Abstract: The invention provides antibodies, and antigen-binding fragments thereof, that specifically bind to E-selectin. The invention includes uses, and associated methods of using the antibodies, and antigen-binding fragments thereof.

Abstract: The invention provides antibodies, and antigen-binding fragments thereof, that specifically bind to E-selectin. The invention includes uses, and associated methods of using the antibodies, and antigen-binding fragments thereof.

Abstract: Systems, methods, and non-transitory computer-readable media can determine that broadcasting of a live content stream has concluded. The concluded live content stream is converted to a post live media content item. The post live media content item corresponding to the concluded live content stream is published through the social networking system. The post live media content item remains accessible through the social networking system for a pre-determined period of time.

Abstract: A water-cooling heat dissipation device includes a water tank, a water source, a pump, a pressure detector and a circulation pipe. The water tank includes an outlet/inlet through which water flows. The pressure detector is connected to the outlet/inlet and seals the outlet/inlet. The pressure detector detects the volume of the liquid in the water tank and generates a pressure signal. A warning device includes a temperature detection unit, a volume detection unit, a receiving unit, a processing unit, a display unit and a buzzer. The temperature detection unit detecting the temperature of the liquid in the circulation pipe to generate a temperature signal. The volume detection unit detects the speed of the liquid in the circulation pipe to generate a volume signal. The temperature signal, the volume signal and the pressure signal are monitored to protect water-cooling heat dissipation device by high temperature.

Abstract: The invention provides antibodies, and antigen-binding fragments thereof, that specifically bind to E-selectin. The invention includes uses, and associated methods of using the antibodies, and antigen-binding fragments thereof.

Abstract: An apparatus comprises an air inlet configured to receive an inlet airflow. The inlet airflow comprises a process airflow and a bypass airflow. An evaporator unit receives a flow of refrigerant and is cools the process airflow by facilitating heat transfer from the process airflow to the flow of refrigerant. A condenser unit receives the flow of refrigerant and (1) reheats the process airflow by facilitating heat transfer from the flow of refrigerant to the process airflow, and (2) heats the bypass airflow by facilitating heat transfer from the flow of refrigerant to the bypass airflow. The process airflow is discharged via a process airflow outlet and the bypass airflow is discharged via a bypass airflow outlet.

Abstract: An apparatus comprises an air inlet configured to receive an inlet airflow. The inlet airflow comprises a process airflow and a bypass airflow. An evaporator unit receives a flow of refrigerant and is cools the process airflow by facilitating heat transfer from the process airflow to the flow of refrigerant. A condenser unit receives the flow of refrigerant and (1) reheats the process airflow by facilitating heat transfer from the flow of refrigerant to the process airflow, and (2) heats the bypass airflow by facilitating heat transfer from the flow of refrigerant to the bypass airflow. The process airflow is discharged via a process airflow outlet and the bypass airflow is discharged via a bypass airflow outlet.

Abstract: A virtual reality operation platform structure comprises a main virtual frame, a virtual reality operation processing module, a menu module, an output checking module, a clearing module, and an accounting module. The menu module is built-in the main virtual frame and includes a housing menu defaulted a plurality of housings, a motherboard menu defaulted a plurality of motherboards, and a heat dissipation assembly menu defaulted a plurality of elements. Each element is virtually electrically coupled to the motherboard with the virtual reality operation processing module. The output checking module is connected to the menu module for checking an output performance of the motherboard and then generating a performance form. The clearing module is connected to the menu module for processing the re-selection of the menu module. The accounting module is connected to the menu module and generates a list.

Abstract: A virtual reality operation platform structure comprises a main virtual frame, a virtual reality operation processing module, a menu module, an output checking module, a clearing module, and an accounting module. The menu module is built-in the main virtual frame and includes a housing menu defaulted a plurality of housings, a motherboard menu defaulted a plurality of motherboards, and a heat dissipation assembly menu defaulted a plurality of elements. Each element is virtually electrically coupled to the motherboard with the virtual reality operation processing module. The output checking module is connected to the menu module for checking an output performance of the motherboard and then generating a performance form. The clearing module is connected to the menu module for processing the re-selection of the menu module. The accounting module is connected to the menu module and generates a list.

Abstract: An apparatus comprises an air inlet configured to receive an inlet airflow. The inlet airflow comprises a process airflow and a bypass airflow. An evaporator unit receives a flow of refrigerant and is cools the process airflow by facilitating heat transfer from the process airflow to the flow of refrigerant. A condenser unit receives the flow of refrigerant and (1) reheats the process airflow by facilitating heat transfer from the flow of refrigerant to the process airflow, and (2) heats the bypass airflow by facilitating heat transfer from the flow of refrigerant to the bypass airflow. The process airflow is discharged via a process airflow outlet and the bypass airflow is discharged via a bypass airflow outlet.

Abstract: An apparatus comprises an air inlet configured to receive an inlet airflow. The inlet airflow comprises a process airflow and a bypass airflow. An evaporator unit receives a flow of refrigerant and is cools the process airflow by facilitating heat transfer from the process airflow to the flow of refrigerant. A condenser unit receives the flow of refrigerant and (1) reheats the process airflow by facilitating heat transfer from the flow of refrigerant to the process airflow, and (2) heats the bypass airflow by facilitating heat transfer from the flow of refrigerant to the bypass airflow. The process airflow is discharged via a process airflow outlet and the bypass airflow is discharged via a bypass airflow outlet.

Abstract: An apparatus comprises an air inlet configured to receive an inlet airflow. The inlet airflow comprises a process airflow and a bypass airflow. An evaporator unit receives a flow of refrigerant and is cools the process airflow by facilitating heat transfer from the process airflow to the flow of refrigerant. A condenser unit receives the flow of refrigerant and (1) reheats the process airflow by facilitating heat transfer from the flow of refrigerant to the process airflow, and (2) heats the bypass airflow by facilitating heat transfer from the flow of refrigerant to the bypass airflow. The process airflow is discharged via a process airflow outlet and the bypass airflow is discharged via a bypass airflow outlet.

Abstract: A cross-flow heat exchanger, method of making a cross-flow heat exchanger, and a dehumidifier are provided. The cross-flow heat exchanger has an axial flow path extending through the heat exchanger from an inlet to an outlet and a transverse flow path oriented transversely to the axial flow path and extending through the heat exchanger from an inlet to an outlet. The transverse flow path is adjacent to and separate from the axial flow path. The surface area of the inlet of the axial flow path is less than the surface area of the outlet of the axial flow path. In a preferred embodiment, the heat exchanger has an exterior shape that is trapezoidal.

Abstract: A water cooling heat sink unit includes a base contacting an electronic part with its outside, and the inside of the base has a first groove, a second groove, a main inlet and a main outlet. The first groove communicates with the main outlet and has a first guide portion. The second groove has a second guide portion. A cover is mounted to the inside of the base and has a first corresponding slot, a second corresponding slot, and a corresponding inlet to respectively communicate with the first groove, the second groove and the main inlet. The first corresponding slot has a first corresponding portion which communicates with the first guide portion. The second corresponding slot has a second corresponding portion which communicates with the second guide portion. Cool water is introduced from the first guide portion, the second guide portion, the main inlet and the main outlet.

Abstract: The present invention discloses a method for handover of User Equipment (UE) a service connection being made via the UE, comprises: if fast cells are set up as base stations starts up, handover from a normal cell to a first fast cell with a radio bearer set up therein when the UE moving speed exceeds a threshold, set up a same radio bearer at a current fast cell as the radio bearer set up at the first fast cell when the UE is leaving the first fast cell for the current fast cell adjacent to the first fast cell, release the radio bearer at the first fast cell after the UE leaves the first fast cell, and re-registering into an adjacent normal cell when the service connection is terminated, or handover to the adjacent normal cell from the current fast cell when the measured moving speed of the UE is below the threshold.