Abstract: A CO2 gas-liquid phase transition-based multistage compression energy storage apparatus for converting thermal energy into mechanical energy, including: a gas storage; a liquid storage tank; an energy storage assembly, which includes compressors and energy storage heat exchangers; an energy release assembly (400), which includes energy release heat exchangers and expanders; a heat exchange assembly the energy generated by the energy storage assembly, and the energy release heat exchangers being capable of receiving the energy temporarily stored by the heat exchange assembly; and a driving assembly, which includes an energy input member and a first driving member, the energy input member absorbing external thermal energy to drive the first driving member to work, and the first driving member being used for driving the compressors to work.

Abstract: The present invention relates to a detection mechanism for polymerase chain reaction and a polymerase chain reaction device, wherein the detection mechanism comprises at least one excitation module group, each of the excitation module groups comprising two excitation modules for providing excitation light with two wavelengths; an excitation optical fiber, connected to the excitation modules, the excitation optical fiber transmitting the excitation light to at least one reaction tube, each of the reaction tubes receiving excitation light with two wavelengths; a receiving optical fiber, for collecting and transmitting a fluorescent signal from the reaction tube; at least one receiving module group, connected to the receiving optical fiber, each of the receiving module groups comprising two receiving modules, to respectively receive the fluorescent signal of two wavelengths from the same said reaction tube, and convert the fluorescent signal into an electrical signal for output; the detection mechanism is config

Abstract: The present invention provides an isothiocyanate compound and its application. The compound is an aryl-substituted isothiocyanate compound that has a structure of the general formula I. The isothiocyanate compound of the present invention has very good solubility in water, far better inhibitory activity for XPO1 protein than other non-aryl substituted congeneric compounds, little side effects, and good biological safety and bioavailability, and is quite suitable for clinical application. Therefore, the isothiocyanate compound would have tremendous potential market space and economic benefits.

Abstract: The present invention relates to a detection mechanism for polymerase chain reaction and a polymerase chain reaction device, wherein the detection mechanism comprises at least one excitation module group, each of the excitation module groups comprising two excitation modules for providing excitation light with two wavelengths; an excitation optical fiber, connected to the excitation modules, the excitation optical fiber transmitting the excitation light to at least one reaction tube, each of the reaction tubes receiving excitation light with two wavelengths; a receiving optical fiber, for collecting and transmitting a fluorescent signal from the reaction tube; at least one receiving module group, connected to the receiving optical fiber, each of the receiving module groups comprising two receiving modules, to respectively receive the fluorescent signal of two wavelengths from the same said reaction tube, and convert the fluorescent signal into an electrical signal for output; the detection mechanism is config

Abstract: The present invention provides an isothiocyanate compound and its application. The compound is an aryl-substituted isothiocyanate compound that has a structure of the general formula I. The isothiocyanate compound of the present invention has very good solubility in water, far better inhibitory activity for XPO1 protein than other non-aryl substituted congeneric compounds, little side effects, and good biological safety and bioavailability, and is quite suitable for clinical application. Therefore, the isothiocyanate compound would have tremendous potential market space and economic benefits.

Abstract: A method for manufacturing an LED (light emitting diode) with transparent ceramic is provided, which includes: adding quantitative fluorescent powder into transparent ceramic powder, wherein the doped ratio of the fluorescent powder is 0.01-100 wt %; preparing the fluorescent transparent ceramic using ceramic apparatus and process, after fully mixing the raw material; assembling the prepared fluorescent transparent ceramic and a semiconductor chip to form the LED device. The method assembles the fluorescent transparent ceramic and a semiconductor chip to form the LED device by replacing the fluorescent powder layer and the epoxy resin package casting of the traditional LED with fluorescent transparent ceramic. The fluorescent transparent ceramic is used as the package cast and fluorescent material, and the LED device manufactured through the method has more excellent performance.

Abstract: A microwave probe having a metal tip on the free end of a microcantilever. In one embodiment, a pyramidal pit is isotropically etched in a device wafer of monocrystalline silicon. Oxidation may sharpen the pit. Deposited metal forms the metal tip in the pit and a bottom shield. Other metal sandwiched between equally thick dielectric layers contact the tip and form a conduction path along the cantilever for the probe and detected signals. Further metal forms a top shield overlying the conduction path and the dielectrically isolated tip and having equal thickness to the bottom shield, thus producing together with the symmetric dielectric layers a balanced structure with reduced thermal bending. The device wafer is bonded to a handle wafer. The handle is formed and remaining silicon of the device wafer is removed to release the cantilever.

Abstract: A microwave probe having a metal tip on the free end of a microcantilever. In one embodiment, a pyramidal pit is isotropically etched in a device wafer of monocrystalline silicon. Oxidation may sharpen the pit. Deposited metal forms the metal tip in the pit and a bottom shield. Other metal sandwiched between equally thick dielectric layers contact the tip and form a conduction path along the cantilever for the probe and detected signals. Further metal forms a top shield overlying the conduction path and the dielectrically isolated tip and having equal thickness to the bottom shield, thus producing together with the symmetric dielectric layers a balanced structure with reduced thermal bending. The device wafer is bonded to a handle wafer. The handle is formed and remaining silicon of the device wafer is removed to release the cantilever.

Abstract: A microwave probe having a metal tip on the free end of a microcantilever. In one embodiment, a pyramidal pit is isotropically etched in a device wafer of monocrystalline silicon. Oxidation may sharpen the pit. Deposited metal forms the metal tip in the pit and a bottom shield. Other metal sandwiched between equally thick dielectric layers contact the tip and form a conduction path along the cantilever for the probe and detected signals. Further metal forms a top shield overlying the conduction path and the dielectrically isolated tip and having equal thickness to the bottom shield, thus producing together with the symmetric dielectric layers a balanced structure with reduced thermal bending. The device wafer is bonded to a handle wafer. The handle is formed and remaining silicon of the device wafer is removed to release the cantilever.

Abstract: A method for manufacturing an LED (light emitting diode) with transparent ceramic is provided, which includes: adding quantitative fluorescent powder into transparent ceramic powder, wherein the doped ratio of the fluorescent powder is 0.01-100 wt %; preparing the fluorescent transparent ceramic using ceramic apparatus and process, after fully mixing the raw material; assembling the prepared fluorescent transparent ceramic and a semiconductor chip to form the LED device. The method assembles the fluorescent transparent ceramic and a semiconductor chip to form the LED device by replacing the fluorescent powder layer and the epoxy resin package casting of the traditional LED with fluorescent transparent ceramic. The fluorescent transparent ceramic is used as the package cast and fluorescent material, and the LED device manufactured through the method has more excellent performance.

Abstract: The magnesium-contained high-silicon aluminum alloys for use as structural materials, including profiles, bars, sheets, and forgings, are manufactured by a process including the steps of: casting an alloy ingot by direct chill casting, preheating the ingot to disperse eutectic Si phase particles, and thermal-plastic processing and heat-treating to obtain the product with a final shape and a modified microstructure. The aluminum alloys contain 0.2˜2.0 wt % of Mg and 8˜18 wt % of Si, and have homogeneous and fine microstructure, wherein the aluminum matrix is equiaxed with an average grain size less than 6 ?m, and the silicon and second phase particles are dispersed with an average size less than 5 ?m. Without adding any modifiers, they are low-costly produced by incorporating the direct chill casting with thermal-plastic processing and heat treatment, which give rise to good plasticity and relatively high strength.