Abstract: A wick, a preparation method thereof, and a temperature equalization board are proposed. The wick is configured for being installed on a housing, and the housing includes cover plates. First diversion grooves and second diversion grooves are formed in both sides of the wick, respectively. The first diversion grooves are configured for forming first capillary channels together with the cover plates. The first capillary channels and the second diversion grooves are configured for connecting a heat source area with a heat dissipation area. Capillary through holes for working liquid and vapor of working liquid to pass through are formed in the first diversion groove.

Abstract: A heat pipe and a geothermal energy collecting device. The heat pipe includes a sealing member which is provided with channels; a first pipe body, one end of the first pipe body has an opening, and an other end of the first pipe body is sealed by the sealing member, which has a first chamber, first heat transfer members which are connected to the sealing member and located at one side of the sealing member, each of the first heat transfer members has a first cavity; and second heat transfer members which are connected to the sealing member and located at an other side of the sealing member, each of second heat transfer members has a second cavity configured to communicate with the first cavity of a corresponding one of the first heat transfer members via a respective one of the channels.

Abstract: A monocrystal furnace with lateral feeding includes: a furnace body, a feeding apparatus, and a thermal insulation layer, a sealing member, a crucible and a lifting apparatus that are provided within the furnace body. The thermal insulation layer is located between the crucible and the furnace body, a first through-hole is provided on a side portion of the furnace body, and a second through-hole is provided in a position of the thermal insulation layer opposite to the first through-hole; the lifting apparatus is connected to the sealing member and is used to drive the sealing member to switch between a rising state and a falling state; in the rising state, the sealing member rises, and the feeding apparatus is capable of passing through the first through-hole and the second through-hole to be opposite to an opening of the crucible.

Abstract: Disclosed are a power battery module, a power battery pack and a thermal management method of the power battery module. The power battery module includes a plurality of battery cell units, a plurality of heat pipe structures and a plurality of liquid channels, wherein one end of the heat pipe structure is embedded between the battery cell units, and the liquid channel is connected to the other end, which is not embedded into the battery cell unit, of the heat pipe structure, the battery cell unit includes a positive current collector, a positive electrode material, a diaphragm, a negative electrode material and a negative current collector which are arranged in sequence, and two sides of the heat pipe structure are tightly attached to the positive current collector or the negative current collector respectively.

Abstract: Disclosed in the present disclosure is a manufacturing method for a 3D microelectrode. The manufacturing method includes the following steps: (1) manufacturing a 3D model of a 3D microelectrode; (2) pouring a flexible material into the 3D model, and performing demolding so as to form a flexible mold having a cavity, wherein the cavity of the flexible mold can be fitted to the 3D model; (3) performing silanization treatment on the flexible mold, then pouring a flexible material into the surface of the flexible mold having the cavity, and performing demolding so as to form a flexible 3D microelectrode substrate; and (4) manufacturing a conductive layer on the flexible 3D microelectrode substrate so as to form the 3D microelectrode. In the present disclosure, a 3D microelectrode having an ultrahigh microcolumn height can be manufactured by using a 3D printing technology and a two-time mold-reversing method.

Abstract: A heat pipe and a geothermal energy collecting device. The heat pipe includes a sealing member which is provided with channels; a first pipe body, one end of the first pipe body has an opening, and an other end of the first pipe body is sealed by the sealing member, which has a first chamber, first heat transfer members which are connected to the sealing member and located at one side of the sealing member, each of the first heat transfer members has a first cavity; and second heat transfer members which are connected to the sealing member and located at an other side of the sealing member, each of second heat transfer members has a second cavity configured to communicate with the first cavity of a corresponding one of the first heat transfer members via a respective one of the channels.

Abstract: A control method includes displaying a first interface, receiving first input of a user acting on a non-navigation button, displaying, in response to the first input, at least one of an artificial intelligence (AI) function entry interface and a scene service task interface that are corresponding to the non-navigation button, where the first interface includes a navigation bar, the navigation bar is provided with a navigation button and at least one non-navigation button, when the navigation button is triggered, an electronic device performs at least one of returning to a previous interface, jumping to a home interface, and invoking an interface of an application program accessed within a preset time up to a current moment, and when the at least one non-navigation button is triggered, the electronic device displays at least one of an AI function entry interface and a scene service task interface.

Abstract: A flat-plate heat pipe and a preparation method thereof, and a heat exchanger are provided. The flat-plate heat pipe includes an upper shell (11) and a lower shell (12); the upper shell (11) and the lower shell (12) are assembled with each other to form a flat-plate shell (10) with a sealed cavity; the sealed cavity is filled with a phase change working medium; a capillary wick (20) is arranged in the flat-plate shell (10); and a surface of the capillary wick (20) has a micro-nano structure. By means of the arrangement of the above capillary wick having the micro-nano structure on the surface thereof, the flat-plate heat pipe has excellent heat conductivity and high resistance to gravity, and is flexible in use and arrangement.

Abstract: A control method includes displaying a first interface, receiving first input of a user acting on a non-navigation button, displaying, in response to the first input, at least one of an artificial intelligence (AI) function entry interface and a scene service task interface that are corresponding to the non-navigation button, where the first interface includes a navigation bar, the navigation bar is provided with a navigation button and at least one non-navigation button, when the navigation button is triggered, an electronic device performs at least one of returning to a previous interface, jumping to a home interface, and invoking an interface of an application program accessed within a preset time up to a current moment, and when the at least one non-navigation button is triggered, the electronic device displays at least one of an AI function entry interface and a scene service task interface.

Abstract: The present invention relates to methods and systems for detecting one or more analytes in a sample and/or for classifying a sample. In particular, the present invention relates to methods and systems which can be used to detect the analytes in real time and which rely on flowing through a microfluidic device one or more types of sensor molecule each comprising a domain that binds one or more analytes, a chemiluminescent donor domain and an acceptor domain, wherein the separation and relative orientation of the chemiluminescent donor domain and the acceptor domain, in the presence and/or the absence of analyte, is within ±50% of the Forster distance.

Abstract: A control method includes displaying a first interface, receiving first input of a user acting on a non-navigation button, displaying, in response to the first input, at least one of an artificial intelligence (AI) function entry interface and a scene service task interface that are corresponding to the non-navigation button, where the first interface includes a navigation bar, the navigation bar is provided with a navigation button and at least one non-navigation button, when the navigation button is triggered, an electronic device performs at least one of returning to a previous interface, jumping to a home interface, and invoking an interface of an application program accessed within a preset time up to a current moment, and when the at least one non-navigation button is triggered, the electronic device displays at least one of an AI function entry interface and a scene service task interface.

Abstract: The present invention relates to methods and systems for detecting one or more analytes in a sample and/or for classifying a sample. In particular, the present invention relates to methods and systems which can be used to detect the analytes in real time and which rely on flowing through a microfluidic device one or more types of sensor molecule each comprising a domain that binds one or more analytes, a chemiluminescent donor domain and an acceptor domain, wherein the separation and relative orientation of the chemiluminescent donor domain and the acceptor domain, in the presence and/or the absence of analyte, is within ±50% of the Forster distance.

Abstract: The present invention relates to methods and systems for detecting one or more analytes in a sample and/or for classifying a sample. In particular, the present invention relates to methods and systems which can be used to detect the analytes in real time and which rely on flowing through a microfluidic device one or more types of sensor molecule each comprising a domain that binds one or more analytes, a chemiluminescent donor domain and an acceptor domain, wherein the separation and relative orientation of the chemiluminescent donor domain and the acceptor domain, in the presence and/or the absence of analyte, is within +50% of the Forster distance.

Abstract: The present invention relates to methods and systems for detecting one or more analytes in a sample and/or for classifying a sample. In particular, the present invention relates to methods and systems which can be used to detect the analytes in real time and which rely on flowing through a microfluidic device one or more types of sensor molecule each comprising a domain that binds one or more analytes, a chemiluminescent donor domain and an acceptor domain, wherein the separation and relative orientation of the chemiluminescent donor domain and the acceptor domain, in the presence and/or the absence of analyte, is within +50% of the Forster distance.

Abstract: A method of mixing (10), including: providing a fluid (10) in a well (6) so as to establish an acoustic field gradient; and applying an acoustic signal to cause mixing within a fluid (3).

Abstract: This computer Chinese character input method mainly includes: Select 10 elements corresponding to the 10 simplified Chinese character strokes, which are and Select 46 elements corresponding to the 46 stroke combination sets, whose representative visual representations are: Assign the above 10 elements and 46 elements to keys on a computer keyboard; Determine desired characters based on the elements input by a user using the keyboard mentioned above or other apparatus.

Abstract: A method of mixing (10), including: providing a fluid (10) in a well (6) so as to establish an acoustic field gradient; and applying an acoustic signal to cause mixing within a fluid (3).

Abstract: This computer Chinese character input method mainly includes: Select 10 elements corresponding to the 10 simplified Chinese character strokes, which are and Select 46 elements corresponding to the 46 stroke combination sets, whose representative visual representations are: Assign the above 10 elements and 46 elements to keys on a computer keyboard; Determine desired characters based on the elements input by a user using the keyboard mentioned above or other apparatus.