Abstract: The invention discloses a high impermeability and low thermal conductivity inorganic lightweight foam concrete and its preparation method, including the following mass fraction of raw materials: 1260˜1540 parts of ordinary silicate cement, 20˜60 parts of nano-silica, 460˜740 parts of fly ash, 360˜440 parts of aggregate, 9˜11 parts of redispersible latex powder, 7.2˜8.8 parts of polypropylene fiber, 27˜33 parts of quick-setting agent, 500 parts of fluorine-free foam, 900˜1100 parts of water. 33 parts, 500 parts of fluorine-free foam, 900˜1100 parts of water. The high impermeability and low thermal conductivity inorganic lightweight foam concrete prepared by the present invention has a simple formulation, good workability, light weight and low thermal conductivity, and is suitable for the construction of thermal insulation system for building exterior walls.

Abstract: A nuclear emergency multifunctional operation robot includes a base, a mechanical arm, a tool change-over device, and motion supporting devices. The base includes a pedestal, a mounting seat A, a mounting seat B, a mounting seat C, a rotation driving mechanism A, and a rotation driving mechanism B. The front end of the mechanical arm is connected to the mounting seat B; the tool change-over device includes a male connector and a female connector which are abutted with or separated from each other; and the motion supporting devices are used to drive the nuclear emergency multifunctional operation robot to move. The present disclosure has the advantages that the base can be integrated with various end tools, so that the operation robot conveniently changes over tools according to operation needs to conduct various types of operations.

Abstract: Disclosed is a method for preparing an EVA copolymer with a high ethylene content by solution polymerization under a low to a medium pressure. The method comprises the following steps: initiating with a free radical initiator(s), a copolymerization reaction between ethylene and vinyl acetate in a solvent in a reactor under a low to a medium pressure to obtain the EVA copolymer; and continuing to add ethylene during the reaction to maintain the low to medium pressure, wherein the low to medium pressure is 1-101 MPa, and a ratio of a mass of the vinyl acetate to a mass of the initially added ethylene is (1:1) to (1:20). The amount of ethylene incorporated in the EVA copolymer prepared according to the method is ? 50 wt%, and the EVA copolymer has properties equivalent to those of an EVA copolymer obtained by bulk polymerization at high temperature under high pressure.

Abstract: The embodiments of the present disclosure disclose a method, apparatus and system for determining sweet spot region for shale oil in-situ conversion development. The method comprises: determining an output oil and gas potential index according to a Total Organic Carbon (TOC), a Hydrogen Index (HI) and a shale density; determining a heated shale section according to the output oil and gas potential index and corresponding lower limit value of the oil and gas potential index that is determined according to a well arrangement mode and a shale vitrinite reflectance; determining an output quantity according to a thickness and an area of the heated shale section and data of the output oil and gas potential index; determining a Return on Investment (ROI) according to the output quantity and an invested cost; and determining a sweet spot region for shale oil in-situ conversion development by using the ROI.

Abstract: The problems associated with the traditional methods and devices in the field of cell cloning have been solved by the multi-compartment device and method in the present invention. The device combines the advantages of a traditional petri-dish and a traditional microplate. The multi-compartment device in the present invention comprises sidewalls, which are taller than openings of the multi-compartments. The cells in the suspension flow across the multi-compartments and seed inside the compartments during a plating process. The multi-compartment device in the present invention allows easier plating process, changing conditioned medium, and cell colony detachment and transfer. The multi-compartment device also minimizes the risk of cross-contamination during cloning process and during cell colony transfer. The invention also provides an exemplary method of using the multi-compartment device for cell cloning.

Abstract: The problems associated with the traditional methods and devices in the field of cell cloning have been solved by the multi-compartment device and method in the present invention. The device combines the advantages of a traditional petri-dish and a traditional microplate. The multi-compartment device in the present invention comprises sidewalls, which are taller than openings of the multi-compartments. The cells in the suspension flow across the multi-compartments and seed inside the compartments during a plating process. The multi-compartment device in the present invention allows easier plating process, changing conditioned medium, and cell colony detachment and transfer. The multi-compartment device also minimizes the risk of cross-contamination during cloning process and during cell colony transfer. The invention also provides an exemplary method of using the multi-compartment device for cell cloning.