The present disclosure provides a bogie assembly and a straddle-type monorail vehicle with the same. The bogie assembly comprises: a bogie frame; an electric assembly which is mounted on the bogie frame and comprises a traction motor, a gear reducer and a planetary wheel-side reducer, wherein the traction motor is connected with an input shaft of the gear reducer, and an output shaft of the gear reducer is connected with an input end of the planetary wheel-side reducer; and a running wheel which is mounted on the bogie frame, wherein an output end of the planetary wheel-side reducer is connected with a hub of the running wheel.

Disclosed is a frame for a bogie, comprising two side beams parallel to each other and a transverse beam connected to the middles of the side beams, wherein the middle of the transverse beam is provided with a traction pin hole, and an upper surface of the transverse beam is provided with a plurality of mounting seats for mounting a secondary suspension. The frame of the present invention is provided with a traction pin hole at the center of the transverse beam so that the transverse beam is connected to the bolster so as to bear a traction force, and a plurality of mounting seats for mounting the secondary suspension are arranged on an upper surface of the transverse beam, so that the secondary suspension can bear a rotation movement between the bogie and the vehicle body to improve curve passing capability of the vehicle.

A maglev vehicle and a suspension frame assembly thereof. The suspension frame assembly includes multiple suspension frames sequentially connected to each other. Each suspension frame comprises two motor beams, four support arms, and four air springs. An air spring mounting seat is disposed at a top portion of each support arm. The air spring mounting seats are cavities having openings. The air springs are accommodated in the respective cavities.

The present invention relates to a pneumatic suspension for a rail vehicle comprising a body and a bogie, said pneumatic suspension extending between the body and a chassis of the bogie, comprising: at least one secondary pneumatic suspension element for vertically supporting the body on the chassis and capable of being supplied with compressed air at a supply pressure, and a pressure source, wherein it further comprises: a control unit, for each suspension element, a sensor connected to the command unit and able to measure a height between the chassis and the body at the level of said suspension element, and for each suspension element, a solenoid valve connecting said suspension element to the pressure source, said solenoid valve being commanded automatically by an electric command signal, generated by the command unit as a function of the measured height(s).

The present invention relates to a pneumatic suspension for a rail vehicle comprising a body and a bogie, said pneumatic suspension extending between the body and a chassis of the bogie, comprising: at least one secondary pneumatic suspension element for vertically supporting the body on the chassis and capable of being supplied with compressed air at a supply pressure, and a pressure source, wherein it further comprises: a control unit, for each suspension element, a sensor connected to the command unit and able to measure a height between the chassis and the body at the level of said suspension element, and for each suspension element, a solenoid valve connecting said suspension element to the pressure source, said solenoid valve being commanded automatically by an electric command signal, generated by the command unit as a function of the measured height(s).

A system for recovery of compressed air released by air suspensions of at least one railway vehicle or train is described, comprising: a first compressor, a compressed air drying device, a first pipe, a first tank, a non-return valve, a limiting valve, a second tank, a second pipe, at least one pneumatic spring, and a first control device. The system for recovery further comprises a third pipe arranged to be connected to the pneumatic discharge port of the at least one leveling valve so as to receive compressed air discharged by the pneumatic spring, and a third tank arranged to be connected to the third pipe and to be supplied with compressed air provided by the third pipe.

A system for recovery of compressed air released by air suspensions of at least one railway vehicle or train is described, comprising: a first compressor, a compressed air drying device, a first pipe, a first tank, a non-return valve, a limiting valve, a second tank, a second pipe, at least one pneumatic spring, and a first control device. The system for recovery further comprises a third pipe arranged to be connected to the pneumatic discharge port of the at least one leveling valve so as to receive compressed air discharged by the pneumatic spring, and a third tank arranged to be connected to the third pipe and to be supplied with compressed air provided by the third pipe.

A railcar bogie includes: a cross beam extending in a car width direction; a first traction motor supported by a first car longitudinal direction portion of the cross beam; a second traction motor supported by a second car longitudinal direction portion of the cross beam; and a coupling member arranged under the cross beam and between the first traction motor and the second traction motor and coupling the first traction motor and the second traction motor to each other.

Disclosed is a bogie for a rail vehicle. One embodiment of a rail vehicle includes a bogie frame and at least four wheels arranged at the bogie frame. The bogie frame has a first and second frame parts, each frame part including a longitudinal beam and a cross beam. Each cross beam can be fixedly attached at the first end to the respective longitudinal beam. Each cross beam includes a pin at the second end. The longitudinal beam of the first frame part includes a receptacle for the pin of the second frame part and the longitudinal beam of the second frame part has a receptacle for the pin of the first frame part. The bogie can include one or more at bushing that includes elastomeric material, such as an elastomeric flange bushing, where the bushing is fixed to each cross beam or to the pin of the cross beam.

A failure determination device includes an acquirer to acquire pressure values of air springs provided to bogies included in a vehicle to support a vehicle body included in the vehicle, a compensator to perform compensation of the pressure values of the air springs depending on the position of the vehicle, and a determiner to determine, based on the pressure values of the air springs compensated by the compensator, whether any failure occurs in the air springs.