An electrically driven pump is provided, which includes an impeller. The impeller includes an upper plate, blades and a lower plate. The blades are formed on a lower surface of the upper plate, the blades include first blades and second blades, and a length of each of the first blades is greater than a length of each of the second blades. The first blades are uniformly distributed along a circumference of the upper plate. The first blades and the second blades are distributed alternately in the circumferential direction. The first blades each include a first head portion and a first tail portion, the second blade includes a second head portion and a second tail portion, and the first tail portion and the second tail portion are aligned with outer edge of the upper plate. The impeller arranged in such manner facilitates the improvement of hydraulic efficiency and lift.

There is provided a method for analyzing a vibration damping structure in which a tube bundle disposed in a fluid is supported by a vibration damping member disposed in a gap between tubes included in the tube bundle. The method includes a model making step of making a FEM model corresponding to the vibration damping structure, an error setting step of setting an error parameter for a parameter relating to an element included in the FEM model, and an analysis step of performing structural analysis by a finite-element method using the FEM model in which the error parameter is set.

There is provided a method for analyzing a vibration damping structure in which a tube bundle disposed in a fluid is supported by a vibration damping member disposed in a gap between tubes included in the tube bundle. The method includes a model making step of making a FEM model corresponding to the vibration damping structure, an error setting step of setting an error parameter for a parameter relating to an element included in the FEM model, and an analysis step of performing structural analysis by a finite-element method using the FEM model in which the error parameter is set.

An apparatus is provided for detecting the quality of a heat pipe. The apparatus has an infrared (IR) thermal imager bound with a data computing-and-analyzing program to detect thermal conductivity quality and vacuum quality of the heat pipe. An online overall detection is thus provided to quickly detect the quality of the heat pipe without damage for efficient quality control. Requirements of quality detection are met for mass production of heat pipes. The apparatus comprises the heat pipe to be tested; a tape adhered to a surface of the heat pipe; a fixed base for disposing the heat pipe; a heating device in an allocation space of the fixed base; the IR thermal imager located facing to the tape; a signal line connected to the IR thermal imager; and an electronic device connected to the IR thermal imager through the signal line.

An apparatus is provided for detecting the quality of a heat pipe. The apparatus has an infrared (IR) thermal imager bound with a data computing-and-analyzing program to detect thermal conductivity quality and vacuum quality of the heat pipe. An online overall detection is thus provided to quickly detect the quality of the heat pipe without damage for efficient quality control. Requirements of quality detection are met for mass production of heat pipes. The apparatus comprises the heat pipe to be tested; a tape adhered to a surface of the heat pipe; a fixed base for disposing the heat pipe; a heating device in an allocation space of the fixed base; the IR thermal imager located facing to the tape; a signal line connected to the IR thermal imager; and an electronic device connected to the IR thermal imager through the signal line.

The present technology provides power generation using thermoradiative cell (TRC) structures, which generate electricity by radiating heat from a hotter area/body to a cooler area/body. The TRC structures may be used in conjunction with photovoltaic (PV) cells on a common platform as a power generation system. In some scenarios, the platform may be a high altitude platform (HAP). Here, the TRC structures may be arranged or aligned to radiate heat towards space or otherwise in a direction generally away from the Earth's surface. The electricity generated by the TRC structures is provided to a power supply, for instance to recharge batteries of the power supply. The TRC structures may be intersubband TRC structures. In some configurations, the TRC structures are co-located on the same side of a panel as the PV cells. In other configurations, the TRC structures are remote from the PV cells.

A cover (25) is intended to be attached to a housing (2) of a heat exchanger (1). The cover (25) comprises a wall (26) that is intended to close off an orifice (5) for introducing a heat exchange core into the housing (2). The wall (26) is configured to allow the cover (25) to be attached removably to the housing (2) and has a raised edge (27). The cover (25) also comprises means (30) for mechanical reinforcement of the wall (26). The invention also relates to a heat exchange core (7) comprising the cover (25), to a heat exchanger (1) comprising the core (7), and to an air intake module for a motor vehicle combustion engine comprising the heat exchanger (1).

A cover (25) is intended to be attached to a housing (2) of a heat exchanger (1). The cover (25) comprises a wall (26) that is intended to close off an orifice (5) for introducing a heat exchange core into the housing (2). The wall (26) is configured to allow the cover (25) to be attached removably to the housing (2) and has a raised edge (27). The cover (25) also comprises means (30) for mechanical reinforcement of the wall (26). The invention also relates to a heat exchange core (7) comprising the cover (25), to a heat exchanger (1) comprising the core (7), and to an air intake module for a motor vehicle combustion engine comprising the heat exchanger (1).

A mount configured for use with a recirculation heat exchanger of an aircraft environmental control is provided including a rectangular base having a length of about 14 inches (35.56 cm) and a width of about 6 inches (15.24 cm). A support extends vertically from the base. A top surface of the support is arranged at a 10 angle below a horizontal plane.

A gas injection device according to an example includes a support portion having a first sidewall extending at a first slope, a sealing cap including an elastic material and having a second sidewall extending at a second slope, and a pipe connection portion having a conduit shape including a through-hole extending in a first direction, the pipe connection portion having one end portion connected to one end portion of the sealing cap, wherein the first sidewall and the second sidewall are arranged to face each other, and a first inclination angle formed by the first direction and the first sidewall is greater than a second inclination angle formed by the first direction and the second sidewall.