Stability LED-Pumped Nd:YVO₄ Laser with a Cr:YAG for Passive Q-Switching

With improvements in light-emitting diode (LED) performance and a sharp decline in price, a light source with the irradiance of a laser and the cost of an LED is worthy of further study. We demonstrated a LED-pumped Nd:YVO4 laser in quasi-continuous-wave (QCW) and passively Q-switched (PQS) regime. With an incident pump energy of 6.28 mJ (150 μs pulses at 1 Hz), the Nd:YVO4 laser has an energy of 206 μJ at 1064 nm in the QCW regime. The optical conversion efficiency of the system is 4.1%, and the slope efficiency is 9.0%. A pulsed energy of 2.5 μJ was obtained with a duration of 897 ns (FWHM) in the PQS regime, which means the peak power is 2.79 W. The output energy stability is 97.54%