A permanent magnet direct-drive bogie and a rail vehicle thereof are disclosed. The permanent magnet direct-drive bogie comprises a frame (1), a wheel set (2), and a permanent magnet motor (3); the frame (1) comprises a longitudinal beam (11), a cross beam (12) perpendicular to the longitudinal beam (11), and end beams (13) arranged at both ends of the longitudinal beam (11); a hollow shaft (4) is sleeved on an axle (21) of the wheel set (2), a force transmission seat (5) is fixed on the axle (21), the permanent magnet motor (3) is sleeved on the hollow shaft (4), one end of the hollow shaft (4) is connected to the permanent magnet motor (3) through a flexible coupling (6), and the other end of the hollow shaft (4) is connected to the force transmission seat (5) through a flexible coupling (6); both longitudinal sides of the cross beam (12) are provided with protrusions (121); the permanent magnet motor (3) is flexibly connected to the frame (1) through a swing rod (7) and a suspension rod (17), one end of the swing rod (7) is hung on the protrusion (121), the other end is connected to a housing of the permanent magnet motor (3), and the axis of the swing rod (7) is arranged longitudinally; one end of the suspension rod (17) is connected to the housing of the permanent magnet motor (3), and the other end is suspended on the end beam (13); and the permanent magnet motor (3) is laterally movable.

A permanent magnet direct-drive bogie and a rail vehicle thereof are disclosed. The permanent magnet direct-drive bogie comprises a frame (1), a wheel set (2), and a permanent magnet motor (3); the frame (1) comprises a longitudinal beam (11), a cross beam (12) perpendicular to the longitudinal beam (11), and end beams (13) arranged at both ends of the longitudinal beam (11); a hollow shaft (4) is sleeved on an axle (21) of the wheel set (2), a force transmission seat (5) is fixed on the axle (21), the permanent magnet motor (3) is sleeved on the hollow shaft (4), one end of the hollow shaft (4) is connected to the permanent magnet motor (3) through a flexible coupling (6), and the other end of the hollow shaft (4) is connected to the force transmission seat (5) through a flexible coupling (6); both longitudinal sides of the cross beam (12) are provided with protrusions (121); the permanent magnet motor (3) is flexibly connected to the frame (1) through a swing rod (7) and a suspension rod (17), one end of the swing rod (7) is hung on the protrusion (121), the other end is connected to a housing of the permanent magnet motor (3), and the axis of the swing rod (7) is arranged longitudinally; one end of the suspension rod (17) is connected to the housing of the permanent magnet motor (3), and the other end is suspended on the end beam (13); and the permanent magnet motor (3) is laterally movable.

A chassis for rail vehicles includes at least one support structure, at least one first primary spring and a second primary spring, at least one first drive motor transmission unit connected to the at least one support structure via at least one first suspension element, at least one first wheelset and at least one first clutch connected to the at least one drive motor transmission unit and to the at least first wheelset, wherein the at least first drive motor transmission unit is connected to the at least one support structure via a coupling element that is loadable primarily in the direction of a chassis longitudinal axis so as to create advantageous construction conditions such that an advantageous movability of the support structure and the first wheelset relative to each other is achieved.

A chassis for rail vehicles includes at least one support structure, at least one first primary spring and a second primary spring, at least one first drive motor transmission unit connected to the at least one support structure via at least one first suspension element, at least one first wheelset and at least one first clutch connected to the at least one drive motor transmission unit and to the at least first wheelset, wherein the at least first drive motor transmission unit is connected to the at least one support structure via a coupling element that is loadable primarily in the direction of a chassis longitudinal axis so as to create advantageous construction conditions such that an advantageous movability of the support structure and the first wheelset relative to each other is achieved.

Disclosed is a bogie framework of a rail vehicle and a bogie, wherein the bogie framework of the rail vehicle includes a first end beam (01), a second end beam (02) and a box beam disposed between the first end beam (01) and the second end beam (02). The box beam includes a primary gearbox (1) and a secondary gearbox (2), and the primary gearbox (1) is used for connecting a traction motor and the secondary gearbox (2). The secondary gearbox (2) is disposed between the primary gearbox (1) and the first end beam (01), as well as between the primary gearbox (1) and the second end beam (02).

Disclosed is a bogie framework of a rail vehicle and a bogie, wherein the bogie framework of the rail vehicle includes a first end beam (01), a second end beam (02) and a box beam disposed between the first end beam (01) and the second end beam (02). The box beam includes a primary gearbox (1) and a secondary gearbox (2), and the primary gearbox (1) is used for connecting a traction motor and the secondary gearbox (2). The secondary gearbox (2) is disposed between the primary gearbox (1) and the first end beam (01), as well as between the primary gearbox (1) and the second end beam (02).

Disclosed is a gearbox for rail vehicle, a bogie for rail vehicle and a rail vehicle. The gearbox for rail vehicle includes a primary gearbox (1) configured to connect with a traction motor, and a secondary gearbox (2) arranged on both sides of the primary gearbox (1) along a longitudinal direction of the rail vehicle, wherein a framework bearing beam is formed by connecting the primary gearbox (1) and the secondary gearbox (2), the primary gearbox (1) is configured to transmit power from the traction motor to the secondary gearbox (2), and the secondary gearbox (2) are configured to transmit power from the primary gearbox (1) to wheelsets of the rail vehicle.

Disclosed is a gearbox for rail vehicle, a bogie for rail vehicle and a rail vehicle. The gearbox for rail vehicle includes a primary gearbox (1) configured to connect with a traction motor, and a secondary gearbox (2) arranged on both sides of the primary gearbox (1) along a longitudinal direction of the rail vehicle, wherein a framework bearing beam is formed by connecting the primary gearbox (1) and the secondary gearbox (2), the primary gearbox (1) is configured to transmit power from the traction motor to the secondary gearbox (2), and the secondary gearbox (2) are configured to transmit power from the primary gearbox (1) to wheelsets of the rail vehicle.

An air intake port has an opening part and an air intake port cover forming an air flow channel from the opening part to the air intake port. The air intake port cover has a guide plate to block the opening part and the air intake port from each other and leave an air flow path between the guide plate and an outer perimeter surface facing a vehicle body, a discharge port formed in the outer perimeter surface, a discharge port cover separating the discharge port and the air intake port from each other, and leaving an air flow path from the opening part to the discharge port, and a pair of cylindrical members, one end of each being connected to two holes formed in the discharge port cover, and the other ends facing each other in a travel direction, and tapering in cross-sectional area.

An air intake port has an opening part and an air intake port cover forming an air flow channel from the opening part to the air intake port. The air intake port cover has a guide plate to block the opening part and the air intake port from each other and leave an air flow path between the guide plate and an outer perimeter surface facing a vehicle body, a discharge port formed in the outer perimeter surface, a discharge port cover separating the discharge port and the air intake port from each other, and leaving an air flow path from the opening part to the discharge port, and a pair of cylindrical members, one end of each being connected to two holes formed in the discharge port cover, and the other ends facing each other in a travel direction, and tapering in cross-sectional area.