JP2016215684A - Railway vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To promote stability during linear travel and improved curve passing performance, relating to a railway vehicle which can be utilized as a very low floor type streetcar.SOLUTION: In a railway vehicle, for example, a cabin part car body 1 with no truck is rotatably connected so as to sandwich from front and back with end part car bodies 4a, 4b supported with a single two-axle truck 3 having integral wheel axles 2a, 2b. An axle spring 5 provided between the two-axle truck 3 and integral wheel axle 2a, 2b, and, a bolster spring 6 provided between the two-axle truck 3 and the end part car body 4a, 4b, are soft in hardness along to-fro direction. The end part car body 4a, 4b and the integral wheel axle 2a or 2b, otherwise, 2a, 2b are connected with a link mechanism 11.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a railway vehicle that can be used as an ultra-low floor tram.

  In the ultra-low-floor type tram, as shown in FIG. 8, end vehicle bodies 4a and 4b supported by a two-shaft carriage 3 having two wheel shafts 2a and 2b in front and rear of a cabin-body vehicle 1 without a carriage. The vehicle bodies 4a and 1, 1 and 4b are connected so as to be able to rotate while preventing pitching (for example, Patent Document 1).

  When the wheel shafts 2a and 2b are integrated wheel shafts in which the left and right wheels rotate together, a snake action S occurs as shown in FIG. 9 due to the creep force F generated by the influence of the tread surface gradient of the wheels. The wheel shaft 2a is moved in the left-right direction and the yaw direction. Hereinafter, in the present specification, the integral wheel shaft is also simply referred to as a wheel shaft.

  Of the above movements, the movement in the yaw direction is such that the shaft spring 5 provided between the wheel shafts 2a, 2b and the two-axis carriage 3 and the pillow spring 6 provided between the two-axis carriage 3 and the end body 4a are high in the front-rear direction. When the biaxial cart 3 does not rotate so much with respect to the end vehicle body 4a, the end vehicle body 4a and the biaxial cart 3 are substantially in phase.

  Therefore, the motion in the yaw direction is transmitted from the leading wheel shaft 2a to the end vehicle body 4a via the shaft spring 5, the two-shaft carriage 3, and the pillow spring 6. Reference numeral 7 denotes a shaft box provided with a bearing that rotatably supports the wheel shafts 2a and 2b.

  As means for preventing the serpentine behavior, the gradient of the tread surface of the wheel is made small, and the longitudinal spring of the shaft spring provided between the axle box and the carriage and the pillow spring that supports the vehicle body is made highly rigid. Is effective.

  However, since the curve passing performance, which is in a trade-off relationship with the stability during traveling in a straight section, deteriorates, such means cannot be applied to a tram with many sharp curved sections.

  Further, the higher the rigidity in the front-rear direction of the pillow spring, the closer the biaxial bogie and the vehicle body are to those integrated with each other, and the turning moment increases. In a tramway vehicle that cannot provide a relaxation curve section even in a sharp curve section, an increase in the turning moment increases the angular velocity of the vehicle body at the entrance of the curve section, resulting in a sudden yaw direction of the vehicle body. Generate displacement.

  Therefore, in the vehicle described in Patent Document 1, as a connecting structure between the vehicle bodies, a damper capable of controlling the force acting between the vehicle bodies is attached, thereby improving stability during straight running and curve passing performance. A technique is disclosed (Patent Document 2).

  The technique of this patent document 2 determines whether the vehicle is traveling linearly or curvedly based on the relative displacement between the detected vehicle bodies, the relative speed calculated based on the relative displacement, or the frequency of the relative displacement. The damper is actuated so as to assist the yawing movement of the vehicle body when traveling on a curve.

  However, as in Patent Document 2, in a system that controls the operation of the damper so as to be suitable for straight running or curved running determined based on the detection signal, it is possible to deal with a case where the control system fails (failure resistance). There are challenges.

JP 2001-301614 A JP 2006-306156 A

  The problem to be solved by the present invention is that a damper capable of controlling the force acting between the vehicle bodies is attached when the cabin vehicle body and the end vehicle bodies arranged at the front and rear are rotatably connected while preventing pitching. In this case, there is a problem in dealing with the case where the control system fails.

  The present invention provides stability during straight running and curve passing performance in a railway vehicle that can be used as an ultra-low floor tramway by a mechanical system without using a control system that has a problem with fail resistance. The purpose is to improve the above.

In order to achieve the above object, the present invention provides
A railway vehicle that is rotatably connected to a vehicle body supported by a single two-shaft carriage having an integrated wheel shaft, or a vehicle body that is not equipped with a carriage is rotatable so as to be sandwiched from the front and rear by the vehicle body supported by the single two-shaft carriage. Railway vehicle connected to
Both the shaft spring provided between the two-shaft carriage and the integral wheel shaft and the pillow spring provided between the two-shaft carriage and the vehicle body are made to be flexible in the front-rear direction, so that the integral wheel shaft, the two-shaft carriage, the two-shaft carriage, and the While allowing the body to relatively turn in the yaw direction,
The main feature is that the vehicle body and the integral wheel shaft are connected by a link mechanism to transmit the turning moment of the integral wheel shaft in the yaw direction to the vehicle body.

  The link mechanism of the present invention is, for example, a lever that is rotatably attached to a two-shaft carriage, and a shaft box that rotatably supports an integral wheel shaft, and one end side is rotatably attached, and the other end side is rotated to the lever. It comprises a first link that is freely connected, and a second link that is rotatably attached at one end to the vehicle body and that is rotatably connected to the lever at the other end.

  In the present invention, when a snake action occurs during traveling, the first link, the insulator, the second link from the integral wheel shaft separately from the flow transmitted from the integral wheel shaft to the vehicle body via the shaft spring, the two-shaft carriage, and the pillow spring. A moment is transmitted to the car body via the link.

  Therefore, the distance between the connecting point of the insulator and the second link is made longer than the distance between the connecting point of the insulator to the two-axis cart and the first link, The inertial force can be amplified and the movement of the integral wheel shaft in the yaw direction can be suppressed.

  The link mechanism of the present invention may be one that connects the two integrated wheel shafts of the vehicle body and the two-shaft carriage, or one that connects to one of the two integrated wheel shafts of the vehicle body and the two-shaft carriage. Good.

  At that time, the turning in the relative yaw direction as viewed from the bogie of the integral wheel shaft is appropriately determined so as to be in the same direction or in the opposite direction to the turning of the biaxial bogie in the yaw direction.

  In the case of an ultra-low floor tram cart, the axial spring 5 has a longitudinal rigidity of 5 to 10 kN / mm and the pillow spring 6 has a longitudinal rigidity of about 500 N / mm. The term “flexible rigidity in the front-rear direction” means that the spring constant in the front-rear direction of the shaft spring is less than 5 kN / mm. Moreover, the flexibility of the pillow spring in the front-rear direction means that the spring constant of the pillow spring in the front-rear direction is less than 500 N / mm.

  In the present invention, the axial spring and the pillow spring are made to be flexible in the front-rear direction, and the integral wheel shaft, the two-shaft carriage, and the two-shaft carriage and the vehicle body are allowed to turn relatively in the yaw direction. As a result, the attack angle can be reduced and the curve passing performance can be improved.

  Further, in the present invention, the vehicle body and the integrated wheel shaft are connected by a link mechanism so that the yaw direction turning of the integrated wheel shaft is transmitted to the vehicle body. Can improve the stability.

It is a figure explaining one Example of the railway vehicle of this invention, and transmission of the force at the time of driving | running | working of the railway vehicle of this invention. It is a figure explaining the attitude | position when the vehicle which supported the vehicle body by the one 2 axis | shaft trolley | bogie which has an integral wheel shaft passes a curve area. Simulation of the angular velocity of the vehicle body in the yaw direction (hereinafter referred to as the yaw angular velocity) when a railway vehicle in which two vehicles supporting the vehicle body are connected by a single two-shaft carriage having an integrated wheel shaft passes through a curved section having a radius of 25 m. In the figure, (a) is a case where the shaft spring and the pillow spring are highly rigid in the front-rear direction, (b) is a case where the shaft spring and the pillow spring are flexible in the front-rear direction, and (c) is the first part of the railcar. When steering is performed so that the relative yaw angle of the wheel axis viewed from the carriage is opposite to the relative yaw angle of the vehicle body viewed from the carriage, (d) is positioned at the center of the railway vehicle. This is a case where steering is performed so that the relative yaw angle of the wheel shaft seen from the carriage is the same as the relative yaw angle of the vehicle body seen from the carriage. It is the figure which compared the yaw angular velocity of the vehicle body shown in FIG. 3 in the entrance of a curve area. (A)-(d) is the figure which simulated the bogie angle of the top trolley | bogie on the same conditions as FIG. It is the figure which compared the logarithmic attenuation factor in the exit of the curve area of the bogie angle of the top trolley | bogie shown in FIG. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram for explaining a link mechanism in a railway vehicle according to the present invention, and FIG. (B) Steering so that the relative yaw angle of the leading wheel axle is in the same direction as the relative yaw angle of the end vehicle body, (c) is the relative yaw angle of the rear wheel shaft being the relative yaw angle of the end vehicle body. Steering to make the direction opposite to the angle, (d) steering to make the relative yaw angle of the rear wheel axle the same as the relative yaw angle of the end vehicle body, (e) Steering is performed so that the relative yaw angle of the rear wheel shaft is the same as the relative yaw angle of the end vehicle body, so that the relative yaw angle is opposite to the relative yaw angle of the end vehicle body. It is explanatory drawing of the ultra-low-floor type streetcar disclosed by patent document 1. FIG. It is a figure explaining the transmission of the force at the time of driving | running | working in case the axial spring and pillow spring of a vehicle which support an end part vehicle body with one 2-axis trolley | bogie are highly rigid in the front-back direction.

  In the present invention, the shaft spring and the pillow spring are made to be flexible and integrated with the vehicle body for the purpose of improving the stability during straight running and the curve passing performance in a railway vehicle that can be used as an ultra-low floor tram. This was realized by connecting the axles with a link mechanism.

Embodiments of the present invention will be described below with reference to FIGS.
For example, FIG. 1 shows a connecting device 8 so that a passenger compartment body 1 without a carriage is sandwiched from the front and rear by an end body 4a (4b) supported by a single two-shaft carriage 3 having integral wheel shafts 2a and 2b. The railway vehicle connected using is shown.

  In the railway vehicle of the present invention shown in FIG. 1, the front-rear direction stiffness of the shaft spring 5 provided between the two-shaft truck 3 and the integrated wheel shafts 2a and 2b is made flexible, and the creep force F is applied to the leading integrated wheel shaft 2a. When this occurs, the leading integrated wheel shaft 2a is allowed to allow a turn in the yaw direction relative to the biaxial cart 3.

  Further, the rigidity in the front-rear direction of the pillow spring 6 provided between the biaxial carriage 3 and the end vehicle body 4a (, 4b) is set to be flexible, so that the biaxial carriage 3 is connected to the end vehicle body 4a (, 4b). The rotation in the yaw direction is allowed relatively. Therefore, the turning moment of the leading integrated wheel shaft 2a can be reduced, and the yaw angular velocity acting on the end vehicle body 4a (4b) at the sharply curved entrance can be reduced.

  In addition, the railway vehicle of the present invention shown in FIG. 1 connects the end vehicle body 4a (, 4b) and the leading integrated wheel shaft 2a by the link mechanism 11, and ends the turning of the leading integrated wheel shaft 2a in the yaw direction. It is transmitted to the partial vehicle body 4a (4b).

  FIG. 2 shows a posture when the end vehicle body 4a supported by one two-shaft carriage 3 having the integrated wheel shafts 2a and 2b passes through the curved section.

  At the time of passing through the curved section, the smaller the angle (attack angle) θ1 between the integrated wheel shafts 2a, 2b and the traveling direction of the track, the better the curve passing performance. Therefore, the attack angle θ1 is reduced by the link mechanism 11 based on the bogie angle θ2 between the end vehicle body 4a (, 4b) and the biaxial carriage 3 when passing through the curved section.

  The inventors have determined that the yaw angular velocity of the vehicle body when a railway vehicle, in which two vehicles supporting the vehicle body are connected by a single biaxial vehicle having an integrated wheel axis for a tram, passes through a curved section having a radius of 25 m. And the bogie angle of the top carriage was simulated. The results are shown in FIGS.

  FIG. 3 is a diagram simulating the yaw angular velocity of the vehicle body, and FIG. 4 is a diagram comparing the yaw angular velocity of the vehicle body shown in FIG. 3 at the entrance of the curve section.

  FIG. 5 is a diagram simulating the bogie angle of the top carriage, and FIG. 6 is a diagram comparing logarithmic decay rates at the exit of the curve section of the bogie angle of the top carriage.

  3 and 5 (a) shows a case where the shaft spring and the pillow spring are highly rigid in the front-rear direction, FIG. 3B shows a case where the shaft spring and the pillow spring are made flexible in the front-rear direction, and FIG. When the first first axis and the last fourth axis are steered, (d) shows the case where the second and third axes located at the center of the railway vehicle are steered.

  The yaw angular velocity of the vehicle body generated at the entrance of the curved section is about 120 mrad / s from FIG. 3A and FIG. 4 in the conventional tram where the shaft spring and the pillow spring are highly rigid in the front-rear direction. I understand.

  On the other hand, when the axial spring and the pillow spring are flexible in the front-rear direction, the yaw angular velocity generated at the entrance of the curved section is reduced to about 85 mrad / s from FIG. 3B and FIG. I understand.

  Also, the axial spring and the pillow spring are made to be flexible in the front-rear direction, and the relative yaw angle of the wheel shaft when the first and fourth axes of the railway vehicle are both viewed from the carriage by the link mechanism is the relative yaw angle of the vehicle body as viewed from the carriage. 3C and FIG. 4, it can be seen that the yaw angular velocity is the same as that obtained when the axial spring and the pillow spring are merely made to be flexible in the front-rear direction.

  In addition, the axial spring and the pillow spring are made to be flexible in the front-rear direction, and the relative yaw angle of the wheel shaft when the second axis and the third axis of the railway vehicle are both viewed from the carriage by the link mechanism is When swiveling in the same direction, the yaw angular velocity is 80 mrad / s or less from FIGS. 3 (d) and 4. It can be seen that it is reduced.

  On the other hand, the bogie angle of the leading carriage generated at the center of the curved section is 5 mrad or less as shown in FIG. 5 (a) in the conventional tram where the shaft spring and the pillow spring are highly rigid in the front-rear direction. The logarithmic decay rate of the bogie angle of the leading carriage at the exit of the curved section is as high as 2.25 as shown in FIG. Therefore, as shown in FIG. 5A, the vibration component of the bogie angle converges immediately after passing through the curved section.

  On the other hand, when the axial spring and the pillow spring are flexible in the front-rear direction, a bogie angle of about 5 to 25 mrad is generated at the center of the curved section as shown in FIG. It can be seen that has occurred. Further, the logarithmic decay rate of the bogie angle of the leading carriage at the exit of the curved section is as low as 0.75 as shown in FIG. 6, and it can be seen that the vibration component of the bogie angle after passing through the curved section is difficult to converge.

  However, the axial spring and the pillow spring are flexible in the front-rear direction, and the relative yaw angle of the wheel shaft when the second and third axes of the railway vehicle are both viewed from the carriage by the link mechanism is the relative yaw angle of the vehicle body when viewed from the carriage. When turning in the same direction, as shown in FIG. 5D, a bogie angle of about 20 mrad is generated at the center of the curved section, but almost no vibration component is generated in the bogie angle. Further, the logarithmic decay rate of the bogie angle of the leading carriage at the exit of the curved section is as high as 2.75 as shown in FIG. Therefore, as shown in FIG. 5D, it can be seen that the vibration component of the bogie angle converges immediately after passing through the curved section.

  Also, the axial spring and the pillow spring are made to be flexible in the front-rear direction, and the relative yaw angle of the wheel shaft when the first and fourth axes of the railway vehicle are both viewed from the carriage by the link mechanism is the relative yaw angle of the vehicle body as viewed from the carriage. When the vehicle is turned in the opposite direction, a bogie angle of about 10 to 20 mrad is generated at the center of the curved section as shown in FIG. 5 (c), but the logarithmic decay of the bogie angle of the leading carriage at the exit of the curved section. The rate is 1 or more as shown in FIG. Accordingly, as shown in FIG. 5C, it can be seen that the vibration component of the bogie angle after passing through the curved section is more easily converged than when the axial spring and the pillow spring are made to be flexible in the front-rear direction.

  Based on the above results, the head integrated wheel shaft 2a or the rear integrated wheel shaft 2b, or the head integrated wheel shaft 2a and the rear integrated wheel shaft 2b are turned in the same direction or in the opposite direction to the turning of the two-shaft truck 3 in the yaw direction. Thus, the link mechanism 11 is configured.

  For example, in the embodiment shown in FIG. 1, the link mechanism 11 is constituted by the insulator 12, the first link 13, and the second link 14. Among these, the insulator 12 is attached to the center of the two-shaft carriage 3 so as to be freely rotatable. Further, the first link 13 is rotatably attached at one end side to the axle box 7 that rotatably supports the leading integrated wheel shaft 2a, and the other end side from the attachment point P1 of the insulator 12 to the two-shaft carriage 3 One end is rotatably connected. The second link 14 is rotatably attached at one end side to the end vehicle body 4a, and the other end side is rotatably connected to the other end side from the attachment point P1 of the insulator 12.

  In the railway vehicle of the present invention described above, when the snake action S occurs during traveling, it is integrated separately from the flow transmitted from the integral wheel shaft 2a to the end vehicle body 4a via the shaft spring 5, the two-shaft carriage 3, and the pillow spring 6. A moment is transmitted from the wheel shaft 2a to the end vehicle body 4a via the first link 13, the insulator 12, and the second link 14 (see FIG. 1).

  Therefore, the connection point between the attachment point P1 and the second link 14 of the insulator 12 is larger than the distance L1 between the attachment point P1 of the insulator 12 to the two-axis carriage 3 and the connection point P2 between the first link 13 and the connection point P2. If the distance L2 from P3 is increased to amplify the inertial force of the end vehicle body 4a, the movement of the integral wheel shaft 2a in the yawing direction can be suppressed during traveling in the straight section.

  In the link mechanism 11 shown in FIG. 1 and FIG. 7A, the relative yaw angle of the head integrated wheel shaft 2 a viewed from the biaxial cart 3 is the relative yaw angle of the end vehicle body 4 a viewed from the biaxial cart 3. It is connected to the end body 4a (4b) so as to turn in the opposite direction, but the one shown in FIGS. 7B to 7E may be used.

  7B, the attachment point P1 of the insulator 12 is one end side of the insulator 12, the connection point P3 of the second link 14 to the insulator 12 is the other end side of the insulator 12, and the first link 13 The connecting point P2 to the insulator 12 is the central portion of the insulator 12. In this case, the relative yaw angle of the leading integrated wheel shaft 2 a viewed from the biaxial cart 3 turns in the same direction as the relative yaw angle of the end vehicle body 4 a viewed from the biaxial cart 3.

  On the other hand, the link mechanism 11 shown in FIGS. 7C and 7B is an example in which the rear integrated wheel shaft 2b is connected to the end vehicle body 4a (4b).

  Among these, FIG.7 (c) is free to rotate to the axle box 7 which supports the one end side of the 1st link 13 in the link mechanism 11 shown to Fig.7 (a) rotatably at the rear integrated wheel shaft 2b. It is attached to.

  Further, FIG. 7D shows that the one end side of the first link 13 in the link mechanism 11 shown in FIG. 7B is rotatable on the axle box 7 that rotatably supports the rear integrated wheel shaft 2b. It is attached.

  On the other hand, FIG. 7 (e) shows that the leading integrated wheel shaft 2a and the trailing integrated wheel shaft 2b are both connected to the end vehicle body 4a (4b) by the link mechanism 11, and the leading integrated wheel shaft 2a as viewed from the two-shaft truck 3 is shown. The relative yaw angle is opposite to the relative yaw angle of the end vehicle body 4a viewed from the biaxial cart 3, and the relative yaw angle of the rear integrated wheel shaft 2b viewed from the biaxial cart 3 is viewed from the biaxial cart 3. This is an example of turning in the same direction as the relative yaw angle of the end body 4a.

  1 and 7, the link mechanism 11 protrudes from the side surface of the end vehicle body 4a. However, this is a schematic diagram for facilitating understanding. Needless to say, it is arranged between the shaft carriage 3 and the end vehicle bodies 4a, 4b.

Next, the evaluation in the case where the link mechanism 11 shown in FIG.
The evaluation shown in Table 1 below was performed based on the following evaluation criteria.

Effect 1: Yaw angular velocity of the vehicle body at the entrance of the curved section Pillow spring longitudinal rigidity Stiff; -1 point Pillow spring longitudinal rigidity Soft; +1 point

Effect 2: Dynamic vibration absorber effect that absorbs vibration in the yaw direction by the inertial force of the steering device Based on the simulation results of FIG.
Bogie with rigid rigidity in the longitudinal direction of the pillow spring (without steering device); +2 points Bogie with flexible rigidity in the longitudinal direction of the pillow spring (without steering device); +0.5 point The relative yaw angle of the wheel axis as seen from the carriage Pattern in which the movement of the relative yaw direction of the vehicle body viewed from the carriage is in the opposite direction; +1 point Pattern in which the relative yaw angle of the wheel axis viewed from the carriage and the movement of the vehicle body in the relative yaw direction viewed from the carriage are the same direction; +2. 5 points

Effect 3: Steering effect Pattern in which steering device assists self-steering performance of wheel axle; +1 point Pattern in which steering device impedes self-steering performance of wheel shaft; -0.5 point

  Since the yaw angular velocity of the vehicle body at the entrance of the curve section of effect 1 depends on the longitudinal rigidity of the pillow spring, score evaluation was performed from the results of FIGS. 3 and 4.

  In addition, the dynamic vibration absorber effect of effect 2 is that the inertial force (inertia moment) of the vehicle body is larger than the yawing moment generated by the snake behavior of the wheel shaft, and the movement of the wheel shaft and the vehicle body in the yaw direction as viewed from the carriage is large. In the case of the same direction, since a larger dynamic vibration absorber effect can be expected, it was evaluated as +2.5 points. For comparison with the case without the steering device, the score was evaluated from the results of FIGS.

  The steering effect of the railway vehicle subject to the present invention is that the relative yawing angle at the time of passing through the curve is mostly borne between the opposite vehicle bodies, and not between the vehicle body and the carriage. The pattern that hinders the self-steering performance was evaluated as -0.5 points instead of -1.

  From Table 1, No. 5, the first axis and the last fourth axis of the railway vehicle are the link mechanism shown in FIG. 7B, and the second axis and the third axis located in the center of the railway vehicle are When the link mechanism shown in FIG. 7 (d) is employed, and in No. 7, the first axis and the last fourth axis of the railway vehicle are shown in FIG. 7 (a). The evaluation is highest when the link mechanism shown in FIG. 7D is adopted for the second and third axes located in the center.

  However, the first axis and the last fourth axis of the railway vehicle, or the second axis and the third axis located in the center of the railway vehicle are set in the same direction or in the opposite direction to the turning of the two-axis carriage in the yaw direction. Even if it turns (No. 1 to 4), it is equal to or better than the conventional streetcar with axial and pillow springs with high rigidity in the front-rear direction, and the axial spring and pillow spring with only rigidity in the front-rear direction. Was obtained.

  Also, when steering all axes, the turning directions of the first and last fourth axes of the railway vehicle and the second and third axes located in the center of the railway vehicle are shown in Table 1. Even if it is other than .5, 7, the evaluation is higher than the conventional tram that makes the shaft spring and pillow spring highly rigid in the front-rear direction and the case where only the shaft spring and pillow spring is made flexible in the front-rear direction. (No. 6, 8).

  The present invention is not limited to the above example, and it goes without saying that the embodiments may be changed as appropriate within the scope of the technical idea described in each claim.

  For example, in FIGS. 1 and 2, the three-way railway vehicle of the end vehicle bodies 4 a and 5 b having one two-shaft carriage and the cabin body 1 having no carriage shown in FIG. FIG. 6 illustrates a railway vehicle in which two vehicles that support the vehicle body with one two-axis cart are connected. However, in the present invention, the number of vehicles to be connected is not particularly limited.

1 Cabin body 2 Wheel axle (integrated wheel axle)
3 Biaxial cart 4a, 4b End vehicle body 5 Axle spring 6 Pillow spring 7 Axle box 8 Connecting device 11 Link mechanism 12 Insulator 13 First link 14 Second link

Claims (7)

A railway vehicle that is rotatably connected to a vehicle body supported by a single two-shaft carriage having an integrated wheel shaft, or a vehicle body that is not equipped with a carriage is rotatable so as to be sandwiched from the front and rear by the vehicle body supported by the single two-shaft carriage. Railway vehicle connected to
Both the shaft spring provided between the two-shaft carriage and the integral wheel shaft and the pillow spring provided between the two-shaft carriage and the vehicle body are made to be flexible in the front-rear direction, so that the integral wheel shaft, the two-shaft carriage, the two-shaft carriage, and the While allowing the body to relatively turn in the yaw direction,
The railway vehicle, wherein the vehicle body and the integral wheel shaft are connected by a link mechanism, and the turning moment of the integral wheel shaft in the yaw direction is transmitted to the vehicle body.   The link mechanism includes a lever that is rotatably attached to the two-shaft carriage, and a shaft box that rotatably supports the integral wheel shaft, and one end side is rotatably attached, and the other end side is rotatable to the lever. 2. The railway vehicle according to claim 1, comprising a first link to be connected, and a second link in which one end side is rotatably attached to the vehicle body and the other end side is rotatably connected to the insulator. .   The railway vehicle according to claim 2, wherein the link mechanism connects the vehicle body and two integral wheel shafts of the two-shaft carriage.   The link mechanism is configured such that the relative yaw angle of the integral wheel shaft viewed from the cart and the relative yaw angle of the vehicle body viewed from the cart are the same direction with respect to one integral wheel shaft of the two-shaft cart, and the cart relative to the other integral wheel shaft. The railway vehicle according to claim 3, wherein the relative yaw angle of the integral wheel shaft as viewed from the side and the relative yaw angle of the vehicle body as viewed from the carriage are operated in opposite directions.   The link mechanism is configured to operate a relative yaw angle of the integrated wheel shaft viewed from the cart and a relative yaw angle of the vehicle body viewed from the cart in the same direction or in the opposite direction with respect to the two integrated wheel shafts of the two-axis cart. The railway vehicle according to claim 3.   The railway vehicle according to claim 2, wherein the link mechanism connects one of two integrated wheel shafts of the vehicle body and the two-shaft carriage.   The link mechanism is configured to operate the relative yaw angle of the integrated wheel shaft viewed from the cart and the relative yaw angle of the vehicle body viewed from the cart in the same direction or in the opposite direction with respect to the integrated wheel shaft of the biaxial cart. The railway vehicle according to claim 6.

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