Abstract: A gas drying system (100) includes an inflow pipe (111), a drying tower (120), and an outflow pipe (112). In the inflow pipe, gas that contains moisture and is mixed with oil flows. The drying tower is packed with desiccant. The drying tower dries gas entering from the inflow pipe with the desiccant. In the outflow pipe, gas after being dried in the drying tower flows. The desiccant has a plurality of pores into which the oil penetrates, the plurality of pores having a pore size greater than or equal to a size of molecules of the oil.

Abstract: A cam portion (22) is attached to a first position (111) on a measurement target (110). A moving portion (24) is attached to a second position (112) on the measurement target (110) and is movable with respect to the cam portion (22) in an expanding/contracting direction of the measurement target (110). A strain portion (25) is attached to the moving portion (24) so as to fit along the measurement target (110), and is pressed against the cam portion (22). A strain of the strain portion (25) changes when the measurement target (110) expands or contracts and the moving portion moves (24) accordingly. An optical fiber sensor (10) has a temperature measurement portion (16) for measuring a temperature, and a strain measurement portion (17) for measuring a strain, and is attached to the strain portion (25).

Abstract: To provide a temperature measurement system, which is capable of preventing distortion that occurs in a temperature measurement object from being transmitted to an optical fiber, and improving responsiveness of heat transfer from the temperature measurement object to the optical fiber. The temperature measurement system includes: a temperature measurement object; an optical fiber provided on the temperature measurement object; an intermediate material provided on the optical fiber; and a pressing jig which is provided on the temperature measurement object, and is configured to press the optical fiber against the temperature measurement object through intermediation of the intermediate material, wherein the optical fiber is expandable and contractible in a longitudinal direction of the optical fiber due to a change in a temperature of the optical fiber with respect to the temperature measurement object and the intermediate material.

Abstract: A solar power generation paddle includes a blanket that is stored by being taken up into a roll with using extension masts, and that is extended. Solar battery cells are disposed on one surface of the blanket, and thermoelectric conversion elements are disposed on the other surface of the blanket. A plurality of heat dissipation members are disposed on surfaces of the thermoelectric conversion elements which are opposite to surfaces near the blanket, along an extending direction, to cover the thermoelectric conversion elements.

Abstract: A honeycomb sandwich structure in which moisture absorption deformation can be sufficiently suppressed and a method for manufacturing the same are provided. The honeycomb sandwich structure includes: a honeycomb core having a recess in a mesh of a carbon fiber fabric; a pair of face plates; a resin layer which fills a part of the recesses; and a water-impermeable film which covers an exposed area including surfaces of the resin layer and the honeycomb core, wherein the recess includes an unfilled part, the unfilled part is a part of the recess that is closer to the opening of the recess, and the unfilled part is not filled with the resin layer.

Abstract: A solar power generation paddle includes a blanket that is stored by being taken up into a roll with using extension masts, and that is extended. Solar battery cells are disposed on one surface of the blanket, and thermoelectric conversion elements are disposed on the other surface of the blanket. A plurality of heat dissipation members are disposed on surfaces of the thermoelectric conversion elements which are opposite to surfaces near the blanket, along an extending direction, to cover the thermoelectric conversion elements.

Abstract: A honeycomb sandwich structure in which moisture absorption deformation can be sufficiently suppressed and a method for manufacturing the same are provided. The honeycomb sandwich structure includes: a honeycomb core having a recess in a mesh of a carbon fiber fabric; a pair of face plates; a resin layer which fills a part of the recesses; and a water-impermeable film which covers an exposed area including surfaces of the resin layer and the honeycomb core, wherein the recess includes an unfilled part, the unfilled part is a part of the recess that is closer to the opening of the recess, and the unfilled part is not filled with the resin layer.

Abstract: A honeycomb core includes carbon fiber having four or more different fiber directions, and when a ribbon direction is set as an X axis direction, a cell width direction is set as a Y axis direction, and a direction that is orthogonal to the ribbon direction and the cell width direction is set as a Z axis direction. A condition in which angles formed by the X axis direction and the respective fiber directions of the carbon fiber are set at ?45 degrees, 0 degrees, 45 degrees, and 90 degrees is set as a reference condition. The respective fiber directions are rotated from the reference condition by a fixed rotation angle so that none of the fiber directions are parallel to the X axis direction.

Abstract: An optical fiber temperature sensor includes: a substrate having a first substrate main body, and a second substrate main body, which has a coefficient of thermal expansion larger than that of the first substrate main body, and is bonded to the first substrate main body; and an optical fiber having a FBG sensor portion for measuring a temperature from a relationship between a Bragg wavelength and the temperature, and the optical fiber is configured to be embedded in the second substrate main body so that the FBG sensor portion is positioned in the second substrate main body.

Abstract: A honeycomb sandwich structure includes a main body portion having a first skin material, a second skin material, and a honeycomb core sandwiched between the first skin material and the second skin material, and a thermoelectric conversion module that generates power using a temperature difference between a high temperature side module front surface and a low temperature side module rear surface. The thermoelectric conversion module is embedded in a main body portion such that at least one of the module front surface and the module rear surface is in a state being exposed from the main body portion, and as a result, a temperature difference is generated between the module front surface and the module rear surface.

Abstract: An optical fiber temperature sensor includes: a substrate having a first substrate main body, and a second substrate main body, which has a coefficient of thermal expansion larger than that of the first substrate main body, and is bonded to the first substrate main body; and an optical fiber having a FBG sensor portion for measuring a temperature from a relationship between a Bragg wavelength and the temperature, and the optical fiber is configured to be embedded in the second substrate main body so that the FBG sensor portion is positioned in the second substrate main body.

Abstract: A honeycomb core includes carbon fiber having four or more different fiber directions, and when a ribbon direction is set as an X axis direction, a cell width direction is set as a Y axis direction, and a direction that is orthogonal to the ribbon direction and the cell width direction is set as a Z axis direction. A condition in which angles formed by the X axis direction and the respective fiber directions of the carbon fiber are set at ?45 degrees, 0 degrees, 45 degrees, and 90 degrees is set as a reference condition. The respective fiber directions are rotated from the reference condition by a fixed rotation angle so that none of the fiber directions are parallel to the X axis direction.

Abstract: A honeycomb sandwich structure includes a main body portion having a first skin material, a second skin material, and a honeycomb core sandwiched between the first skin material and the second skin material, and a thermoelectric conversion module that generates power using a temperature difference between a high temperature side module front surface and a low temperature side module rear surface. The thermoelectric conversion module is embedded in a main body portion such that at least one of the module front surface and the module rear surface is in a state being exposed from the main body portion, and as a result, a temperature difference is generated between the module front surface and the module rear surface.

Abstract: An electric unit is attached to a power unit including a motor-generator, the power unit being disposed in a power unit mounting chamber that is formed at a front of a vehicle and separated from a vehicle cabin by a partition wall. The electric unit includes: a high-voltage component including an electric power conversion device of a relatively high voltage, the electric power conversion device converting an electric power between a DC electric power and an AC electric power for the motor-generator; and a low-voltage component including a control device of a relatively low voltage, the control device controlling the electric power conversion device. The high-voltage component and the low-voltage component are accommodated in an accommodation case. Inside the accommodation case, the high-voltage component is arranged toward the front of the vehicle, and the low-voltage component is arranged toward a rear of the vehicle.

Abstract: An electric unit is attached to a power unit including a motor-generator, the power unit being disposed in a power unit mounting chamber that is formed at a front of a vehicle and separated from a vehicle cabin by a partition wall. The electric unit includes: a high-voltage component including an electric power conversion device of a relatively high voltage, the electric power conversion device converting an electric power between a DC electric power and an AC electric power for the motor-generator; and a low-voltage component including a control device of a relatively low voltage, the control device controlling the electric power conversion device. The high-voltage component and the low-voltage component are accommodated in an accommodation case. Inside the accommodation case, the high-voltage component is arranged toward the front of the vehicle, and the low-voltage component is arranged toward a rear of the vehicle.

Abstract: The present invention provides a blow molding machine comprising a plurality of pillars 5 set up facing on a seat 4 above a base 3 located above a blow mold 2; a stationary platen 6 provided bridging on the top portions of the pillars 5; a moving cylinder 7 set on both side of the stationary platen 6; and a holding plate 9 of blow-core members, which is connected with a piston rod 7a of the moving cylinder 7, and in which the pillars 5 are inserted vertically movable; and a clamp plate 15 projecting at both ends from the holding plate 9 outwardly, and a clamp block 16, which includes internally a pair of hydraulic cylinders 18 to clamp the clamp plate 15 from both sides with rams when the holding plate 9 is in the lower limit position, which is provided on both sides of the seat 4.

Abstract: A linear motor includes a row of permanent magnets fixed at a position above a stator, and a plurality of magnetic pole members fixed at a position below a movable member. The row of permanent magnets is formed from N poles and S poles alternately arranged at given intervals. The plurality of magnetic pole members extend toward the row of permanent magnets and in a vertical direction and have the same height. The extremities of the magnetic pole members oppose the row of permanent magnets via an air gap. The magnetic pole members are coated with insulators, and a former-wound coil is fitted around the insulator. The part of the magnetic pole member coated with the insulator, except for the extremity thereof, is made thin by the amount corresponding to the thickness of the insulator.

Abstract: A linear motor includes a row of permanent magnets fixed at a position above a stator, and a plurality of magnetic pole members fixed at a position below a movable member. The row of permanent magnets is formed from N poles and S poles alternately arranged at given intervals. The plurality of magnetic pole members extend toward the row of permanent magnets and in a vertical direction and have the same height. The extremities of the magnetic pole members oppose the row of permanent magnets via an air gap. The magnetic pole members are coated with insulators, and a former-wound coil is fitted around the insulator. The part of the magnetic pole member coated with the insulator, except for the extremity thereof, is made thin by the amount corresponding to the thickness of the insulator.

Abstract: A linear motor includes a row of permanent magnets fixed at a position above a stator, and a plurality of magnetic pole members fixed at a position below a movable member. The row of permanent magnets is formed from N poles and S poles alternately arranged at given intervals. The plurality of magnetic pole members extend toward the row of permanent magnets and in a vertical direction and have the same height. The extremities of the magnetic pole members oppose the row of permanent magnets via an air gap. The magnetic pole members are coated with insulators, and a former-wound coil is fitted around the insulator. The part of the magnetic pole member coated with the insulator, except for the extremity thereof, is made thin by the amount corresponding to the thickness of the insulator.

Abstract: A movable platen 5 which is provided between a base platen and a stationary platen, is connected to a mold clamping ram13 of a mold clamping cylinder 8. A pair of mold clamping cylinders 8 include a cylinder of which the inner diameter of their lower end portions is smaller than the inner diameter of the other portions, the mold clamping ram 13 having a piston 14 which fits to the lower end, a booster ram 16 which is inserted into the mold clamping ram, and a circulation device 20 which is provided to a side portion of the mold clamping cylinder.