Abstract: A vehicle wiring structure equipped with a pipe (20), the two ends of which are inserted into the vehicle through an electrical-load-side through-hole and a power-source-side through-hole provided in the floor, and power cables (40a, 40b, 41), which are inserted in the pipe (20) and connect a power source and electrical loads. The power cables pulled out of the end part of the pipe (20) inserted through the power-source-side through-hole (60) are restrained by a first cable guide (70) provided inside the vehicle and are wired to a power source connection part, while the end part of the pipe (20) inserted through the power-source-side through-hole (60) reaches as far as the position where the first cable guide (70) is provided. The pipe (20) is supported by a through-hole seal member (61) that has a pipe through-hole (62) through which the pipe (20) passes and that closes the power-source-side through-hole (60).

Abstract: A vehicle wiring structure equipped with a pipe (20), the two ends of which are inserted into the vehicle through an electrical-load-side through-hole and a power-source-side through-hole provided in the floor, and power cables (40a, 40b, 41), which are inserted in the pipe (20) and connect a power source and electrical loads. The power cables pulled out of the end part of the pipe (20) inserted through the power-source-side through-hole (60) are restrained by a first cable guide (70) provided inside the vehicle and are wired to a power source connection part, while the end part of the pipe (20) inserted through the power-source-side through-hole (60) reaches as far as the position where the first cable guide (70) is provided. The pipe (20) is supported by a through-hole seal member (61) that has a pipe through-hole (62) through which the pipe (20) passes and that closes the power-source-side through-hole (60).

Abstract: Disclosed is a vehicle wiring structure that uses a power cable to connect a power source and an electrical load disposed, inside a vehicle, with a space therebetween in the vehicle front-to-back direction. The vehicle wiring structure is provided with a metal pipe (20) which is disposed on vehicle floor under surface (61), between a position below where the power source is installed and a position below where the electrical load is installed, and two ends of which are inserted into the vehicle, and a power cable that is inserted through the metal pipe (20) and connects the power source and the electrical load. The metal pipe (20) is provided slanting from the two ends toward a bottommost part (21), in the vertical direction, and the bottommost part (21) is heated by heat released from CAT (51).

Abstract: A cooling apparatus for a vehicle electrical packaging unit that includes an inverter for a vehicle drive motor, a DC-DC converter for a vehicle control power source, and an electrical power converter for driving the electrical accessories, and cools them by heat exchange with cooling air. The cooling apparatus includes a first heat radiating plate for the inverter, a second heat radiating plate for the DC-DC converter, a third heat radiating plate for the electrical power converter, and connecting members that respectively connect the first heat radiating plate to the second heat radiating plate and the first heat radiating plate to the third heat radiating plate. Heat radiating fins of the first to third heat radiating plates are enclosed by the first heat radiating plate, second heat radiating plate, the third heat radiating plate, and the connecting members to form an air passage through which the cooling air passes.

Abstract: In a power supply unit disposed below a floor behind a seat, battery modules are disposed in a lower position, and a DC/DC converter and a motor driving inverter are disposed side by side in a vehicle width direction above the battery modules. Thus, cooling air flowing from the front side to the rear side of a vehicle body is divided into upper and lower portions to cool in parallel the DC/DC converter and the motor driving inverter on the upper side and the battery modules on the lower side. Thus, it is possible to simplify a passage of the cooling air to reduce the size of the entire power supply unit, and improve mountability of the power supply unit on the vehicle body. Also, it is possible to apply low temperature cooling air, before heat exchange, to the battery module, the DC/DC converter, and the motor driving inverter.

Abstract: A heat exchange core has a plurality of flat tubes laminated in a thickness direction, each flat tube defining an exhaust gas passage in which the exhaust gas flows. A plurality of coolant flow pass holes are formed in each of the flat tubes, wherein each of the coolant flow pass holes penetrates the flat tube in the thickness direction. The coolant flow pass holes of each flat tube are connected with the coolant flow pass holes of the other flat tubes, in order to respectively form a plurality of coolant flow passages through which liquid coolant flows, and the coolant flow pass holes of each coolant flow passages are communicated with each other in the laminated direction, so that the coolant flow passages are formed to be perpendicular to the exhaust gas passages.

Abstract: A power cable holding structure for a vehicle in which compressor power cables having a small outer diameter are disposed in the gaps between the outer surface of motor power cables having a large outer diameter and the inner surface of a protective pipe. Also, a method of assembling a power cable assembly comprising the steps of: inserting the other end side of the power cables with first connectors attached into one end portion into the protective pipe; disposing the small diameter compressor power cables in the gaps between the outer surface of the large diameter power cables and the inner surface of the protective pipe; and after applying bending work to the protective pipe in this state, adjusting the lengths of the other end portions of the power cables and attaching second connectors.

Abstract: In a power supply unit disposed below a floor behind a seat, battery modules are disposed in a lower position, and a DC/DC converter and a motor driving inverter are disposed side by side in a vehicle width direction above the battery modules. Thus, cooling air flowing from the front side to the rear side of a vehicle body is divided into upper and lower portions to cool in parallel the DC/DC converter 41 and the motor driving inverter on the upper side and the battery modules on the lower side. Thus, it is possible to simplify a passage of the cooling air to reduce the size of the entire power supply unit, and improve mountability of the power supply unit on the vehicle body. Also, it is possible to apply cooling air at low temperature before heat exchange to all the battery module, the DC/DC converter, and the motor driving inverter, thereby enhancing cooling effect.

Abstract: High-tension cables 7U, 7V, 7W connect an inverter 6 disposed outside an engine compartment with a motor/generator 3 disposed in the engine compartment, the high-tension cables 7U, 7V, 7W are individually passed through metallic protection pipes 30 under a floor of a vehicle, the protection pipes 30 are supported from an underside of the floor, and the high-tension cables 7U, 7V, 7W are passed through a protection tube 20 over a predetermined distance from the motor/generator 3 in the engine compartment.

Abstract: A cooling apparatus for a vehicle electrical packaging unit that includes an inverter for a vehicle drive motor, a DC-DC converter for a vehicle control power source, and an electrical power converter for driving the electrical accessories, and cools them by heat exchange with cooling air. The cooling apparatus includes a first heat radiating plate for the inverter, a second heat radiating plate for the DC-DC converter, a third heat radiating plate for the electrical power converter, and connecting members that respectively connect the first heat radiating plate to the second heat radiating plate and the first heat radiating plate to the third heat radiating plate. Heat radiating fins of the first to third heat radiating plates are enclosed by the first heat radiating plate, second heat radiating plate, the third heat radiating plate, and the connecting members to form an air passage through which the cooling air passes.

Abstract: A heat exchange core has a plurality of flat tubes laminated in a thickness direction, each flat tube defining an exhaust gas passage in which the exhaust gas flows. A plurality of coolant flow pass holes are formed in each of the flat tubes, wherein each of the coolant flow pass holes penetrates the flat tube in the thickness direction. The coolant flow pass holes of each flat tube are connected with the coolant flow pass holes of the other flat tubes, in order to respectively form a plurality of coolant flow passages through which liquid coolant flows, and the coolant flow pass holes of each coolant flow passages are communicated with each other in the laminated direction, so that the coolant flow passages are formed to be perpendicular to the exhaust gas passages.

Abstract: A thermoelectric generating device has a thermoelectric element which utilizes an exhaust gas from an engine as a high temperature heat source and an engine coolant as a low temperature heat source in order to generate electricity. An introducing passage introduces a part of the exhaust gas passed through the thermoelectric element into an intake of the engine. An introducing valve opens and closes the introducing passage. A controller controls an opening degree of the introducing valve according to a load of the engine.

Abstract: A cooling device for a high voltage electrical unit for a motor of a vehicle, includes: an inverter for controlling the motor that drives the vehicle; an electrical energy storing device for supplying electrical energy to the motor via the inverter; a downverter for decreasing source voltage of the electrical energy storing device, the downverter, the inverter, and the electrical energy storing device disposed under a seat of the vehicle in a concentrated manner; a fan, disposed under the seat, for moving cooling air to the electrical energy storing device and the inverter; an air inlet disposed under the seat and at an end of the seat as viewed in a width direction of the vehicle; and an air outlet disposed under the seat and at the other end of the seat as viewed in a width direction of the vehicle.

Abstract: A thermoelectric generator has a high temperature heat source part provided on a first passage through which a first fluid for cooling an engine flows, a low temperature heat source part provided on a second passage through which a second fluid having a temperature lower than that of the first fluid flows, and a thermoelectric element for producing electric power by a temperature difference produced between the high temperature heat source part and the low temperature heat source part. The first passage is included in a first circuit in which the engine and a first radiator for cooling the first fluid are connected in loop through a main passage. Further, the first passage is in parallel to the first radiator in the first circuit. The second passage is included in a second circuit that is separate from the first circuit and includes a second radiator for cooling the second fluid.

Abstract: A thermoelectric generator comprising: at least a high-temperature heat source using a high-temperature fluid; at least a low-temperature heat source using a low-temperature fluid lower in temperature than the high-temperature fluid; and a plurality of thermoelectric elements arranged in parallel between the high-temperature heat source and the low-temperature heat source; wherein at least selected one of the high-temperature heat source and the low-temperature heat source is connected with a frame surrounding the plurality of thermoelectric elements.

Abstract: A thermoelectric power generation system having a thermoelectric unit is provided for an engine, through which cooling water flows. A part of cooling water circulates through the engine and a radiator, where cooling water is cooled. Cooling water of a discharge side of the engine and that of a discharge side of the radiator are respectively used as a high-temperature side heat source and a low-temperature side heat source of the thermoelectric unit. Thus, the thermoelectric unit is provided with a steady temperature difference to generate power, without increasing a component number and deteriorating a cooling of the engine.

Abstract: In a cooling device, a condensation unit is constructed by stacking plural unit plates and two outer plates. The plural unit plates are superimposed in a plate-thickness direction between the outer plates, and three sheets of unit plates are also arranged in the planar direction. The radiating fins are provided such that the width of the base is substantially equal to the width of the unit plate, and are arranged in parallel on one of the outer plates in the same manner as the unit plate. According to this structure, the number of the unit plates arranged in parallel with the outer plates and the number of the radiating fins are increased or decreased, so that it is possible to easily change the size of a radiating unit in accordance with a necessary cooling capacity.

Abstract: A thermoelectric generator has a plurality of hot-side heat source portions, a plurality of cold-side heat source portions, a thermoelectric element, a hot-side communicator and a cold-side communicator. Hot fluid flows in the plurality of hot-side heat source portions, and cold fluid colder than the hot fluid flows in the plurality of cold-side heat source portions. The heat source portions are alternately stacked in such a manner of interposing the thermoelectric element between the hot-side heat source portion and the cold-side heat source portion. The hot-side communicator communicates the hot-side heat source portions, and the cold-side communicator communicates the plurality of cold-side heat source portions. Each of the hot-side communicator and the cold-side communicator has a distance adjuster for adjusting distances between the hot-side heat source portions and the cold-side heat source portions so as to bring them in contact with the thermoelectric elements in the stacking direction thereof.

Abstract: A power cable holding structure for a vehicle in which compressor power cables having a small outer diameter are disposed in the gaps between the outer surface of motor power cables having a large outer diameter and the inner surface of a protective pipe. Also, a method of assembling a power cable assembly comprising the steps of: inserting the other end side of the power cables with first connectors attached into one end portion into the protective pipe; disposing the small diameter compressor power cables in the gaps between the outer surface of the large diameter power cables and the inner surface of the protective pipe; and after applying bending work to the protective pipe in this state, adjusting the lengths of the other end portions of the power cables and attaching second connectors.

Abstract: A cooling device for a high voltage electrical unit for a motor of a vehicle, includes: an inverter for controlling the motor that drives the vehicle; an electrical energy storing device for supplying electrical energy to the motor via the inverter; a downverter for decreasing source voltage of the electrical energy storing device, the downverter, the inverter, and the electrical energy storing device disposed under a seat of the vehicle in a concentrated manner; a fan, disposed under the seat, for moving cooling air to the electrical energy storing device and the inverter; an air inlet disposed under the seat and at an end of the seat as viewed in a width direction of the vehicle; and an air outlet disposed under the seat and at the other end of the seat as viewed in a width direction of the vehicle.