Abstract: The present invention provides a piezoelectric MEMS microphone having a base with a cavity, a piezoelectric diaphragm, and a restraining element. The base has a ring base circumferentially forming a cavity, a support column. The piezoelectric diaphragm includes diaphragm sheets each having a fixing end connected to a support column and a free end suspended over the cavity. The restraining element has one end fixedly connected to the free end, the other end connected to the part on the base that is not connected to the fixing end. The piezoelectric MEMS microphone of the invention can constrain the deformation of the diaphragm sheet, thereby improving the resonant frequency of the piezoelectric diaphragm, reducing the noise of the whole piezoelectric MEMS microphone.

Abstract: The invention provides a piezoelectric micro-electromechanical systems (MEMS) microphone having a base with a cavity, a piezoelectric diaphragm, and a limit element. The base has a ring base, and a support column. The piezoelectric diaphragm includes diaphragm sheets. Each diaphragm sheet have a fixing end connected with the support column and a free end suspended above the cavity. The limit element includes a limit part arranged apart from the piezoelectric diaphragm to limit the free ends in vibration directions of the diaphragm sheets, and an edge fixing plate connected with the outer edge of the limit part and arranged on the ring base. When the diaphragm sheets greatly deform upwards under impact force, deformation of the diaphragm sheets can be controlled, and the diaphragm sheets are protected to prevent the diaphragm sheets from breaking, thereby improving the stability of the piezoelectric MEMS microphone.

Abstract: A piezoelectric MEMS microphone is disclosed. The microphone includes a base having a cavity; a piezoelectric diaphragm; a fixation beam connecting with the piezoelectric diaphragm; and a support beam connecting with the base and the fixation beam. The piezoelectric diaphragm has a number of diaphragm sheets fixed by the fixation beam, each diaphragm sheet having a fixed end and a free end. The fixed end is connected with the fixation beam, and the free end extends from the fixed end to two sides and is suspended above the cavity. Compared with the related art, mechanical strength of the diaphragm sheet is improved, and the output intensity of the signal is improved.

Abstract: Provided is a piezoelectric type and capacitive type combined MEMS microphone, comprising a base with a back cavity and a capacitor system arranged on the base; wherein, the capacitor system comprises a back plate and a diaphragm; the back plate is opposite to and apart from the diaphragm to form a first sound cavity; a piezoelectric diaphragm structure is between the capacitor system and the base; a second sound cavity is formed between the capacitor system and the piezoelectric diaphragm structure; the second sound cavity is at least in communication with the first sound cavity or the back cavity; the piezoelectric type and capacitive type combined MEMS microphone can output two groups of electric signals comprising a group of electric signals output from the capacitor system and a group of electric signals output from the piezoelectric diaphragm structure, thus improving sensitivity of the microphone.

Abstract: A microchannel heat exchanger structure with a nozzle and a working method thereof. The microchannel heat exchanger structure with a nozzle, includes a first heat exchange portion, a second heat exchange portion, and at least one nozzle portion between the first heat exchange portion and the second heat exchange portion, the first heat exchange portion having a high-pressure heat exchange channel, a first micro-fin array being provided inside the high-pressure heat exchange channel, and the second heat exchange portion having a low-pressure heat exchange channel, the high-pressure heat exchange channel and the low-pressure heat exchange channel being in communication through at least one nozzle disposed in the nozzle portion. The heat exchanger structure has a good heat exchange effect and can achieve a better heat flux during heat exchange.

Abstract: The present disclosure discloses a method and apparatus for loading an application. An embodiment of the method comprises: selecting, in a programmable read-only memory, a storage space for storing a preset data section in an executable file of an application; copying the preset data section to a memory, and relocating the preset data section based on a start address of the storage space; and copying the relocated preset data section to the storage space. A relocation of a code portion of the executable file in the memory is implemented, and the relocated code portion is then written back into the programmable read-only memory, so that the relocation of the code portion can be completed only by one erase operation for a memory block, thereby reducing system overheads during the application loading process, and reducing wear of the programmable read-only memory.

Abstract: The present application discloses an organic electroluminescent device including a host material and guest material, the host material is an exciplex formed by electron donor material and electron receptor material, the guest material is thermal activated delayed fluorescent material, a singlet energy level of the host material is lower than a singlet energy level of the guest material.

Abstract: The present application provides a piezoelectric microphone including a substrate having a back cavity and a piezoelectric cantilever diaphragm fixed to the substrate, the piezoelectric cantilever diaphragm includes a fixed end fixedly connected to the substrate and a movable end connected to the fixed end and suspended above the back cavity, the piezoelectric microphone further includes a support back plate, the support back plate includes a support arm opposite to and spaced apart from the movable end of the piezoelectric cantilever diaphragm and a fixing arm that fixes the support arm. The piezoelectric microphone of the present disclosure has better stability compared to the related art.

Abstract: The present application provides a piezoelectric microphone, including a substrate having a back cavity and a piezoelectric cantilever diaphragm fixed to the substrate. The piezoelectric cantilever diaphragm includes a first diaphragm located at its center and suspended above the back cavity, and a second diaphragm fixed to the substrate and provided around the first diaphragm. The second diaphragm includes a fixed end fixed to one side of the substrate and a movable end close to the first diaphragm side and suspended above the back cavity. The piezoelectric microphone further includes one or more elastically stretchable members each connecting the first diaphragm with the movable end. The piezoelectric microphone of the present disclosure has better performance.

Abstract: The present disclosure discloses a method and apparatus for operating on a file. A specific embodiment of the method comprises: receiving a request of an operation on a target file, acquiring index information associated with a storage space address of a data page based on a file name and a data page identifier, the index information being stored in an on-chip memory of a processor for executing a machine instruction corresponding to the operation; and finding the data page based on the index information, and performing the operation on the data page. Accordingly, the operation on the file is implemented depending on an index stored in the on-chip memory, so that memory overheads of accessing the index are equivalent to 0, and memory resources are saved, thereby reducing system overheads.

Abstract: The present application provides a piezoelectric microphone, and it includes a substrate having a back cavity and a piezoelectric cantilever diaphragm fixed to the substrate. The piezoelectric cantilever diaphragm includes a plurality of diaphragm flaps, and each of the diaphragm flaps has one end fixed to the substrate and another end suspended above the back cavity. Every two adjacent ones of the diaphragm flaps are spaced apart to form a gap. The piezoelectric microphone further comprises an elastically stretchable member connecting the two adjacent diaphragm flaps, and the elastically stretchable member is provided between at least one set of two adjacent ones of the diaphragm flaps. The piezoelectric microphone of the present disclosure has better performance.

Abstract: A combined cooling, heating and power system is formed by integrating a CO2 and ORC cycle systems, and an LNG cold energy utilization system on the basis of an SOFC/GT hybrid power generation system. The combined systems provide utilization of energy and low carbon dioxide emission. The SOFC/GT is used as a prime mover, high-temperature, medium-temperature, and low-temperature waste heat of the system are recovered through a CO2 and ORC cycles, cold energy (for air conditioning and refrigeration), heat, power, natural gas, ice, and dry ice is provided by using LNG as a cold source of the CO2 cycle and the ORC cycle, and low carbon dioxide emission of the system is achieved by condensation and separation of CO2 from flue gas, so energy losses of the combined system is reduced, and efficient and cascade utilization of energy is achieved, thereby providing energy conservation and emission reduction effect.

Abstract: The invention provides a piezoelectric micro-electromechanical systems (MEMS) microphone having a base with a cavity, a piezoelectric diaphragm, and a limit element. The base has a ring base, and a support column. The piezoelectric diaphragm includes diaphragm sheets. Each diaphragm sheet have a fixing end connected with the support column and a free end suspended above the cavity. The limit element includes a limit part arranged apart from the piezoelectric diaphragm to limit the free ends in vibration directions of the diaphragm sheets, and an edge fixing plate connected with the outer edge of the limit part and arranged on the ring base. When the diaphragm sheets greatly deform upwards under impact force, deformation of the diaphragm sheets can be controlled, and the diaphragm sheets are protected to prevent the diaphragm sheets from breaking, thereby improving the stability of the piezoelectric MEMS microphone.

Abstract: The invention provides a piezoelectric micro-electromechanical system (MEMS) microphone includes a base with a cavity and a piezoelectric diaphragm arranged on the base. The base has a ring base and a support column. The piezoelectric diaphragm includes a plurality of diaphragm sheets. Each diaphragm sheet has a fixing end connected with the support column and a free end suspended above the cavity. The widths of the diaphragm sheets are gradually increased from the fixing ends to the free ends. According to the piezoelectric MEMS microphone provided by the invention, under sound pressure, the free ends vibrate, wide free ends drive short fixing ends, and the diaphragm sheets close the fixing ends generate greater deformation to generate more charge. Therefore, the sensitivity can be further improved.

Abstract: The present invention provides a piezoelectric MEMS microphone having a base with a cavity, a piezoelectric diaphragm, and a restraining element. The base has a ring base circumferentially forming a cavity, a support column. The piezoelectric diaphragm includes diaphragm sheets each having a fixing end connected to a support column and a free end suspended over the cavity. The restraining element has one end fixedly connected to the free end, the other end connected to the part on the base that is not connected to the fixing end. The piezoelectric MEMS microphone of the invention can constrain the deformation of the diaphragm sheet, thereby improving the resonant frequency of the piezoelectric diaphragm, reducing the noise of the whole piezoelectric MEMS microphone.

Abstract: The present disclosure provides an MEMS microphone including a base having a rear cavity and a capacitor system disposed on the base. The capacitor system includes a rear plate and a diaphragm that are spaced relatively apart to form an acoustic cavity. A piezoelectric diaphragm is attached to a side of the diaphragm, the side being away from the acoustic cavity. The piezoelectric diaphragm, under the deformation effect of the diaphragm, deforms to generate and output charges. Therefore, the MEMS microphone can output two groups of electrical signals, one group of electrical signals output by the capacitor system and one group of electrical signals output by the piezoelectric diaphragm, thereby sensitivity of the microphone is improved.

Abstract: Provided is a piezoelectric type and capacitive type combined MEMS microphone, comprising a base with a back cavity and a capacitor system arranged on the base; wherein, the capacitor system comprises a back plate and a diaphragm; the back plate is opposite to and apart from the diaphragm to form a first sound cavity; a piezoelectric diaphragm structure is between the capacitor system and the base; a second sound cavity is formed between the capacitor system and the piezoelectric diaphragm structure; the second sound cavity is at least in communication with the first sound cavity or the back cavity; the piezoelectric type and capacitive type combined MEMS microphone can output two groups of electric signals comprising a group of electric signals output from the capacitor system and a group of electric signals output from the piezoelectric diaphragm structure, thus improving sensitivity of the microphone.

Abstract: The present application discloses an organic electroluminescent device comprising carrier transport layers. The carrier transport layers include an electron transport layer and/or a hole transport layer, at least one of the carrier transport layers is doped with inert material having a refractive index less than 1.5. The present application also provides a manufacturing method of the above-mentioned organic electroluminescent device.

Abstract: The present invention discloses a thermally activated delayed fluorescence material and application thereof in an organic electroluminescence device. The thermally activated delayed fluorescence material is a compound having the general structure of Formula I or Formula II: In Formula I and Formula II, R1 is a cyano, p is 1, 2 or 3, q is 1, 2 or 3, m is 1 or 2, n is 1 or 2, Ar1 is a phenyl substituted with one or more groups selected from C1-6 alkyl, methoxy, ethoxy, or phenyl, Ar2 and Ar3 are selected from the following groups: and X is bromine or iodine. The present invention further discloses application of the thermally activated delayed fluorescence material as a host material or a luminescent dye of a luminescent layer of an organic electroluminescence device.

Abstract: The present invention discloses a transparent OLED device, which comprises a plurality of pixels, each pixel comprising an organic functional layer, a first transparent electrode and a second transparent electrode being disposed on both sides of the organic functional layer, a reflective electrode being disposed on one side of the organic functional layer, the area of the reflective electrode being less than that of the organic functional layer. With regard to the transparent OLED device, by providing a reflective electrode, a combination of a light-emitting device over a microdomain is combined with a transparent light-emitting device, such that the luminance on both sides of a transparent OLED device can be respectively adjusted to be the same or different as required. The present invention can be applied to the field of transparent illumination or display.