JP7262992B2 - Wear amount calculation device, abnormal wear determination device, and brake device - Google Patents

Description

The present invention relates to a wear amount calculation device, an abnormal wear determination device, and a brake device.

Patent Literature 1 describes a tread brake type braking device used in railroad vehicles. A wear detection device is applied to this brake device to detect that the brake shoe has worn to a predetermined wear limit. The wear detection device of Patent Literature 1 includes a transponder attached to a brake shoe and a transmitter/receiver arranged outside a railroad vehicle. The transponder is mounted at a location where it contacts the wheel when the brake shoe wears to its wear limit. When the brake shoe wears down to its wear limit, the transponder comes into contact with the wheel and is destroyed. On the other hand, the transmitter/receiver transmits radio waves to the transponder and detects the state of the brake shoe based on the presence or absence of a signal from the transponder. Specifically, when a signal from the transponder is input, the transceiver determines that the brake shoe has not worn to a predetermined wear limit. On the other hand, if the signal from the transponder is not input, the transmitter/receiver determines that the brake shoe has worn to the predetermined wear limit.

Japanese Patent Application Laid-Open No. 2002-250383

In the wear detection device of Patent Document 1, it is necessary to attach a transponder to the brake shoe each time the brake shoe is replaced. Therefore, in the wear detection device of Patent Document 1, the work for replacing the brake shoe tends to be complicated. Therefore, a wear detection device applied to a brake device is required to be capable of appropriately detecting the amount of wear of the brake shoe and simplifying the work of replacing the brake shoe. The wear detection device applied to a disc brake type brake device, as well as the wear detection device applied to the tread brake type brake device, has the same problem.

A wear amount calculation device for solving the above problems includes a detection unit that detects the position of a component of a brake device that moves together with a braking unit that generates a braking force by friction force, and a position detected by the detection unit at an arbitrary time. and a calculation unit that calculates the amount of wear of the braking unit based on the position of the component that has been detected by the detection unit after the arbitrary time.

In the above configuration, the detection section is attached to a component of the brake device that moves together with the braking section, and is not attached to the braking section itself. Therefore, it is not necessary to attach the detection section to the braking section when replacing the braking section. Therefore, the work for exchanging the braking portion can be simplified.

In the above configuration, the component is a member that rotates in opposite directions about the rotation shaft when the braking portion approaches the braking target and when the braking portion moves away from the braking target when the braking is not performed. The rotating shaft may be exposed to the outside of the brake device, and the detection unit may detect a rotating position of the component about the rotating shaft. In the above configuration, since the rotating shaft is exposed to the outside of the brake device, it is easy to simplify the mounting work of the detector to the brake device.

In the above configuration, the calculation unit may calculate the wear rate of the braking portion based on the amount of wear of the braking portion at an arbitrary point of time and the amount of wear of the braking portion after the arbitrary point of time. With the above configuration, it is possible to predict the replacement timing of the braking portion based on the wear rate of the braking portion.

The said structure WHEREIN: The said calculation part may be attached above the air spring fixed to the truck. In the above configuration, less vibration is transmitted to the calculator than in a configuration in which the calculator is attached below the air spring. Therefore, it is possible to suppress failure of the calculation unit due to vibration.

The abnormal wear determination device for solving the above problems is provided for each of a plurality of brake devices, and is provided for detecting the positions of components of each brake device that move together with a braking unit that generates a braking force due to frictional force. a detection unit, positions of components of each of the braking devices detected by the plurality of detection units at an arbitrary point in time, and components of each of the braking devices detected by the plurality of detection units after the arbitrary point of time; The amount of wear of the braking portion of each braking device is calculated based on the position of each of the braking devices, and the wear amounts of the braking portions of the plurality of braking devices are compared to determine abnormal wear of the braking portion of each of the braking devices. and a calculator.

In the above configuration, abnormal wear may occur in which the amount of wear of some of the braking sections driven by the plurality of braking devices becomes excessively large compared to the amount of wear of the other braking sections. In the above configuration, by comparing the amount of wear of a plurality of braking portions, abnormal wear of some of the braking portions can be found.

A braking device for solving the above problems comprises a detecting unit for detecting the position of components of the braking device that move together with a braking unit that generates a braking force due to frictional force; a calculation unit for calculating the amount of wear of the braking unit based on the position of the component and the position of the component detected by the detection unit after the arbitrary time; and a driving source for moving the braking unit. and a mechanical section provided for transmitting the driving force from the driving section to the braking section and including the component as a part thereof.

In the above configuration, the brake device includes the wear amount calculation device. Therefore, for example, compared with the case where the brake device and the separate wear amount calculation device are respectively attached to the truck, the attachment work to the truck can be simplified.

According to the present invention, the work for exchanging the braking portion can be simplified.

1 is a schematic diagram of a rail vehicle according to a first embodiment; FIG. Sectional drawing of the brake device before the brake shoe concerning the same embodiment wears. Sectional drawing of the brake device after the brake shoe which concerns on the same embodiment wears. (a) to (d) are plan views showing changes in the gap adjusting mechanism according to the embodiment. 4 is a flowchart showing wear determination processing according to the embodiment; Sectional drawing of the brake device before the brake pad concerning 2nd Embodiment wears out. Sectional drawing of the brake device after the brake pad concerning 2nd Embodiment was worn.

(First embodiment)
The first embodiment will be described below with reference to FIGS. 1 to 5. FIG.
As shown in FIG. 1, a railway vehicle 100 includes a vehicle body 10 that defines an interior space. The vehicle body 10 has a rectangular box shape as a whole and extends in the vehicle front-rear direction (left-right direction in FIG. 1).

A carriage 30 is attached to the lower surface of the vehicle body 10 via an air spring 35 that absorbs vibrations with the elasticity of compressed air. Two bogies 30 are arranged spaced apart in the vehicle front-rear direction. Each truck 30 is rotatably attached with an axle 31 extending in the width direction of the vehicle (the direction toward the front and back of the paper surface in FIG. 1). Two axles 31 are arranged separately in the longitudinal direction of the vehicle for each bogie 30 . A disk-shaped wheel 32 as a whole is fixed to both ends of the axle 31 .

As shown in FIG. 1, the bogie 30 is provided with a braking device 50 for braking the rotation of the wheels 32 . As shown in FIG. 2, the brake device 50 has a brake shoe 40 as a braking portion that is brought into contact with the tread surface 32a (outer peripheral surface) of the wheel 32 to be braked to brake the rotation of the wheel 32, that is, the so-called tread. It is a brake type brake device. A total of eight braking devices 50 are attached to the railway vehicle 100 corresponding to a total of eight wheels 32 .

As shown in FIG. 2 , the brake device 50 is arranged adjacent to one side (the right side in FIG. 2 ) of the vehicle front-rear direction with respect to the wheel 32 . The brake device 50 includes a drive section 60 that is a drive source for moving the brake shoe 40 and a mechanism section 70 that transmits the driving force from the drive section 60 to the brake shoe 40 .

A drive housing 61 in the drive unit 60 has a bottomed cylindrical shape extending in the vehicle front-rear direction as a whole. An introduction hole 61b for introducing compressed air from an air source (not shown) penetrates through a bottom wall 61a on the other side (the left side in FIG. 2) of the drive housing 61 in the vehicle front-rear direction.

A substantially disk-shaped piston 62 is arranged inside the drive housing 61 . The outer diameter of the piston 62 is substantially the same as the inner diameter of the drive housing 61 . The piston 62 is arranged such that the central axis of the piston 62 coincides with the central axis of the drive housing 61 . Therefore, the internal space of the drive housing 61 is partitioned by the piston 62 into a space on the side of the bottom wall 61a (left side in FIG. 2) and a space on the side opposite to the bottom wall 61a (right side in FIG. 2).

A substantially bar-shaped output shaft 63 protrudes from the surface of the piston 62 opposite to the bottom wall 61a. The output shaft 63 extends along the center axis of the piston 62 . The output shaft 63 extends to the outside of the drive housing 61 .

A spring 64 for urging the piston 62 toward the bottom wall 61a is arranged in the inner space of the drive housing 61 on the opposite side of the bottom wall 61a. When compressed air is introduced into the inner space of the drive housing 61 through the introduction hole 61b, the piston 62 moves toward the side opposite to the bottom wall 61a against the biasing force of the spring 64. As shown in FIG. On the other hand, when compressed air is not introduced into the drive housing 61 through the introduction hole 61b, the biasing force of the spring 64 causes the piston 62 to move toward the bottom wall 61a.

A mechanism housing 71 is fixed to one side of the drive housing 61 in the vehicle front-rear direction. The mechanism housing 71 has a rectangular box shape as a whole and extends downward from one surface of the drive housing 61 in the vehicle front-rear direction. The internal space of the mechanism housing 71 communicates with the internal space of the drive housing 61 . A portion of the output shaft 63 of the drive unit 60 on the distal end side is located inside the mechanism housing 71 . In addition, in this embodiment, the mechanism housing 71 is formed integrally with the drive housing 61 .

Inside the mechanism housing 71 , one end of a bar-shaped lever 72 is connected to the distal end of the output shaft 63 via a connecting pin 81 . The lever 72 is rotatable with respect to the distal end of the output shaft 63 around the connecting pin 81 . The lever 72 extends generally downward from the tip of the output shaft 63 . A middle portion of the lever 72 in the longitudinal direction (in this embodiment, a portion slightly lower than the center in the longitudinal direction) is supported by the mechanism housing 71 via a support shaft 78 . The lever 72 is rotatable with respect to the mechanism housing 71 around the support shaft 78 . A contact portion 72A protrudes toward one side in the vehicle front-rear direction from a portion of the lever 72 above the support shaft 78 in the longitudinal direction. A fixing hole 72a extends through the other end of the lever 72 in the longitudinal direction of the vehicle. The inner diameter of the fixing hole 72a is maximum at the central portion in the vehicle front-rear direction and is minimum at both end portions in the vehicle front-rear direction. Further, the inner peripheral surface of the fixing hole 72a has an arcuate shape when viewed in cross section from a direction perpendicular to the vehicle front-rear direction.

A sheath rod 73 is connected to a fixing hole 72 a in the lever 72 inside the mechanism housing 71 . The sheath rod 73 includes a cylindrical portion 73a, a spherical bearing 73b protruding from the outer peripheral surface of the cylindrical portion 73a, a gear portion 73c protruding from the outer peripheral surface of the cylindrical portion 73a, and one axial direction of the cylindrical portion 73a. and a connecting gear 73d protruding from the side end.

The spherical bearing 73b is located on the other side of the center of the cylindrical portion 73a in the central axis direction. The spherical bearing 73b extends over the entire circumferential direction (360 degrees) of the cylindrical portion 73a on the outer peripheral surface of the cylindrical portion 73a. The outer surface of the spherical bearing 73b has an arcuate shape when viewed in a cross section perpendicular to the vehicle front-rear direction, and the curvature thereof is substantially the same as the curvature of the inner peripheral surface of the fixing hole 72a. The gear portion 73c is located on one side of the center of the cylindrical portion 73a in the axial direction. The gear portion 73c protrudes outward in the radial direction of the cylindrical portion 73a and is composed of teeth arranged at equal intervals in the circumferential direction of the cylindrical portion 73a. The connecting gear 73d protrudes from one end surface of the cylindrical portion 73a in the central axis direction to one side in the central axis direction and is composed of teeth arranged at equal intervals in the circumferential direction of the cylindrical portion 73a. . A female screw (screw groove) is helically cut on the inner peripheral surface of the cylindrical portion 73a.

The spherical bearing 73b of the sheath rod 73 is attached to the fixing hole 72a of the lever 72 so that the gear portion 73c of the sheath rod 73 is positioned on one side in the vehicle front-rear direction. As a result, the sheath rod 73 can rotate to some extent with respect to the lever 72 while the outer peripheral surface of the spherical bearing 73b slides on the inner peripheral surface of the fixed hole 72a.

A push rod 74 is connected to the inside of the cylindrical portion 73 a of the sheath rod 73 . The push rod 74 has a threaded portion 74a extending in the longitudinal direction of the vehicle. A helical external thread (thread) is provided on the outer peripheral surface of the threaded portion 74 a of the push rod 74 . A portion of the threaded portion 74 a in the extending direction is arranged inside the cylindrical portion 73 a of the sheath rod 73 and meshes with the internal thread of the inner peripheral surface of the cylindrical portion 73 a of the sheath rod 73 .

The other end of threaded portion 74 a in the vehicle front-rear direction protrudes outside sheath rod 73 and also protrudes outside mechanism housing 71 through opening 71 a of mechanism housing 71 . A fixing portion 74b extends downward from the other end of the threaded portion 74a in the vehicle front-rear direction. A tilting hole 74d extends through the front end (lower end) of the fixed portion 74b in the vehicle width direction (the front-to-back direction of the sheet of FIG. 2). The tilting hole 74d has an elliptical shape that is long in the vehicle front-rear direction as a whole when viewed from the vehicle width direction. A cover 79 that covers the threaded portion 74a and the opening 71a of the mechanism housing 71 is attached to the other end of the threaded portion 74a in the vehicle front-rear direction. The cover 79 has a bellows shape and is extendable in the longitudinal direction of the vehicle.

A brake shoe head 75 for supporting the brake shoe 40 is connected via a connecting pin 82 to the boundary portion between the threaded portion 74a and the fixed portion 74b of the push rod 74. As shown in FIG. The brake shoe head 75 has a substantially triangular shape in which the width in the vertical direction increases toward the other side in the vehicle front-rear direction when viewed from the vehicle width direction. The surface of the brake shoe head 75 on the other side in the vehicle front-rear direction is a curved surface corresponding to the tread surface 32 a of the wheel 32 . The brake shoe head 75 can swing around the connecting pin 82 .

A substantially cylindrical tilting pin 84 protrudes from one side surface of the brake shoe head 75 in the vehicle width direction. The tilting pin 84 is positioned inside the tilting hole 74 d of the push rod 74 . Therefore, the swingable range of the brake shoe head 75 is limited by the contact relationship between the tilting pin 84 and the tilting hole 74d of the push rod 74. As shown in FIG.

A protruding portion 71A protrudes toward the other side in the vehicle front-rear direction from the outer surface of the mechanism housing 71 on the other side in the vehicle front-rear direction. The projecting portion 71A is positioned above a connecting pin 82 connected to the brake shoe head 75 in the vertical direction of the vehicle. In addition, in the present embodiment, the projecting portion 71A is formed integrally with the mechanism housing 71 and the drive housing 61. As shown in FIG.

One end of a rod-shaped hanger 76 is connected via a connecting pin 83 to the tip of the projecting portion 71A. The hanger 76 is rotatable around the connecting pin 83 . The other end of the hanger 76 is connected to the brake shoe head 75 via a connecting pin 82 . Therefore, the brake shoe head 75 and the brake shoe 40 connected to the hanger 76 rotate around the connecting pin 83 . Since the connecting pin 83 is located outside the mechanism housing 71 , it is exposed outside the brake device 50 .

An angle sensor 89 for detecting the rotation angle position of the hanger 76 about the connecting pin 83 with respect to the projecting portion 71A is attached to the connecting portion between the projecting portion 71A and the hanger 76 . The angle sensor 89 is, for example, a rotary potentiometer. In this embodiment, the angle sensor 89 is a detection unit that detects the positions of components of the brake device 50 . Also, the hanger 76 is a component of the brake device 50 whose rotational position (rotational angular position) is detected by the detector.

A brake shoe 40 is fixed to the surface of the brake shoe head 75 on the other side in the vehicle front-rear direction. The brake shoe 40 has a substantially arc shape that follows the tread surface 32 a of the wheel 32 . The brake shoe 40 is a brake friction material that is pressed against the tread surface 32a of the wheel 32 to generate a braking force due to frictional force.

As shown in FIG. 2, inside the mechanism housing 71, a gap adjusting mechanism 90 is mounted for adjusting the gap between the brake shoe 40 and the tread surface 32a of the wheel 32. As shown in FIG. The gap adjustment mechanism 90 is arranged to surround the radially outer side of the gear portion 73 c of the sheath rod 73 .

Specifically, as shown in FIG. 4( a ), the gap adjustment mechanism 90 includes a rod-shaped first link 91 . The first link 91 extends in the vehicle vertical direction (the vertical direction in FIG. 4A) on one side in the vehicle width direction (the right side in FIG. 4A) from the sheath bar 73 . A roller portion 91A is attached to the upper end portion of the first link 91 and contacts the contact portion 72A of the lever 72 . A substantially cylindrical cylindrical portion 91B extends downward from the lower end portion of the first link 91 . The outer diameter of the columnar portion 91B is smaller than the width of the first link 91 .

A spring receiving portion 92 is positioned in the vicinity of the lower end portion of the cylindrical portion 91B. The spring receiving portion 92 is fixed with respect to the mechanism housing 71 . A through hole 92a extends through the spring receiving portion 92 in the vertical direction of the vehicle. A lower end portion of the columnar portion 91B is passed through the through hole 92a of the spring receiving portion 92 . A first coil spring 93 is attached between the step portion between the first link 91 and the cylindrical portion 91B and the spring receiving portion 92 . A portion of the upper end side of the columnar portion 91B is passed through the inside of the first coil spring 93 . The first coil spring 93 biases the first link 91 upward. A strip-like tooth holding portion 94 extends from the upper surface of the spring receiving portion 92 toward the gear portion 73 c of the sheath rod 73 . The tip of the tooth pressing portion 94 abuts on the gear portion 73c. It should be noted that the contact of the tooth pressing portion 94 with the gear portion 73c acts as a resistance to the rotation of the sheath rod 73 in the circumferential direction, so that the sheath rod 73 is prevented from rotating unintentionally.

One end of a rod-shaped second link 95 is rotatably connected to a substantially central portion of the first link 91 in the vertical direction of the vehicle. The second link 95 extends above the sheath bar 73 from the first link 91 to the other side in the vehicle width direction (left side in FIG. 4). The other end of the second link 95 reaches the other side in the vehicle width direction from the sheath rod 73 . A portion of the second link 95 in the middle in the longitudinal direction (in this embodiment, the first link 91 side of the center in the longitudinal direction) is supported by the mechanism housing 71 via a support shaft 95A. The second link 95 is rotatable with respect to the mechanism housing 71 around the support shaft 95A. A first support portion 96 extending from the support shaft 95A toward the gear portion 73c is connected to the support shaft 95A. A portion of the first support portion 96 is arranged so as to be positioned near the outer peripheral portion of the gear portion 73c.

A claw portion 97 is rotatably connected to the other end of the second link 95 via a connecting pin 95B. The claw portion 97 extends obliquely downward from the other end portion of the second link 95 toward the gear portion 73c. Further, the tip portion 97 a of the claw portion 97 abuts on the outer peripheral portion (tooth portion) of the gear portion 73 c of the sheath rod 73 .

One end of a second coil spring 98 that biases the claw portion 97 downward is fixed to the claw portion 97 . The second coil spring 98 extends downward from the claw portion 97 on the other side of the sheath rod 73 in the vehicle width direction (the left side in FIG. 4A). The other end of the second coil spring 98 is fixed to a fixing pin 98A projecting from the mechanism housing 71. As shown in FIG. The fixing pin 98</b>A is positioned on one side (first link 91 side) in the vehicle width direction of the fixing portion between one end of the second coil spring 98 and the claw portion 97 . Therefore, the second coil spring 98 biases the claw portion 97 slightly obliquely downward toward the sheath rod 73 side.

A second support portion 99 extending from the fixing pin 98A toward the gear portion 73c is fixed to the fixing pin 98A. A portion of the second support portion 99 is arranged near the outer peripheral portion of the gear portion 73c. Also, the second support portion 99 is located in the opposite direction to the first support portion 96 with the gear portion 73c interposed therebetween. The second support portion 99 and the first support portion 96 are designed so that the positional relationship between the gear portion 73c of the sheath rod 73 and the distal end portion 97a of the claw portion 97 is excessively displaced due to vibration or the like in the brake device 50. is suppressed.

As shown in FIG. 2 , an adjustment nut 77 having a bottomed cylindrical shape as a whole is attached to one wall portion of the mechanism housing 71 in the vehicle front-rear direction. The adjusting nut 77 is positioned on the central axis of the sheath rod 73 . A portion of the adjustment nut 77 is exposed outside the mechanism housing 71 . The adjustment nut 77 is rotatably supported with respect to the mechanism housing 71 . A connection gear 77B is attached to the other end of the adjustment nut 77 in the vehicle front-rear direction via a connection spring 77A. The connecting gear 77B is positioned on the central axis of the sheath rod 73. As shown in FIG. Depending on the position of the sheath rod 73 that is moved by driving the brake device 50, the coupling gear 77B switches the connection state of the sheath rod 73 to the coupling gear 73d.

As shown in FIG. 1 , a display 25 for displaying various information related to the operation of the railroad vehicle 100 is attached inside the vehicle body 10 , for example, in the driver's cab. A control device 20 is attached inside the vehicle body 10 . The control device 20 is connected to the cab (display 25). The control device 20 includes a control section 21 that controls the drive section 60 of the brake device 50 and a calculation section 22 that calculates the amount of wear of the brake shoe 40 . An angle sensor 89 is electrically connected to the control device 20 . The control device 20 receives a signal from the angle sensor 89 that indicates the rotational angular position of the hanger 76 about the connecting pin 83 with respect to the projecting portion 71A.

In addition, the operator or the like who fixed the new brake shoe 40 inputs to the control device 20 information about the time when the new brake shoe 40 is fixed and the wear margin of the new brake shoe 40 up to the wear limit. , they are stored. The wear limit of the brake shoe 40 is a reference position indicating a guideline for replacing the worn brake shoe 40 with a new brake shoe 40 so that the brake shoe 40 can generate an appropriate braking force.

Next, the operation of the brake device 50 controlled by the control section 21 in the control device 20 will be described. When compressed air is introduced into the drive housing 61 through the introduction hole 61b under the control of the control unit 21, the piston 62 and the output shaft 63 move toward one side in the longitudinal direction of the vehicle, as indicated by the arrow A in FIG. Moving. Then, as indicated by an arrow B in FIG. 2, the lever 72 rotates in one circumferential direction (clockwise direction in FIG. 2) about the support shaft 78. As shown in FIG. At this time, as indicated by arrow C in FIG. 2 , the lower end of lever 72 moves to the other side in the vehicle front-rear direction opposite to the moving direction of output shaft 63 . Along with this, the sheath rod 73 connected to the lever 72 and the push rod 74 connected to the sheath rod 73 also move to the other side in the vehicle front-rear direction. Then, the brake shoe head 75 and the brake shoe 40 move toward the tread surface 32 a of the wheel 32 , and the brake shoe 40 comes into contact with the tread surface 32 a of the wheel 32 .

On the other hand, when compressed air is not introduced into the drive housing 61 through the introduction hole 61b, the piston 62 and the output shaft 63 move to the other side in the vehicle longitudinal direction in the direction opposite to the arrow A shown in FIG. Then, the lever 72 rotates in the opposite direction to the arrow B shown in FIG. 2 in the other circumferential direction (counterclockwise direction in FIG. 2) about the support shaft 78 . At this time, the lower end portion of the lever 72 moves in the direction opposite to the arrow C shown in FIG. Along with this, the sheath rod 73 connected to the lever 72 and the push rod 74 connected to the sheath rod 73 also move to one side in the vehicle front-rear direction. Then, the brake shoe head 75 and the brake shoe 40 move away from the tread surface 32 a of the wheel 32 , and the brake shoe 40 is separated from the tread surface 32 a of the wheel 32 .

Here, when the brake shoe 40 comes into contact with the tread surface 32a of the wheel 32, as shown in FIG. Therefore, the brake shoe 40 needs to be replaced with a new brake shoe 40 when it has worn to a predetermined wear limit. Since the parts constituting the braking device 50 , such as the hanger 76 , do not contact the wheels 32 , the frequency of replacement of the brake shoe 40 is higher than that of the parts constituting the braking device 50 . Further, when the brake shoe 40 wears, the gap between the brake shoe 40 and the tread surface 32a of the wheel 32 tends to increase before the drive unit 60 is driven. The greater the gap between the brake shoe 40 and the tread 32a of the wheel 32 before the drive unit 60 is driven, the greater the amount of movement of the brake shoe head 75 and the brake shoe 40 driven by the brake device 50. In FIG. 3, the position of the hanger 76 when the brake shoe 40 that is not worn is in contact with the tread surface 32a of the wheel 32 is shown imaginarily by a chain double-dashed line.

When the brake shoe head 75 moves to the other side in the longitudinal direction of the vehicle as indicated by arrow C in FIG. 2) in one direction in the circumferential direction (clockwise direction in FIG. 2). Here, the rotational state of the hanger 76 when the brake shoe 40 and the tread surface 32a of the wheel 32 come into contact varies depending on the wear amount of the brake shoe 40. As shown in FIG. Specifically, as the amount of wear of the brake shoe 40 increases, the brake shoe head 75 approaches the tread surface 32a of the wheel 32 when the brake shoe 40 and the tread surface 32a of the wheel 32 come into contact with each other. When the brake shoe 40 and the tread surface 32a of the wheel 32 come into contact with each other, the position of the other end of the hanger 76 connected to the brake shoe head 75 changes so as to approach the tread surface 32a of the wheel 32. Therefore, the rotational angular position of the hanger 76 about the connecting pin 83 with respect to the protruding portion 71A changes depending on the amount of wear of the brake shoe 40 .

As indicated by arrow B in FIG. 2, when the lever 72 rotates to one side in the circumferential direction around the support shaft 78, the contact portion 72A of the lever 72 contacts the roller portion 91A of the clearance adjustment mechanism 90. . Then, as indicated by an arrow E in FIG. 4(b), the first link 91 in the gap adjusting mechanism 90 moves downward. Then, when the second link 95 rotates to one side in the circumferential direction (clockwise direction in FIG. 4) about the support shaft 95A, the pawl portion 97 moves upward as indicated by the arrow F in FIG. 4(b). Moving. The gap between the brake shoe 40 and the tread surface 32a of the wheel 32 before the drive unit 60 is driven is adjusted according to the amount of movement of the pawl portion 97 .

Specifically, the larger the gap between the brake shoe 40 and the tread surface 32a of the wheel 32 before the drive unit 60 is driven, the larger the lever 72 rotates about the support shaft 78. As shown in FIG. Then, the amount of movement of the first link 91 that moves due to the contact of the contact portion 72A of the lever 72 increases. As the amount of movement of the first link 91 increases, the amount of movement of the claw portion 97 increases.

When the amount of movement of the tip portion 97a of the claw portion 97 is equal to or greater than one pitch of the tooth portion of the gear portion 73c, the contact relationship between the contact portion 72A of the lever 72 and the roller portion 91A of the first link 91 is released. 4(c), the tip portion 97a of the claw portion 97 meshes with the gear portion 73c of the sheath rod 73. As shown in FIG. Then, as indicated by arrow G in FIG. 4D, the biasing force of the second coil spring 98 causes the claw portion 97 to rotate the sheath rod 73 in the other circumferential direction (counterclockwise direction in FIG. 4). Then, as indicated by arrow C in FIG. 2 , the push rod 74 moves to the other side in the vehicle longitudinal direction with respect to the sheath rod 73 due to the rotation of the sheath rod 73 . As a result, the gap between the brake shoe 40 and the tread surface 32a of the wheel 32 before the drive unit 60 is driven becomes smaller.

On the other hand, when the amount of movement of the tip portion 97a of the claw portion 97 is less than one pitch of the tooth portion of the gear portion 73c, the contact relationship between the contact portion 72A of the lever 72 and the roller portion 91A of the first link 91 is When released, the tip portion 97a of the claw portion 97 does not mesh with the gear portion 73c of the sheath rod 73. As shown in FIG. Therefore, the sheath bar 73 does not rotate in the circumferential direction. Since the push rod 74 does not move in the longitudinal direction of the vehicle with respect to the sheath rod 73, the gap between the brake shoe 40 and the tread surface 32a of the wheel 32 before the drive unit 60 is driven is maintained without changing.

Further, as shown in FIG. 2 , when the sheath rod 73 is positioned on the other side in the vehicle front-rear direction due to the drive of the brake device 50 , the connection gear 77</b>B is not connected to the connection gear 73 d of the sheath rod 73 . On the other hand, when the brake device 50 is not driven and the sheath rod 73 is positioned on one side in the vehicle front-rear direction, the coupling gear 77B is coupled to the coupling gear 73d of the sheath rod 73 . When the connecting gear 77B is connected to the connecting gear 73d of the sheath rod 73 in this manner, the rotation angle of the sheath rod 73 with respect to the push rod 74 can be changed by manually rotating the adjustment nut 77 by an operator or the like. can be adjusted. By adjusting the rotation angle of the sheath rod 73 with respect to the push rod 74, the size of the gap between the brake shoe 40 and the tread surface 32a of the wheel 32 before the drive unit 60 is driven can be adjusted.

Next, the wear determination process of the brake shoe 40 performed by the control device 20 will be described. The control device 20 operates from when the system activation switch of the railway vehicle 100 is turned on and the control device 20 starts to operate until when the system activation switch is turned off and the control device 20 ends the operation. Wear determination processing is repeatedly executed for each cycle.

As shown in FIG. 5, when the wear determination process is started, the control device 20 executes the process of step S11. In step S11, the control device 20 determines whether or not the change amount X of the detection value detected by the angle sensor 89 is equal to or less than a predetermined value Z which is set in advance. Here, the change amount X of the detection value of the angle sensor 89 is the absolute value of the difference between the detection value of the angle sensor 89 detected this time and the detection value of the angle sensor 89 detected last time. Also, the predetermined value Z is determined as follows. A reference of the rotation angle position of the hanger 76 that changes per unit time when the brake shoe 40 moves from a position away from the wheel 32 to a position where the brake shoe 40 abuts on the tread surface 32a of the wheel 32 by driving the brake device 50. A standard value is defined as the value of The predetermined value Z is set as a value smaller than the above reference value. That is, the predetermined value Z is a value for determining whether the braking device 50 is in a transitional state from non-braking to braking or from a transitional state from braking to non-braking. In step S11, when the control device 20 determines that the amount of change X in the detection value detected by the angle sensor 89 is greater than the preset predetermined value Z (S11: NO), the current wear determination process ends. do. On the other hand, in step S11, when the control device 20 determines that the change amount X of the detection value detected by the angle sensor 89 is equal to or less than the predetermined value Z (S11: YES), the process proceeds to step S12. proceed.

In step S12, the control device 20 determines whether or not the braking device 50 is being driven. In step S12, when the control device 20 determines that the brake device 50 is not being driven (S12: NO), the current wear determination process ends. On the other hand, in step S12, when the control device 20 determines that the brake device 50 is being driven (S12: YES), the process proceeds to step S13. That is, the braking device 40 is in contact with the tread surface 32a of the wheel 32 by driving the braking device 50, and the detected value of the angle sensor 89 indicates that the rotation angle of the hanger 76 is changing by driving the braking device 50. If it is determined that the detection value is not present, the process proceeds to step S13.

In step S<b>13 , the control device 20 determines whether or not it is the first braking by the new brake shoe 40 . Here, the new brake shoe 40 means a new brake shoe 40 fixed to the brake device 50 for the first time, or a worn brake shoe 40 that has been fixed to the brake device 50 and has worn out. A new brake shoe 40 replaced in place of the The control device 20 determines whether or not it is the first braking with the new brake shoe 40 based on the time when the new brake shoe 40 is fixed. In step S13, when the control device 20 determines that it is the first braking by the new brake shoe 40 (S13: YES), the process proceeds to step S14.

In step S14, the control device 20 stores the detected value of the angle sensor 89 detected this time as the initial value of the rotational angular position of the hanger 76 about the connecting pin 83 with respect to the projecting portion 71A. In this embodiment, the initial value stored in step S14 is the position detected by the detection unit at an arbitrary time. After that, the control device 20 ends the current wear determination process.

On the other hand, in step S13, when the control device 20 determines that it is not the first braking by the new brake shoe 40 (S13: NO), the process proceeds to step S21. In step S21, the control device 20 stores the detected value of the angle sensor 89 detected this time as the current value of the rotational angular position of the hanger 76 about the connecting pin 83 with respect to the projecting portion 71A. In this embodiment, the current value stored in step S21 is the position detected by the detection unit after an arbitrary point in time. After that, the control device 20 advances the process to step S22.

In step S<b>22 , the calculator 22 in the control device 20 calculates the amount of wear of the brake shoe 40 . Here, when the brake shoe 40 and the tread surface 32a of the wheel 32 come into contact with each other as the brake shoe 40 wears, the brake shoe head 75 moves closer to the tread surface 32a of the wheel 32. Then, the position of the other end of the hanger 76 connected to the brake shoe head 75 changes so as to approach the tread surface 32a of the wheel 32 . Therefore, depending on the amount of wear of the brake shoe 40, the rotational angular position of the hanger 76 about the connecting pin 83 with respect to the projecting portion 71A changes. Therefore, the calculation unit 22 calculates the initial value of the rotation angle position of the hanger 76 about the connecting pin 83 with respect to the projecting portion 71A in step S14, and the initial value of the rotation angle position of the hanger 76 about the connecting pin 83 with respect to the projecting portion 71A in step S21. The wear amount of the brake shoe 40 is calculated based on the current value of the rotation angle position. The amount of wear of the brake shoe 40 is the absolute value of the difference between the thickness of the brake shoe 40 in the radial direction of the wheel 32 when it is not worn and the thickness when the brake shoe 40 is worn. After that, the control device 20 advances the process to step S23.

In step S23, the control device 20 determines whether or not the calculation of the wear amount of the brake shoe 40 in step S22 is the first calculation of the wear amount of the brake shoe 40 in question. In step S23, when the control device 20 determines that the calculation of the wear amount of the brake shoe 40 in step S22 is the first calculation of the wear amount of the brake shoe 40 (S23: YES), the wear determination process of this time is performed. finish. On the other hand, in step S23, when the controller 20 determines that the calculation of the wear amount of the brake shoe 40 in step S22 is not the first calculation of the wear amount of the brake shoe 40 (S23: NO), the process proceeds to step S24. proceed.

In step S<b>24 , the calculator 22 in the control device 20 calculates the wear rate of the brake shoe 40 . Specifically, the calculation unit 22 calculates the absolute value of the difference between the amount of wear of the current brake shoe 40 and the amount of wear of the first brake shoe 40, and the calculation of the amount of wear of the first brake shoe 40. The wear rate of the brake shoe 40 is calculated based on the length of the period until the calculation of the wear amount. For example, the absolute value of the difference between the amount of wear of the current brake shoe 40 and the amount of wear of the first brake shoe 40 is 10 mm, and the amount of wear of the current brake shoe 40 is calculated from the calculation of the amount of wear of the first brake shoe 40. If the length of time to is 50 days, the brake shoe 40 has worn at a wear rate of 0.2 mm per day. In addition, the wear amount of the brake shoe 40 is small in one braking by the brake shoe 40, and the amount of change in the detection value of the angle sensor 89 is extremely small, so the initial wear amount of the brake shoe 40 is usually substantially zero . Therefore, in this embodiment, the initial wear amount (zero) of the brake shoe 40 is the wear amount of the brake shoe 40 at an arbitrary time. Also, the amount of wear of the brake shoe 40 at this time is the amount of wear of the brake shoe 40 after an arbitrary point in time. If the wear rate of the brake shoe 40 cannot be calculated appropriately, for example, if the absolute value of the difference between the current wear amount of the brake shoe 40 and the first wear amount of the brake shoe 40 is 0 (zero) mm The wear rate in step S24 is set to 0 (zero). After that, the control device 20 advances the process to step S25.

In step S25, the calculation unit 22 in the control device 20 predicts the replacement timing of the brake shoe 40. FIG. Specifically, the calculation unit 22 subtracts the current wear amount of the brake shoe 40 calculated in step S22 from the wear allowance up to the new wear limit of the brake shoe 40, and the current brake calculated in step S24. Based on the wear rate of the wheel 40, the replacement timing of the wheel 40 is calculated. For example, if the wear allowance of the new brake shoe 40 up to the wear limit is 40 mm and the current wear amount of the brake shoe 40 calculated in step S22 is 10 mm, the wear amount of the new brake shoe 40 up to the wear limit The value obtained by subtracting the current wear amount of the brake shoe 40 calculated in step S22 from the wear margin is 30 mm. If the current wear rate of the brake shoe 40 calculated in step S24 is 0.2 mm per day, the time to replace the brake shoe 40 will be 150 days from the present time. If the current wear rate of the brake shoe 40 calculated in step S24 is 0 (zero), the preset replacement time of the brake shoe 40 (for example, after 200 days) is set as the replacement time in step S25. . After that, the control device 20 advances the process to step S26.

In step S26, the control device 20 determines whether or not the time to replace the brake shoe 40 has passed. Specifically, when the replacement time predicted in step S25 is 0 days or less, the control device 20 determines that the replacement time for the brake shoe 40 has passed. That is, when the current wear amount of the brake shoe 40 calculated in step S22 is greater than or equal to the wear amount up to the wear limit of the brake shoe 40, it is determined that the replacement time for the brake shoe 40 has passed. In step S26, when the controller 20 determines that the replacement time for the brake shoe 40 has passed (S26: YES), the process proceeds to step S31.

In step S31, the control device 20 displays a warning on the display 25 indicating that the time to replace the brake shoe 40 has passed. After that, the control device 20 ends the current wear determination process.

On the other hand, in step S26, when the controller 20 determines that the replacement time for the brake shoe 40 has not elapsed (S26: NO), the process proceeds to step S32. In step S32, control device 20 displays on display 25 the replacement timing predicted in step S25. After that, the control device 20 ends the current wear determination process.

The action and effect of this embodiment will be described.
(1) The calculation unit 22 in the control device 20 calculates the wear amount of the brake shoe 40 based on the rotation angle position of the hanger 76 about the connecting pin 83 with respect to the projecting portion 71A detected by the angle sensor 89. .

Here, if a sensor for detecting the amount of wear of the brake shoe 40 is attached to the brake shoe 40, every time the worn brake shoe 40 is replaced with a new brake shoe 40 A new sensor needs to be attached to the brake shoe 40 . Therefore, when a sensor is attached to the brake shoe 40, the work for replacing the brake shoe 40 tends to be complicated.

The angle sensor 89 is attached to the brake device 50 that moves the brake shoe 40 with respect to the tread surface 32a of the wheel 32, more specifically, the joint between the projecting portion 71A and the hanger 76. As shown in FIG. That is, the angle sensor 89 is not attached to the brake shoe 40 itself. Therefore, when replacing the worn brake shoe 40 with a new brake shoe 40 , there is no need to attach a sensor to the new brake shoe 40 . Therefore, compared to a configuration in which a sensor is attached to the brake shoe 40, the work for replacing the brake shoe 40 can be simplified.

(2) The angle sensor 89 is attached to the joint between the projecting portion 71A and the hanger 76 in the braking device 50 . Here, in general, the angle sensor 89 (rotary potentiometer) for the rotational angular position of the hanger 76 about the connecting pin 83 with respect to the protruding portion 71A is compared with the linear potentiometer for calculating the linear movement distance. and small. Therefore, the size of the angle sensor 89 does not become excessively large, and the size of the entire brake device 50 does not become excessively large due to the size of the angle sensor 89 being excessively large.

(3) The angle sensor 89 is attached to a connecting portion between the protruding portion 71A exposed to the outside of the braking device 50 and the hanger 76 . Therefore, the mounting work of the angle sensor 89 to the brake device 50 can be performed without disassembling the mechanism housing 71 and the like, and the mounting work can be easily simplified. As a result, the angle sensor 89 can be easily attached to an existing brake device attached to the truck 30 without the angle sensor 89, for example.

(4) By the way, if the angle sensor 89 is to be arranged inside the mechanism housing 71 of the brake device 50, it is necessary to secure a space for mounting the angle sensor 89 inside the mechanism housing 71. Therefore, when the angle sensor 89 is attached inside the mechanism housing 71 , design changes such as the shape of the mechanism housing 71 and the layout of parts inside the mechanism housing 71 may be forced.

In this respect, as described above, the angle sensor 89 is attached to the joint between the projecting portion 71A exposed to the outside of the brake device 50 and the hanger 76 . Therefore, compared to the configuration in which the angle sensor 89 is arranged inside the mechanism housing 71 in the brake device 50, the possibility of requiring a design change is low.

(5) The calculation unit 22 in the control device 20 calculates the wear speed of the brake shoe 40 based on the amount of wear of the brake shoe 40 . Then, the calculation unit 22 in the control device 20 is based on a value obtained by subtracting the current wear amount of the brake shoe 40 from the wear allowance up to the new wear limit of the brake shoe 40, and the current wear speed of the brake shoe 40 , predicts the replacement timing of the brake shoe 40 . As a result, the operator or the like can appropriately plan the time to replace the brake shoe 40 based on the predicted replacement time of the brake shoe 40 .

(6) When the railway vehicle 100 runs, the bogie 30 vibrates due to vibrations transmitted from the wheels 32 . Here, if the control device 20 is attached to the truck 30, the control unit 21 and the calculation unit 22 in the control device 20 may malfunction due to vibration.

The control device 20 is attached inside the vehicle body 10 above the air spring 35 . Therefore, vibrations transmitted from the bogie 30 to the vehicle body 10 are reduced by the air springs 35 . As a result, compared to, for example, a configuration in which the control device 20 is attached to the carriage 30 below the air spring 35, the vibration transmitted to the control unit 21 and the calculation unit 22 in the control device 20 is reduced. Therefore, it is possible to prevent the control unit 21 and the calculation unit 22 in the control device 20 from breaking down due to vibration.

(Second embodiment)
The second embodiment will be described below with reference to FIGS. 6 and 7. FIG. In addition, in the description of the second embodiment, the points of difference from the first embodiment will be mainly described. become

In this second embodiment, a disc-shaped disc 33 is fixed between two wheels 32 on each axle 31 . Two discs 33 are arranged spaced apart in the vehicle width direction. The disk 33 rotates together with the axle 31 and the wheel 32 .

A brake device 150 for braking the rotation of the disk 33 is attached to the carriage 30 . As shown in FIG. 6, the brake device 150 is a so-called disc brake type brake device that brakes the rotation of the disc 33 by sandwiching the disc 33 to be braked between a pair of brake pads 140 as a braking portion. . A total of eight brake devices 150 are attached to the railcar 100 corresponding to a total of eight discs 33 .

Brake device 150 is arranged adjacent to disk 33 on one side in the vehicle front-rear direction (the lower side in FIG. 6). The brake device 150 includes a drive section 160 as a drive source for driving the brake pads 140 and a mechanism section 170 for transmitting the drive force from the drive section 160 to the pair of brake pads 140 .

The driving portion 160 includes a columnar body portion 161 that extends in the vehicle width direction (horizontal direction in FIG. 6) as a whole, and an output portion 162 that moves relative to the body portion 161 in the vehicle width direction. The body portion 161 is arranged on one side (the right side in FIG. 6) of the output portion 162 in the vehicle width direction. An internal space for introducing compressed air from an air source (not shown) is defined in the body portion 161 .

An output portion 162 is connected to an end portion of the body portion 161 on the other side in the vehicle width direction (the left side in FIG. 6) via an output shaft (not shown). When the compressed air is introduced into the internal space of the body portion 161, the amount of protrusion of the output portion 162 with respect to the body portion 161 increases. Accordingly, the tip of the output portion 162 moves away from the body portion 161 in the vehicle width direction. On the other hand, when the compressed air is not introduced into the internal space of the body portion 161, the amount of protrusion of the output portion 162 with respect to the body portion 161 is reduced. Accordingly, the tip of the output portion 162 moves closer to the main body portion 161 in the vehicle width direction.

Arms 171 extending to the other side in the vehicle front-rear direction (upper side in FIG. 6) are connected to both ends of the driving portion 160 in the vehicle width direction. Specifically, one of the pair of arms 171 is rotatably connected to the body portion 161 via a connecting pin 181 . The other of the pair of arms 171 is rotatably connected to the output section 162 via a connecting pin 181 .

The other end of each arm 171 in the vehicle front-rear direction extends to a position overlapping the disk 33 in the vehicle front-rear direction. In other words, the disc 33 is positioned between the ends of the pair of arms 171 on the other side in the vehicle front-rear direction. A mounting portion 176 is connected via a connecting pin 185 to the end of each arm 171 on the other side in the vehicle front-rear direction. The mounting portion 176 is connected to the disk 33 side of each arm 171 in the vehicle width direction. The mounting portion 176 has a substantially triangular shape in which the width in the vehicle front-rear direction increases toward the disk 33 in the vehicle width direction when viewed from above. Further, the surface of the mounting portion 176 on the disk 33 side in the vehicle width direction is a flat surface along the end surface of the disk 33 . The mounting portion 176 can swing around the connecting pin 185 .

A brake pad 140 is fixed to the mounting portion 176 . The brake pad 140 has a substantially flat plate shape that follows the end surface of the disc 33 . The brake pad 140 is a brake friction material that is pressed against the disc 33 to generate a braking force due to frictional force, and the material of the brake pad 140 is synthetic resin, sintered body, or the like.

Midway portions of the pair of arms 171 in the vehicle front-rear direction (substantially central portions in the vehicle front-rear direction in this embodiment) are connected via support portions 173 . The support portion 173 has a Y shape as a whole when viewed from above. Two upper ends of the Y shape of the support portion 173 (ends on the other side in the vehicle front-rear direction) are connected to the respective arms 171 via connecting pins 183 . Therefore, each arm 171 is rotatably connected to the Y-shaped upper end portion of the support portion 173 with the connecting pin 183 as the center. The support portion 173 is fixed to the carriage 30 via a bracket (not shown).

An angle sensor 189 for detecting the rotational angular position of the arm 171 about the connecting pin 183 with respect to the support portion 173 is attached to the connection point between the arm 171 and the support portion 173 . The angle sensor 189 is, for example, a rotary potentiometer. In this embodiment, an angle sensor 189 is attached only to one of the pair of arms 171 (the right arm 171 in FIG. 6). In this embodiment, the angle sensor 189 is a detection unit that detects the positions of components of the brake device 150 . Also, the arm 171 is a component of the brake device 150 whose rotational position (rotational angular position) is detected by the detection unit.

Next, the operation of the braking device 150 controlled by the control section 21 in the control device 20 will be described. When compressed air is introduced into the internal space of the body portion 161 of the driving portion 160 under the control of the control portion 21, the output portion 162 and the body portion 161 move in the vehicle width direction as indicated by arrows H and K in FIG. move away from each other. Then, as indicated by an arrow I in FIG. 6, the arm 171 on one side in the vehicle width direction rotates about the connecting pin 183 in one circumferential direction (counterclockwise direction in FIG. 6). 6, the arm 171 on the other side in the vehicle width direction rotates about the connecting pin 183 in the other circumferential direction (clockwise direction in FIG. 6). At this time, as indicated by arrows J and M in FIG. 6, the ends of the pair of arms 171 on the other side in the vehicle front-rear direction move toward each other in the vehicle width direction. Then, the mounting portion 176 and the brake pads 140 move toward the disc 33 and each brake pad 140 comes into contact with the end face of the disc 33 . The rotation of the disk 33 is braked by being sandwiched between the pair of brake pads 140 .

On the other hand, when the compressed air is not introduced into the internal space of the body portion 161 of the driving portion 160 under the control of the control portion 21, the output portion 162 and the body portion 161 move in the direction opposite to the arrows H and K shown in FIG. They move so as to approach each other in the vehicle width direction. 6, the arm 171 on one side in the vehicle width direction rotates about the connecting pin 183 in the other circumferential direction (clockwise direction in FIG. 6). 6, the arm 171 on the other side in the vehicle width direction rotates about the connecting pin 183 in one circumferential direction (counterclockwise direction in FIG. 6). At this time, the ends of the pair of arms 171 on the other side in the vehicle front-rear direction move away from each other in the vehicle width direction in the direction opposite to arrows J and M shown in FIG. Then, the mounting portion 176 and the brake pads 140 move away from the disc 33 , and each brake pad 140 separates from the end face of the disc 33 .

Here, when the brake pad 140 comes into contact with the disc 33, the brake pad 140 gradually wears due to friction with the disc 33, as shown in FIG. Therefore, it is necessary to replace the brake pad 140 with a new brake pad 140 when the brake pad 140 has worn to a predetermined wear limit. In addition, in the brake device 150, since the pair of brake pads 140 sandwich the disc 33 to brake the rotation of the disc 33, the wear amount of each brake pad 140 is substantially the same. Since the parts constituting the brake device 150 do not come into contact with the disc 33 , the replacement frequency of the brake pads 140 is higher than the frequency of replacement of the components constituting the brake device 150 . Also, in FIG. 7, the position of the arm 171 when the brake pad 140 without wear is in contact with the disc 33 is shown imaginarily by a chain double-dashed line.

Further, when the brake pad 140 wears, the attachment portion 176 moves closer to the disc 33 in the vehicle width direction. Then, the position of the other end of the arm 171 in the vehicle front-rear direction changes so as to approach the disk 33 in the vehicle width direction. Therefore, the rotational angular position of the arm 171 about the connecting pin 183 with respect to the support portion 173 changes depending on the wear amount of the brake pad 140 .

Also in the second embodiment, the control device 20 repeatedly executes the same wear determination process as in the first embodiment at predetermined intervals. Further, in the second embodiment, the same effects as (1) to (6) in the first embodiment can be obtained.

As described above, the rotational angular position of the arm 171 about the connecting pin 183 with respect to the support portion 173 changes according to the amount of wear of the brake pad 140 . Therefore, the wear amount of the brake pad 140 can be calculated based on the rotational angular position of the arm 171 about the connecting pin 183 with respect to the support portion 173 detected by the angle sensor 189 . Also, as described above, the wear amount of each brake pad 140 is substantially the same. Therefore, the wear amount of one brake pad 140 calculated based on the rotational angular position of the arm 171 about the connecting pin 183 with respect to the support portion 173 detected by the angle sensor 189 is the wear amount of the other brake pad 140. can be estimated to be approximately the same as

Each of the above embodiments can be implemented with the following modifications. Each of the above-described embodiments and the following modifications can be implemented in combination with each other within a technically consistent range.
- In the first embodiment, the configuration for calculating the wear amount of the brake shoe 40 can be changed. For example, as shown in FIGS. 2 and 3 , a rotation sensor 101 may be attached to the sheath rod 73 as a detection unit for detecting the rotation angle of the sheath rod 73 with respect to the push rod 74 . Then, the calculation unit 22 may calculate the position of the push rod 74 with respect to the sheath rod 73 in the longitudinal direction of the vehicle based on the rotation angle of the sheath rod 73 with respect to the push rod 74 and calculate the wear amount of the brake shoe 40 . As described above, whenever the clearance between the brake shoe 40 and the tread surface 32a of the wheel 32 before the drive unit 60 is driven due to wear of the brake shoe 40 becomes a predetermined value or more, the sheath rod 73 is rotated by the clearance adjustment mechanism 90. do. Then, the push rod 74 moves to the other side in the longitudinal direction of the vehicle with respect to the sheath rod 73 due to the rotation of the sheath rod 73 . Here, as shown in FIGS. 2 and 3, the amount of movement of the push rod 74 relative to the sheath rod 73 increases as the wear amount of the brake shoe 40 increases.

- For example, as shown in FIG. 4, a position sensor 102 may be attached to the first link 91 as a detector for detecting the position of the first link 91 with respect to the spring receiving portion 92 . Then, the calculation unit 22 may calculate the position of the push rod 74 with respect to the sheath rod 73 in the longitudinal direction of the vehicle based on the position of the first link 91 with respect to the spring receiving portion 92, and calculate the wear amount of the brake shoe 40. . If the position of the push rod 74 with respect to the sheath rod 73 is the same, the larger the gap between the brake shoe 40 and the tread surface 32a of the wheel 32 before the drive unit 60 is driven, the more the support shaft 78 is driven by the drive unit 60. , the lever 72 is largely rotated. Then, as indicated by arrow E in FIG. 4B, the amount of movement of the first link 91 that moves due to the contact of the contact portion 72A of the lever 72 increases. Here, when the sheath rod 73 is rotated by the gap adjusting mechanism 90, the gap between the brake shoe 40 and the tread surface 32a of the wheel 32 before the driving section 60 is driven becomes smaller. Then, when the gap between the brake shoe 40 and the tread surface 32a of the wheel 32 before the drive unit 60 is driven is reduced in this way, the amount of movement of the first link 91 moved by the contact of the contact portion 72A of the lever 72 is become smaller. Therefore, when the amount of movement of the first link 91 driven by the driving portion 60 becomes small, it can be determined that the sheath rod 73 has been rotated by the gap adjusting mechanism 90 . Then, the position of the push rod 74 with respect to the sheath rod 73 in the longitudinal direction of the vehicle can be calculated from the number of clearance adjustments made by the clearance adjustment mechanism 90 .

・In addition, before and after the sheath rod 73 is rotated by the gap adjusting mechanism 90, the amount of rotation of the lever 72 that is rotated by the drive of the drive unit 60 changes. Therefore, for example, as shown in FIGS. 2 and 3, a position sensor 103 may be attached to the mechanism housing 71 as a detection unit for detecting the position of one end of the lever 72 with respect to the mechanism housing 71 . The mounting position of the position sensor 103 is, for example, a position facing the lever 72 on the wall of the mechanism housing 71 . Then, the calculation unit 22 may calculate the position of the push rod 74 with respect to the sheath rod 73 in the longitudinal direction of the vehicle based on the position of the one end of the lever 72 with respect to the mechanism housing 71, and calculate the wear amount of the brake shoe 40. .

- In each of the modifications described above, the sheath rod 73, the first link 91, the lever 72, and the like are all located inside the mechanism housing 71 (brake device 50). As in these modified examples, the component whose position is detected by the detector may be located inside the brake device 50 and not exposed to the outside of the brake device 50 .

Further, when the sheath rod 73 is rotated by the clearance adjustment mechanism 90, the push rod 74 moves to the other side in the vehicle longitudinal direction with respect to the sheath rod 73, as shown in FIG. Therefore, for example, a position sensor 105 may be attached to the sheath rod 73 as a detection unit for detecting the position of the push rod 74 in the longitudinal direction of the vehicle with respect to the sheath rod 73 . Then, the calculation unit 22 may calculate the amount of wear of the brake shoe 40 based on the position of the push rod 74 relative to the sheath rod 73 in the longitudinal direction of the vehicle. A component whose position is detected by the detection unit may move linearly.

When the push rod 74 is moved to the other side in the vehicle front-rear direction with respect to the sheath rod 73 by the gap adjustment mechanism 90, the push rod 74 moves toward the vehicle against the mechanism housing 71 even before the drive unit 60 is driven. Move to the other side in the front-rear direction. Therefore, for example, a position sensor 106 as a detection unit that detects the position of the push rod 74 with respect to the mechanism housing 71 in the longitudinal direction of the vehicle may be attached to the mechanism housing 71 . The mounting position of the position sensor is, for example, a portion near the central axis of the threaded portion 74 a of the push rod 74 in the mechanism housing 71 . Then, the calculation unit 22 may calculate the wear amount of the brake shoe 40 based on the position of the push rod 74 with respect to the mechanism housing 71 .

- Further, in the above-described first embodiment, for example, the sheath rod 73 and the adjusting nut 77 may be connected so that they always rotate integrally. In such a case, a rotation sensor 107 may be attached to the mechanism housing 71 as a detection section for detecting the rotation angle of the adjustment nut 77 with respect to the mechanism housing 71 . Then, the calculation unit 22 may calculate the position of the push rod 74 with respect to the sheath rod 73 in the longitudinal direction of the vehicle based on the rotation angle of the adjustment nut 77 with respect to the mechanism housing 71 and calculate the wear amount of the brake shoe 40 .

In the first embodiment, the greater the amount of wear of the brake shoe 40, the closer the brake shoe head 75 is to the tread surface 32a of the wheel 32 when the brake shoe 40 and the tread surface 32a of the wheel 32 come into contact. Therefore, a position sensor 108 as a detection unit for detecting the position of the brake shoe head 75 with respect to the tread surface 32 a of the wheel 32 may be attached to the brake shoe head 75 . Then, the calculation unit 22 may calculate the wear amount of the brake shoe 40 based on the position of the brake shoe head 75 with respect to the tread surface 32 a of the wheel 32 . Here, since the brake shoe head 75 can swing around the connecting pin 82, the wear amount of the upper end portion of the brake shoe 40 and the wear amount of the lower end portion of the brake shoe 40 are different. Sometimes. Therefore, the position sensor 108 as a detection unit for detecting the position of the brake shoe head 75 with respect to the tread surface 32a of the wheel 32 may be attached to the upper end portion of the brake shoe head 75 and the lower end portion of the brake shoe head 75, respectively. .

Also, a position sensor as a detector for detecting the position of the other end of the hanger 76 with respect to the tread surface 32 a of the wheel 32 may be attached to the other end of the hanger 76 . Then, the calculation unit 22 may calculate the wear amount of the brake shoe 40 based on the position of the other end of the hanger 76 with respect to the tread surface 32 a of the wheel 32 .

・Furthermore, as the wear amount of the brake shoe 40 increases, the position of the other end of the hanger 76 connected to the brake shoe head 75 when the brake shoe 40 and the tread surface 32a of the wheel 32 abut against each other. change away from Therefore, a position sensor 104 as a detection unit for detecting the position of the other end of the hanger 76 with respect to the mechanism housing 71 may be attached to the mechanism housing 71 . Then, the calculation unit 22 may calculate the wear amount of the brake shoe 40 based on the position of the other end of the hanger 76 with respect to the mechanism housing 71 .

- In the second embodiment, the configuration for calculating the wear amount of the brake pad 140 can be changed. Here, as described above, when the brake pad 140 wears, the mounting portion 176 moves closer to the disc 33 in the vehicle width direction. Therefore, for example, a position sensor 111 may be attached to the attachment portion 176 as a detection portion for detecting the position of the attachment portion 176 with respect to the disk 33 . The calculator 22 may then calculate the amount of wear of the brake pad 140 based on the position of the mounting portion 176 with respect to the disc 33 . Here, when the difference between the amount of wear of one of the pair of brake pads 140 and the amount of wear of the other of the pair of brake pads 140 becomes excessively large, the position of the mounting portion 176 with respect to the disc 33 is detected by position sensor 111 may be attached to each attachment portion 176 .

Further, for example, the position sensor 112 as a detection unit for detecting the position of a portion of the arm 171 on the other side in the vehicle front-rear direction with respect to the disc 33 may be attached to a portion on the other side of the arm 171 in the vehicle front-rear direction. good.

Further, when the brake pad 140 wears, the position of the end of the arm 171 on one side in the vehicle front-rear direction changes so as to separate in the vehicle width direction. Therefore, for example, the position sensor 113 as a detection unit that detects the position of a portion on one side of the pair of arms 171 in the vehicle front-rear direction may be attached to a portion of the arms 171 on one side in the vehicle front-rear direction. Then, the calculation unit 22 may calculate the amount of wear of the brake pad 140 based on the position of a portion of the pair of arms 171 on one side in the vehicle front-rear direction.

- In the above-described first embodiment, abnormal wear of the brake shoe 40 may be determined by comparing the amount of wear of the brake shoe 40 fixed to each brake device 50 . For example, the calculator 22 calculates the average value of the wear amounts of the plurality of brake pads 40 . Then, when the amount of wear of any one of the brake shoe 40 is larger than the average value by a predetermined value or more, the calculation unit 22 determines that the brake shoe 40 is abnormally worn. The abnormal wear is a phenomenon in which the amount of wear of the brake shoe 40 becomes excessively large due to some cause such as excessively strong contact between the brake shoe 40 and the wheel 32 . Also, the above-described configuration related to determination of abnormal wear can be similarly applied to the second embodiment.

- In the said 1st Embodiment, the number of the angle sensors 89 in the rail vehicle 100 can be changed. For example, when the wear amount of each of the eight brake shoes 40 in the railway vehicle 100 is substantially the same, the wear amount of one brake shoe 40 may be calculated based on one angle sensor 89 in the railway vehicle 100. . That is, the number of angle sensors 89 in the railway vehicle 100 can be changed to one or more. Moreover, the change in the configuration regarding the number of detection units described above can be similarly applied to the second embodiment.

- In the first embodiment, the wear determination process can be changed. For example, if only the wear amount of the brake shoe 40 is calculated, the processing of steps S23 to S32 may be omitted. In addition, if the calculation of the wear speed of the brake shoe 40 is not performed in this way, a warning is displayed on the display 25 on the condition that the wear amount of the brake shoe 40 has reached the wear limit of the brake shoe 40. You may

・The timing for executing the wear determination process can be changed. For example, instead of executing the wear determination process at predetermined intervals while the control device 20 is operating, the wear determination process may be performed only while the brake device 50 is being driven. Further, the next wear determination process may be performed on the condition that a period (for example, several days) in which the amount of wear of the brake shoe 40 can change has passed since the last execution of the wear determination process.

・Furthermore, the configuration for calculating the wear rate of the brake shoe 40 in step S24 can be changed. For example, the calculation unit 22 calculates the absolute value of the difference between the current wear amount of the brake shoe 40 and the wear amount of the brake shoe 40 a predetermined number of times before this time, and the calculation of the wear amount of the brake shoe 40 a predetermined number of times before this time. The wear rate of the brake shoe 40 may be calculated based on the length of the period until the calculation of the wear amount of the brake shoe 40 this time. Also, the above-described change in configuration regarding the wear determination process can be similarly applied to the second embodiment.

- In the above-described first and second embodiments, the manner of indicating the replacement timing of the brake shoe 40 can be changed. For example, the time to replace the brake shoe 40 may be indicated by lighting a lamp. Further, for example, information indicating the replacement timing of the brake shoe 40 may be transmitted to a control center or the like outside the railroad vehicle 100 by wireless communication or the like, and the information may be received by the control center or the like.

- In the said 1st Embodiment and 2nd Embodiment, the attachment position of the control apparatus 20 can be changed. For example, if the control unit 21 and the calculation unit 22 in the control device 20 are highly durable against vibration, the control device 20 may be attached to the carriage 30 . Further, for example, the control device 20 may be attached to the wall portion of the mechanism housing 71 in each braking device 50 . In this case, since the brake device 50 and the control device 20 are configured integrally, the brake device 50 and the control device 20 can be handled as one brake device.

・Technology for calculating the amount of wear of the braking portion, regardless of the structure of the braking device in the first and second embodiments, in the case of a braking device in which the driving force is mechanically transmitted to move the braking portion. can be applied. In other words, regardless of the structure of the braking device, the detector may be attached to a component of the braking device that moves together with the braking portion.

A... Arrow, B... Arrow, C... Arrow, D... Arrow, E... Arrow, F... Arrow, G... Arrow, H... Arrow, I... Arrow, J... Arrow, K... Arrow, L... Arrow, M... Arrow, X... Change amount of detected value, Z... Predetermined value, 10... Vehicle body, 20... Control device, 21... Control unit, 22... Calculation unit, 25... Display, 30... Truck, 31... Axle, 32... Wheel, 32a... Tread, 33... Disc, 35... Air spring, 40... Brake shoe, 50... Brake device, 60... Driving part, 61... Drive housing, 61a... Bottom wall, 61b... Introduction hole, 62... Piston, 63... Output Axle 64 Spring 70 Mechanism portion 71 Mechanism housing 71a Opening 71A Protrusion 72 Lever 72A Contact portion 72a Fixing hole 73 Sheath rod 73a Cylindrical portion 73b... Spherical bearing, 73c... Gear part, 73d... Connection gear, 74... Push rod, 74a... Screw part, 74b... Fixed part, 74d... Tilt hole, 75... Bracer head, 76... Hanger, 77... Adjusting nut, 77A ... Connection spring 77B ... Connection gear 78 ... Support shaft 79 ... Cover 81 ... Connection pin 82 ... Connection pin 83 ... Connection pin 84 ... Tilt pin 89 ... Angle sensor 90 ... Gap adjustment mechanism DESCRIPTION OF SYMBOLS 91... 1st link, 91A... Roller part, 91B... Cylindrical part, 92... Spring receiving part, 92a... Through hole, 93... First coil spring, 94... Tooth holding part, 95... Second link, 95A... Support shaft , 95B... Connecting pin, 96... First supporting part, 97... Claw part, 97a... Tip part, 98... Second coil spring, 98A... Fixing pin, 99... Second supporting part, 100... Railway vehicle, 140... Brake Pad 150 Brake device 160 Driving unit 161 Main unit 162 Output unit 170 Mechanism unit 171 Arm 173 Supporting unit 176 Mounting unit 181 Connecting pin 183 Connecting pin , 185... Connecting pin, 189... Angle sensor.

Claims (8)

an angle detection unit that detects the position of a hanger of a braking device that is connected to a brake shoe that generates a braking force by frictional force and that moves together with the brake shoe;
A calculation unit that calculates the amount of wear of the brake shoe based on the position of the hanger detected by the angle detection unit at an arbitrary time and the position of the hanger detected by the angle detection unit after the arbitrary time and
The hanger is arranged in opposite directions about a rotation shaft to which the hanger is rotatably connected during braking when the brake shoe approaches the tread surface of the wheel and during non-braking when the brake shoe moves away from the tread surface of the wheel. A member that rotates in the direction of
The rotating shaft connects the hanger to the outside of the housing of the brake device and is exposed,
The wear amount calculation device, wherein the angle detection unit is attached to a connecting portion between the hanger and the housing , and detects a rotation position of the hanger about the rotation shaft. an angle detection unit that detects the position of an arm of a brake device that is connected to a pair of brake pads that generate a braking force due to frictional force and that moves together with the brake pads;
a calculation unit that calculates the amount of wear of the brake pad based on the position of the arm detected by the angle detection unit at an arbitrary time point and the position of the arm detected by the angle detection unit after the arbitrary time point; and
The arm is a rotary shaft to which the arm is rotatably connected during braking when the pair of brake pads approach the disc rotating integrally with the wheel and during non-braking when the pair of brake pads move away from the disc. is a member that rotates in the opposite direction about
The pivot shaft connects the arm and a support portion that supports the arm, and is exposed to the outside of the brake device together with the arm and the support portion ,
The wear amount calculation device, wherein the angle detection section is attached to a connecting portion between the arm and the support section , and detects a rotational position of the arm about the rotational axis. The wear amount calculation device according to claim 1 or 2, wherein the calculation unit calculates the wear rate based on the wear amount at an arbitrary time and the wear amount after the arbitrary time. The wear amount calculation device according to any one of claims 1 to 3, wherein the calculation unit is attached above an air spring fixed to the truck. A plurality of angle detection units provided for detecting the position of a hanger of each brake device connected to a brake shoe that generates a braking force by friction force for each of a plurality of brake devices and moves with the brake shoe;
Based on the position of the hanger of each of the braking devices detected by the plurality of angle detection units at an arbitrary time and the position of the hanger of each of the braking devices detected by the plurality of angle detection units after the arbitrary time a calculation unit that calculates the amount of wear of the brake shoe of each of the braking devices, and compares the amount of wear of the shoe of each of the plurality of braking devices to determine abnormal wear of the shoe of each of the braking devices; prepared,
The hanger is arranged in opposite directions about a rotation shaft to which the hanger is rotatably connected during braking when the brake shoe approaches the tread surface of the wheel and during non-braking when the brake shoe moves away from the tread surface of the wheel. A member that rotates in the direction of
The rotating shaft is connected to the hanger and exposed to the outside of the housing of the brake device,
The abnormal wear determination device, wherein the angle detection unit is attached to a connecting portion between the hanger and the housing , and detects a rotation position of the hanger about the rotation shaft. a plurality of angle detectors provided for detecting positions of component parts of each brake device connected to a pair of brake pads that generate braking force by frictional force for each of the plurality of brake devices and move together with the brake pads; ,
Based on the position of the arm of each of the braking devices detected by the plurality of angle detection units at an arbitrary time and the position of the arm of each of the braking devices detected by the plurality of angle detection units after the arbitrary time a calculation unit that calculates the amount of wear of the brake pads of each of the brake devices, and compares the amounts of wear of the brake pads of each of the plurality of brake devices to determine abnormal wear of the brake pads of each of the brake devices; prepared,
The arm is a rotary shaft to which the arm is rotatably connected during braking when the pair of brake pads approach the disc rotating integrally with the wheel and during non-braking when the pair of brake pads move away from the disc. is a member that rotates in the opposite direction about
The pivot shaft connects the arm and a support portion that supports the arm, and is exposed to the outside of the brake device together with the arm and the support portion ,
The abnormal wear determination device, wherein the angle detection section is attached to a connection portion between the arm and the support section , and detects a rotational position of the arm about the rotational axis. an angle detection unit that detects the position of a hanger of a braking device that is connected to a brake shoe that generates a braking force by frictional force and that moves together with the brake shoe;
A calculation unit that calculates the amount of wear of the brake shoe based on the position of the hanger detected by the angle detection unit at an arbitrary time and the position of the hanger detected by the angle detection unit after the arbitrary time and,
a drive unit that is a drive source for moving the brake shoe;
a mechanism part provided for transmitting the driving force from the drive part to the brake shoe and including the hanger as a part thereof,
The hanger is arranged in opposite directions about a rotation shaft to which the hanger is rotatably connected during braking when the brake shoe approaches the tread surface of the wheel and during non-braking when the brake shoe moves away from the tread surface of the wheel. A member that rotates in the direction of
The rotating shaft connects the hanger to the outside of the housing of the brake device and is exposed,
The angle detection unit is attached to a connecting portion between the hanger and the housing , and detects a rotation position of the hanger about the rotation shaft. Brake device. an angle detection unit that detects the position of an arm of a brake device that is connected to a pair of brake pads that generate a braking force due to frictional force and that moves together with the brake pads;
a calculation unit that calculates the amount of wear of the brake pad based on the position of the arm detected by the angle detection unit at an arbitrary time point and the position of the arm detected by the angle detection unit after the arbitrary time point; and,
a drive unit as a drive source for moving the pair of brake pads;
a mechanism part provided for transmitting the driving force from the driving part to the pair of brake pads and including the arm as a part thereof,
The arm is a rotary shaft to which the arm is rotatably connected during braking when the pair of brake pads approach the disc rotating integrally with the wheel and during non-braking when the pair of brake pads move away from the disc. is a member that rotates in the opposite direction about
The pivot shaft connects the arm and a support portion that supports the arm, and is exposed to the outside of the brake device together with the arm and the support portion ,
The angle detection section is attached to a connecting portion between the arm and the support section , and detects a rotational position of the arm about the rotational axis.

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