JP7475160B2 - Electric wire tension diagnostic device and tension diagnostic method - Google Patents

Description

This invention relates to a train line tension diagnosis device and tension diagnosis method that diagnoses the tension of a train line based on images of a tension adjustment device that adjusts the tension of the train line captured by a vehicle's camera while the train is moving.

Overhead contact lines are erected under tension, and deviation from the specified tension can lead to the collapse of the contact line's static structure and a decrease in wave propagation speed, resulting in a deterioration of current collection performance, so it is important to properly manage the tension. Conventionally, the condition of tension adjustment devices was monitored by humans through regular visual and manual inspection. However, tension adjustment devices are distributed along railway lines, and inspecting them on foot, etc., requires a great deal of time and effort. For this reason, frequent inspection of tension adjustment devices is also difficult.

A conventional tension abnormality detection system includes a pressure sensor that detects the gas pressure of a gas spring tension balancer that adjusts the tension of the overhead train line's contact wire to a predetermined level, an analysis and display device that is fixed to a support and calculates and displays the state of the contact wire from the detection value of the pressure sensor, a solar cell that supplies power to the analysis and display device, and a cable that connects the pressure sensor and the analysis and display device (see, for example, Patent Document 1). In this conventional tension abnormality detection system, the pressure sensor detects the pressure of the gas spring tension balancer, and the analysis and display device calculates and displays the tension of the contact wire based on the output signal of the pressure sensor.

A conventional weight position detection device includes a line sensor camera that photographs an automatic tension adjustment device that adjusts the tension of the trolley wire to a predetermined level while traveling with the vehicle, a circle detection processing unit that calculates the position and diameter of a circle in the line sensor image captured by the line sensor camera, and a line segment detection processing unit that converts the actual length of a line segment extending downward from the circle in the line sensor image (see, for example, Patent Document 2). This conventional weight position detection device calculates the distance from the pulley to the weight using the diameter of the circle calculated by the circle detection processing unit and the actual diameter of the pulley of the automatic tension adjustment device.

JP 2003-348723 A

JP 2017-100474 A

Conventional tension abnormality detection systems require pressure sensors, analysis and display devices, solar cells, and other devices to be installed in the automatic adjustment device along the line and connected by cables. As a result, conventional tension abnormality detection systems require the time and effort required to install pressure sensors and other devices in the automatic adjustment device, which increases costs, and also poses the problem of having to regularly inspect the pressure sensors and other devices.

In conventional weight position detection devices, each time the line sensor camera captures an image of the area between the pulley, which is the lower movable part of the automatic tension adjustment device, and the weight, it is necessary to calculate the distance from the pulley to the weight by converting the diameter of the circle calculated by the circle detection processing unit from the actual diameter of the pulley of the automatic tension adjustment device. For this reason, conventional weight position detection devices have the problem that the calculation process for calculating the distance from the pulley to the weight becomes complicated. In addition, conventional weight position detection devices have the problem that the imaging range of the line sensor camera is narrow, so that a line sensor camera mounted on the roof cannot capture an image of the lower movable part between the pulley of the automatic tension adjustment device and the weight.

The objective of this invention is to provide a train line tension diagnostic device and a tension diagnostic method that can easily diagnose the tension of the train line by using images captured by a tension adjustment device.

The present invention solves the above problems by the means described below.
In addition, although the present invention will be described with reference to corresponding reference numerals, the present invention is not limited to this embodiment.
The invention of claim 1 is a tension diagnosis device for electric wires that diagnoses the tension of a tension adjustment device (10A, 10B) that adjusts the tension of an electric wire (6) based on images (P _N ) taken by a camera (18) of a vehicle (2) while the vehicle is traveling, as shown in Figures 4, 5 and 13, and includes a change measurement unit (19f) that measures a rotation angle (θ _W ) of a pulley (13) or a tilt angle (θ _Y ) of a yoke (11) of the tension adjustment device based on the images taken by the camera, a theoretical value calculation unit (19r) that calculates a theoretical value of the rotation angle of the pulley or the tilt angle of the yoke based on the slackness (s) of the electric wire photographed by the camera, and a tension evaluation unit (19j) that evaluates the tension of the electric wire based on the measurement result of the change measurement unit and the calculation result of the theoretical value calculation unit.

The invention of claim 2 is a tension diagnosis device for electric wires that diagnoses the tension of a tension adjustment device (10A, 10B) that adjusts the tension of an electric wire (6) based on images (P _N ) taken by a camera (18) of a vehicle (2) while the vehicle is traveling, as shown in Figures 13 and 17, and includes a change measurement unit (19f) that measures an amount of expansion and contraction (S) of an inner tube (21) of a spring-type automatic tension adjuster based on the images taken by the camera, a theoretical value calculation unit (19r) that calculates a theoretical value of the amount of expansion and contraction of the inner tube based on the slackness (s) of the electric wire photographed by the camera, and a tension evaluation unit (19j) that evaluates the tension of the electric wire based on the measurement result of the change measurement unit and the calculation result of the theoretical value calculation unit.

The invention of claim 3 is a tension diagnosis method for electric train wires that diagnoses the tension of a tension adjustment device (10A, 10B) that adjusts the tension of the electric train wire (6) based on images (P _N ) taken by a camera (18) of a vehicle (2) while the vehicle is traveling, as shown in Figures 4, 5 and 14, and includes a change amount measurement step (S300) of measuring a rotation angle (θ _W ) of a pulley (13) or a tilt angle (θ _Y ) of a yoke (11) of the tension adjustment device based on the images taken by the camera device, a theoretical value calculation step (S410) of calculating a theoretical value of the rotation angle of the pulley or the tilt angle of the yoke based on the slackness (s) of the electric train wire photographed by the camera device, and a tension evaluation step (S500) of evaluating the tension of the electric train wire based on the measurement result in the change amount measurement step and the calculation result in the theoretical value calculation step.

The invention of claim 4 is a tension diagnosis method for electric train wires that diagnoses the tension of an electric train wire (6) based on images (P _N ) of a tension adjustment device (10A, 10B) that adjusts the tension of the electric train wire (6) captured by a camera (18) of a vehicle (2) while the vehicle is traveling, as shown in FIGS. 14 and 17 , and includes a change amount measurement step (S300) of measuring an amount of expansion and contraction (S) of an inner tube (21) of a spring-type automatic tension adjuster based on the images captured by the camera device, a theoretical value calculation step (S410) of calculating a theoretical value of the amount of expansion and contraction of the inner tube based on the slackness (s) of the electric train wire captured by the camera device , and a tension evaluation step (S500) of evaluating the tension of the electric train wire based on the measurement result of the change amount measurement step and the calculation result of the theoretical value calculation step.

According to this invention, the tension of the electric train line can be easily diagnosed by using images captured by the tension adjustment device.

1 is a conceptual diagram illustrating a train line tension diagnostic system according to a first embodiment of the present invention; 1 is a schematic diagram illustrating a tension adjusting device diagnosed by a train line tension diagnosis device according to a first embodiment of the present invention; 1 is a configuration diagram of a train line tension adjustment system according to a first embodiment of the present invention; FIG. 1 is a schematic diagram for explaining measurement of a change in the inclination angle of a yoke of a tension adjusting device by a change amount measuring unit of the electric rail tension diagnosis device according to the first embodiment of the present invention, in which (A) is a schematic diagram showing a change in the inclination angle of the yoke when the trolley wire becomes relatively longer, and (B) is a schematic diagram showing a change in the inclination angle of the yoke when the trolley wire becomes relatively shorter. 1A and 1B are schematic diagrams for explaining measurement of a change in the rotation angle of a pulley of a tension adjusting device by a change amount measuring unit of an overhead contact line tension diagnosis device according to a first embodiment of the present invention, in which (A) is a schematic diagram showing a change in the rotation angle of the pulley when the overhead contact line tension increases, and (B) is a schematic diagram showing a change in the rotation angle of the pulley when the overhead contact line tension decreases. FIG. 2 is a schematic diagram of a data structure of a change amount storage unit of the electric rail tension diagnosis device according to the first embodiment of the present invention. 1A and 1B are graphs for illustrating the evaluation operation of a tension evaluation unit of the electric rail tension diagnosis device according to the first embodiment of the present invention, in which (A) is a graph for illustrating the evaluation operation based on the amount of change in a yoke of a tension adjustment device, and (B) is a graph for illustrating the evaluation operation based on the amount of change in a pulley of the tension adjustment device. 4 is a flowchart for explaining a method for diagnosing tension of an electric rail according to a first embodiment of the present invention. FIG. 11 is a schematic diagram showing a configuration of a train line tension adjustment system according to a second embodiment of the present invention. 5A and 5B are schematic diagrams for explaining the measurement of the change in the inclination angle of the yoke of the tension adjusting device by the change amount measuring unit of the electric rail tension diagnosis device according to the second embodiment of the present invention, in which (A) is a schematic diagram showing the change in the inclination angle of the yoke when the trolley wire becomes relatively longer, and (B) is a schematic diagram showing the change in the inclination angle of the yoke when the trolley wire becomes relatively shorter. 10A and 10B are schematic diagrams for explaining measurement of a change in the rotation angle of a pulley of a tension adjusting device by a change amount measuring unit of an overhead contact line tension diagnosis device according to a second embodiment of the present invention, in which (A) is a schematic diagram showing a change in the rotation angle of the pulley when the overhead contact line tension increases, and (B) is a schematic diagram showing a change in the rotation angle of the pulley when the overhead contact line tension decreases. 10 is a flowchart for explaining a method for diagnosing tension of an electric rail according to a second embodiment of the present invention. FIG. 13 is a configuration diagram illustrating a train line tension diagnostic system according to a fourth embodiment of the present invention. 13 is a flowchart for explaining a method for diagnosing tension of an electric rail according to a third embodiment of the present invention. FIG. 13 is a conceptual diagram illustrating a train line tension diagnostic system according to a fourth embodiment of the present invention. FIG. 13 is a schematic diagram illustrating a tension adjusting device diagnosed by a train line tension diagnosis device according to a fourth embodiment of the present invention. 13A and 13B are schematic diagrams for explaining measurement of a change in the amount of expansion and contraction of the inner tube of a tension adjusting device by a change amount measuring unit of an electric rail tension diagnosis device according to a fourth embodiment of the present invention, in which (A) is a schematic diagram showing a change in the amount of expansion and contraction of the inner tube when the tension of the overhead wire increases, and (B) is a schematic diagram showing a change in the amount of expansion and contraction of the inner tube when the tension of the overhead wire decreases.

First Embodiment
Hereinafter, a first embodiment of the present invention will be described in detail with reference to the drawings.
The track 1 shown in FIG. 1 is a passage (track) on which the vehicle 2 runs. The track 1 includes a pair of rails that support and guide the wheels of the vehicle 2. The vehicle 2 is a moving body that moves along the track 1. The vehicle 2 is a railway vehicle such as an electric car, a diesel car, a passenger car, or a freight car that runs on the track 1, and is a train made up of a plurality or a single vehicle 2. The vehicle 2 is, for example, a commercial vehicle formed for the purpose of carrying out a passenger or freight transportation business, or an inspection vehicle or test vehicle such as an electric inspection vehicle, an overhead line test vehicle, or an electric track comprehensive test vehicle that has a function of inspecting the state of the electric railway equipment. The vehicle 2 shown in FIG. 1 runs in the direction A from a tension adjustment device 10A on the side closer to the start point of the track 1 to a tension adjustment device 10B on the side closer to the end point of the track 1. The vehicle 2 includes a bogie 3, a car body 4, a current collector 5, and the like. The bogie 3 is a device that supports the car body 4 and runs on the track 1. The bogie 3 is equipped with wheels that roll along the rails of the track 1. The car body 4 is a structure for carrying and transporting passengers or cargo. The car body 4 is equipped with a car body upper surface 4a. The car body upper surface 4a is an outer plate (roof plate) that constitutes the roof structure (roof structure) of the car body 4. On the car body upper surface 4a, roof equipment such as an air conditioner for air-conditioning the interior of the car is installed. The current collector 5 is a device for conducting electric power from the trolley wire 6a to the car 2. The current collector 5 is equipped with a contact strip 5a that slides against the trolley wire 6a.

The overhead line 6 is a train line (overhead train line) that is suspended above the track. The overhead line 6 is supported at support points P by support structures 7 at predetermined intervals so that the distance (span length) between support points P is a predetermined length. The span of the overhead line 6 is set to about 45 to 50 m, and both ends of the overhead line 6 are held down by tension adjustment devices 10A, 10B at regular sections (detaining sections) of up to about 800 to 1600 m. The overhead line 6 is a simple catenary-type overhead line, and includes a trolley wire 6a, a catenary wire 6b, and a hanger 6c. The catenary wire 6a is an electric wire on which the contact strip 5a of the current collector 5 slides. The catenary wire 6b is a wire that supports the trolley wire 6a. The catenary wire 6b supports the trolley wire 6a so that slack due to the weight of the trolley wire 6a is small. The hanger 6c is a member that suspends the trolley wire 6a from the catenary wire 6b. The hanger 6c keeps the height of the trolley wire constant.

The support structure 7 is a catenary support for supporting the catenary 6. The support structure 7 is a movable bracket or the like that supports the catenary 6 so that it can move freely in the length direction (track direction). The support structure 7 can rotate horizontally around the support point P so as to accommodate the movement of the catenary 6 due to temperature changes, and allows the catenary 6 to move in the length direction and can also adjust the movement slightly in the vertical direction. The support structures 8A and 8B are catenary supports that hold the ends of the catenary 6. The support structures 8A and 8B are dead-end columns whose base parts are fixed to the side of the track 1. The support structure 8A holds one end of the catenary 6 via a tension adjustment device 10A, and the support structure 8B holds the other end of the catenary 6 via a tension adjustment device 10B. The insulator 9 is a member that insulates and supports the catenary 6. The insulator 9 provides electrical insulation between the overhead line 6 and the tension adjustment devices 10A and 10B.

The tension adjusting devices 10A and 10B shown in FIG. 1 are devices that adjust the tension of the overhead line 6. The tension adjusting devices 10A and 10B function as automatic tension adjusting devices (tension balancers) that automatically adjust the tension of the overhead line 6 to keep constant the tension change of the trolley wires caused by expansion and contraction due to temperature changes of the trolley wires 6a and the catenary wires 6b or wear of the trolley wires 6a. The tension adjusting devices 10A and 10B shown in FIG. 1 and FIG. 2 are pulley-type tension balancers (Wheel Tension Balancers (WTB)) that keep constant the tension change of the overhead line 6 caused by temperature changes, etc., by using a counterweight. As shown in FIG. 1 and FIG. 2, the tension adjusting devices 10A and 10B include a yoke 11, a retaining material 12, a pulley (wheel) 13, a hanging material 14, a weight 15, a support part 16, etc. The tension adjustment devices 10A and 10B have the same structure, and the following description will focus on one of the tension adjustment devices, 10A. The same parts as those in the tension adjustment device 10A will be given the same reference numerals as the other tension adjustment device 10B, and detailed descriptions will be omitted.

The yoke 11 shown in Figs. 1 and 2 is a member that holds the trolley wire 6a and the catenary wire 6b together. The yoke 11 is, for example, a triangular or diamond-shaped steel plate. The yoke 11 constitutes the upper movable part of the tension adjustment device 10A, 10B. As shown in Fig. 2, the yoke 11 includes an attachment part 11a to which the trolley wire 6a is attached via the insulator 9, an attachment part 11b to which the catenary wire 6b is attached via the insulator 9, and an attachment part 11c to which the retention material 12 is attached at the balance point between the attachment parts 11a and 11b. The yoke 11 is rotatable about the attachment part 11c as a fulcrum when the linear expansion coefficients of the trolley wire 6a and the catenary wire 6b are different and therefore the amount of expansion and contraction due to temperature changes is different.

The retaining material 12 shown in Figures 1 and 2 is a member that connects the yoke 11 and the pulley 13. The retaining material 12 is, for example, a wire such as a deadening wire or a deadening chain. The retaining material 12 is pulled out from the mounting part 11c of the yoke 11 in the opposite direction to the trolley wire 6a and the messenger wire 6b. As shown in Figure 2, one end of the retaining material 12 is attached to the mounting part 11c of the yoke 11, and the other end is attached to the small pulley part 13a of the pulley 13.

The pulley 13 shown in Figs. 1 and 2 is a member that rotates in response to changes in the slack and tension of the overhead line 6. The pulley 13 rotates, for example, when the slack and tension of the overhead line 6 change due to a change in temperature. Here, the slack is the amount of deformation of the trolley wire 6a due to gravity. The slack is the difference between the height of the center of the straight line connecting the support points P shown in Fig. 1 and the height of the trolley wire 6a hanging down due to gravity, and is maximum at the center between the support points P, meaning the maximum value of this difference (maximum distance). The pulley 13 constitutes the upper movable part of the tension adjustment device 10A, 10B, similar to the yoke 11. As shown in Fig. 2, the pulley 13 includes a small pulley part 13a, a large pulley part 13b, a step part 13c, etc. The pulley 13 has a pulley ratio, which is the ratio of the diameter of the small pulley part 13a to the diameter of the large pulley part 13b, which is usually set to about 1:4.

The small pulley section 13a shown in FIG. 2 is a member around which the retaining material 12 is wound. The small pulley section 13a is a hub section (boss section) that corresponds to the central axis of the pulley 13, and the center of rotation of the small pulley section 13a coincides with the center of rotation of the pulley 13, and rotates together with the pulley 13. The large pulley section 13b is a member around which the hanging material 14 is wound. The large pulley section 13b is a rim section that corresponds to the outer periphery of the pulley 13, and has a larger outer diameter than the small pulley section 13a. The center of rotation of the large pulley section 13b coincides with the center of rotation of the pulley 13, and rotates together with the pulley 13. In order to prevent the overhead wire 6 from drifting, the outer periphery of the large pulley section 13b is formed in a spiral (spiral) shape so that the radius from the center of rotation of the large pulley section 13b changes depending on the rotation position. Here, drifting refers to the phenomenon in which the overhead wire 6 moves in the length direction due to the sliding of the slider 5a or the gradient of the track 1. The step portion 13c is an irregularly shaped portion formed on the outer periphery of the large pulley portion 13b. The step portion 13c is formed between a large diameter portion having a large outer diameter so that the pulley ratio is large, and a small diameter portion having a small outer diameter so that the pulley ratio is small, and constitutes the characteristic shape of the appearance of the pulley 13.

The hanging member 14 shown in Figures 1 and 2 is a member that connects the pulley 13 and the weight 15. The hanging member 14 is, for example, a line such as a hanging wire or a hanging chain. One end of the hanging member 14 is attached to the large pulley portion 13b of the pulley 13, and the other end is attached to the weight 15.

The weight 15 is a member that applies tension to the overhead line 6. The weight 15 is, for example, a weight made by stacking multiple concrete or iron plates. The weight 15 is guided so that it can move up and down freely by a guide member attached to the support structure 8A. Unlike the yoke 11 and the pulley 13, the weight 15 constitutes the lower movable part of the tension adjustment device 10A, 10B. The support part 16 is a part that supports the pulley 13 to the support structures 8A, 8B. The support part 16 is a pulley bracket that fixes the pulley 13 to the support structures 8A, 8B while supporting the pulley 13 so that it can rotate freely.

Next, the operation of the tension adjusting device diagnosed by the electric rail tension diagnosis device according to the first embodiment of the present invention will be described.
Usually, the overhead wire 6 is installed with the standard tension at the reference temperature of 15°C. However, the contact wire 6a and the messenger wire 6b expand and contract due to temperature changes, and the contact wire 6a expands due to elastic elongation caused by wear. In winter, when the tension of the messenger wire 6b is strong, the contact wire 6a is pulled up. On the other hand, in summer, when the tension of the messenger wire 6b is weak, the contact wire 6a hangs down, and when the tension of only the contact wire 6a decreases, slack occurs with the hanger 6c as the support point. Therefore, when the vehicle 2 runs, it causes the contact wire 6a to separate from the contact strip 5a. As shown in Figure 2, the weight 15 applies a constant load to the overhead wire 6 through the yoke 11 and the pulley 13. Therefore, when the slack and tension of the overhead wire 6 change due to temperature changes and the overhead wire 6 expands and contracts, the pulley 13 rotates in response to the expansion and contraction of the overhead wire 6, and the weight 15 moves up and down. The outer periphery of the large pulley section 13b is formed in a spiral shape, and the radius from the center of rotation changes depending on the rotation position. Therefore, when the overhead line 6 slackens and the small pulley section 13a rotates to wind up the retaining material 12, the diameter of the contact part between the hanging material 14 and the large pulley section 13b gradually decreases, and the tension of the overhead line 6 gradually increases. On the other hand, when the overhead line 6 contracts and the small pulley section 13a rotates to pay out the retaining material 12, the diameter of the contact part between the hanging material 14 and the large pulley section 13b gradually increases, and the tension of the overhead line 6 gradually decreases. As a result, the tension adjusting devices 10A and 10B correct the slack of the overhead line 6 so that the trolley wire 6a becomes horizontal, and the tension of the overhead line 6 is maintained at a constant standard tension.

The tension diagnostic system 17 shown in Figures 1 and 3 is a system that diagnoses the tension of the overhead wire 6. The tension diagnostic system 17 is equipped with a photographing device 18 and a tension diagnostic device 19. The tension diagnostic system 17 photographs the tension adjustment devices 10A, 10B from the photographing device 18 of the vehicle 2 traveling along the track 1, and diagnoses the tension of the overhead wire 6 and the condition of the overhead wire 6 using the tension diagnostic device 19 based on the images photographed by the photographing device 18.

The photographing device 18 is a device that photographs the tension adjustment devices 10A and 10B. As shown in FIG. 1, the photographing device 18 is mounted on the upper surface 4a of the vehicle 2, and while moving with the vehicle 2, it continuously photographs the overhead line 6 and the overhead line facilities such as the tension adjustment devices 10A and 10B. The photographing device 18 photographs the vehicle 2 from above to both sides so that the upper movable parts such as the yoke 11 and the pulley 13 shown in FIG. 1 and FIG. 2 are included in the photographing area. The photographing device 18 can use a contactless overhead line measuring device that continuously measures the state of the overhead line 6 from the vehicle 2 in a non-contact manner by combining, for example, stereo measurement (triangulation) using two line sensor cameras and laser distance measurement. As shown in FIG. 3, the photographing device 18 includes a photographing optical system 18a, an imaging unit 18b, a signal processing unit 18c, a photographed image storage unit 18d, a transmission unit 18e, a control unit 18f, and the like.

The photographing optical system 18a shown in FIG. 3 is a group of lenses that form a subject image on the imaging unit 18b. The photographing optical system 18a is, for example, a fisheye lens that has a deep depth of field and can distort the subject to capture a wide range, and is used to capture a wider range than an ultra-wide-angle lens. The photographing optical system 18a focuses the light beam that passes through this photographing optical system 18a and forms an image on the imaging plane of the imaging unit 18b.

The imaging unit 18b is a means for capturing an image of a subject transmitted through the imaging optical system 18a. The imaging unit 18b is a photoelectric conversion element (imaging element) that converts the image of a subject transmitted through the imaging optical system 18a into image information, and converts the captured image from the imaging surface on which the image of the subject is formed into an electrical signal (image information) and outputs it to the signal processing unit 18c. The imaging unit 18b is, for example, a line sensor camera (line camera) that outputs the image of a subject (subject light) formed on the element surface as captured image data. The imaging unit 18b is equipped with a solid-state imaging element such as a CCD (Charge Coupled Device) imaging sensor element or a CMOS (Complementary Metal Oxide Semiconductor) imaging element that converts light into an electrical signal and outputs it. The imaging unit 18b has a scanning line direction set perpendicular to the traveling direction of the vehicle 2.

The signal processing unit 18c is a means for processing the electrical signal output by the imaging unit 18b. The signal processing unit 18c is an electrical circuit that converts the analog signal output by the imaging unit 18b into a digital signal (A/D conversion) and performs image processing on this digital signal before outputting it to the control unit 18f. The signal processing unit 18c, for example, corrects uneven illuminance and sensitivity, corrects image density and color, and removes noise components from the output signal of the imaging unit 18b.

The captured image storage unit 18d is a means for storing various data related to the image capture device 18. The captured image storage unit 18d is a storage device that stores the captured images captured by the image capture device 18 in chronological order as captured image data. The captured image storage unit 18d stores the traveling position of the vehicle 2 at the time the captured image was captured as traveling position data in association with the captured image. Here, the traveling position data is, for example, information related to the distance traveled by the vehicle 2 (traveling distance) calculated from the starting point of the track 1 by accumulating a pulse signal (distance pulse signal) output by a tachograph generator according to the number of rotations of the wheels of the vehicle 2.

The transmission unit 18e is a means for transmitting various data stored in the captured image storage unit 18d to the tension diagnosis device 19. The transmission unit 18e is, for example, a communication device that transmits data related to the captured images and the running position stored in the captured image storage unit 18d to the tension diagnosis device 19 wirelessly or via a wired connection.

The control unit 18f is a means (central processing unit (CPU)) that controls various operations related to the imaging device 18. For example, the control unit 18f instructs the captured image storage unit 18d to store the captured image data output by the imaging unit 18b, reads out various data stored in the captured image storage unit 18d and outputs it to the transmission unit 18e, and causes the transmission unit 18e to transmit various data stored in the captured image storage unit 18d. The signal processing unit 18c, the captured image storage unit 18d, and the transmission unit 18e are connected to the control unit 18f so that they can communicate with each other.

1 and 3, the tension diagnostic device 19 is a device that diagnoses the tension of the overhead wire 6 based on images of the tension adjustment devices 10A, 10B captured by the imaging device 18 of the vehicle 2 while the device is traveling. The tension diagnostic device 19 measures the amount of change in the yoke 11 or the pulley 13 based on the images of the tension adjustment devices 10A, 10B, and diagnoses the tension of the overhead wire 6 and the state of the overhead wire 6. As shown in FIG. 3, the tension diagnostic device 19 includes a receiving unit 19a, an image storage unit 19b, an image correction unit 19c, a template image storage unit 19d, a search processing unit 19e, a change amount measurement unit 19f, a change amount storage unit 19g, a plot diagram generation unit 19h, a plot diagram storage unit 19i, a tension evaluation unit 19j, an evaluation result storage unit 19k, a tension diagnosis program storage unit 19m, a display unit 19n, a control unit 19p, and the like. The tension diagnostic device 19 is configured, for example, by a personal computer, and executes a predetermined process according to a tension diagnostic program.

The receiving unit 19a shown in FIG. 3 is a means for receiving various data stored in the captured image storage unit 18d of the image capturing device 18 from the image capturing device 18. The receiving unit 19a is, for example, a communication device that receives data related to the captured images and the traveling position stored in the captured image storage unit 18d from the image capturing device 18 wirelessly or via a wired connection. The receiving unit 19a outputs the captured image data and the traveling position data to the control unit 19p.

The captured image storage unit 19b is a means for storing the captured images taken by the photographing device 18. The captured image storage unit 19b is a storage device that stores the captured images of the tension adjustment devices 10A and 10B in chronological order as captured image data. The captured image storage unit 19b stores the temperature at the time of capturing the captured image as temperature data in association with the captured image and the traveling position. Here, the temperature data is information on the temperature measured by a temperature measuring device at an observation point near the overhead line 6, or the temperature of the overhead line 6 measured by a temperature measuring device from the vehicle 2 while traveling. For example, the temperature information at the time of capturing the captured image at an observation point around the overhead line 6 provided by the Japan Meteorological Agency can be used as the temperature data. When the captured image correction unit 19c corrects the captured image, the captured image storage unit 19b stores the corrected captured image as captured image data. When the search processing unit 19e identifies a search target from the captured image, the captured image storage unit 19b stores the searched captured image as captured image data.

The captured image correction unit 19c is a means for correcting the captured image. The captured image correction unit 19c corrects distortion of the captured image caused by the fisheye lens. The captured image correction unit 19c corrects the captured image, for example, using image processing software, and outputs the corrected captured image to the control unit 19p as captured image data.

The template image storage unit 19d is a means for storing a template image for detecting a search target from a captured image. The template image storage unit 19d is a storage device that stores images of the yoke 11 and pulley 13 as template image data (partial image data) for each type when the shapes and structures (types) of the tension adjustment devices 10A, 10B differ depending on the manufacturer. The template image storage unit 19d stores, for example, a template image created from a design drawing of the actual yoke 11 and pulley 13. The template image storage unit 19d stores in advance template images of the yoke 11 and pulley 13 for each type of tension adjustment device 10A, 10B.

The search processing unit 19e is a means for searching the captured image for a location that is most similar to the template image. As shown in Figures 4 and 5, the search processing unit 19e identifies an area that matches the template image from within the search area of the captured image. The search processing unit 19e performs template matching processing, which is processing for searching the captured image data for a location that is most similar to a portion of the template image stored in the template image storage unit 19d. The search processing unit 19e searches the captured image for the yoke 11 and pulley 13, and outputs the captured image after the search to the control unit 19p as captured image data.

The change amount measuring unit 19f shown in Fig. 3 is a means for measuring the amount of change in the yoke 11 and the pulley 13 of the tension adjusting devices 10A, 10B based on the captured images taken by the imaging device 18. As shown in Figs. 4 and 5, the change amount measuring unit 19f calculates the inclination angle _θY of the yoke 11 and the rotation angle _θW of the pulley 13 as the amount of change based on the captured images searched by the search processing unit 19e. When the tension adjusting devices 10A, 10B are pulley-type automatic tension adjusting devices, the change amount measuring unit 19f measures the inclination angle _θY of the yoke 11 and the rotation angle _θW of the pulley 13 of the pulley-type automatic tension adjusting device.

As shown in Fig. 4(A), when the yoke 11 rotates counterclockwise around the mounting portion 11c as the center of rotation, the change amount measuring unit 19f measures the inclination angle θ _Y of the yoke 11 with reference to the template image P ₀ and the photographed image P _N. On the other hand, as shown in Fig. 4(B), when the yoke 11 rotates clockwise around the mounting portion 11c as the center of rotation, the change amount measuring unit 19f measures the inclination angle θ _Y of the yoke 11 with reference to the template image P ₀ and the photographed image P _N. As shown in Fig. 5(A), when the tension of the overhead wire 6 increases and the pulley 13 rotates counterclockwise around the center as the center of rotation, the change amount measuring unit 19f measures the rotation angle θ _W of the pulley 13 with reference to the template image P ₀ and the photographed image P _N. On the other hand, as shown in FIG. 5(B), when the tension of the overhead wire 6 decreases and the pulley 13 rotates clockwise around the center, the change amount measuring unit 19f measures the rotation angle θ _W of the pulley 13 by referring to the template image P ₀ and the captured image P _N.

For example, as shown in Fig. 2, the change amount measuring unit 19f measures the rotation angle θW of the pulley 13 in the case of the pulley 13 on the tension adjusting device 10A side, with the point of the pulley ratio 4 of this pulley 13 as the reference (origin) _L0 of the rotation angle. For example, as shown in Fig. 4A, the change amount measuring unit 19f measures the inclination angle _θY of the yoke 11 by taking the case where the yoke 11 inclines toward the inside of the drum (counterclockwise in the figure) as the negative side, and by taking the case where the yoke 11 inclines toward the outside of the drum (clockwise in the figure) as the positive side as shown in Fig. 4B. For example, as shown in Fig. 5A, the change amount measuring unit 19f measures the rotation angle _θW of the pulley 13 by taking the direction in which the pulley 13 rotates toward the side where the tension of the overhead wire 6 increases (toward the inside of the drum (counterclockwise in the figure)) as the negative side, and by taking the direction in which the pulley 13 rotates toward the side where the tension decreases (toward the outside of the drum (clockwise in the figure)) as the positive side as shown in Fig. _5B . For example, the change amount measuring unit 19f assumes that the imaging pitch of the imaging unit 18b and the dimensions of the yoke 11 and pulley 13 are known, and converts the inclination angle θY of the yoke 11 and the rotation angle _θW of the pulley ₁₃ into actual angles from the inclination of the yoke 11 in the captured image and the rotation angle of the pulley 13. The change amount measuring unit 19f outputs the measured inclination angle _θY of the yoke 11 and the rotation angle _θW of the pulley 13 to the control unit 19p as change amount data.

The change amount storage unit 19g shown in Fig. 3 is a means for storing the change amount of the yoke 11 and the pulley 13 of the tension adjusting devices 10A and 10B. The change amount storage unit 19g is a storage device that stores the change amount of the yoke ₁₁ and the pulley 13 in chronological order as change amount data in association with the air temperature at the time of taking the photographed image. As shown in Fig. 6, the change amount storage unit 19g stores the change amount for each drum ID1, ..., ID _M. Here, the drums _ID1 , ..., ID _M are a series of electric wires between the tension adjusting devices 10A and 10B (within the deadhead section) shown in Fig. 1, and each drum is assigned a management number for maintenance. The drums _ID1 , ..., ID _M are identified based on the running position data stored by the photographed image storage unit 19b together with the photographed image data. The change amount memory unit 19g stores, for example, as shown in Figure 6, the inclination angles _θYA1 , ..., _θYAN of the yoke 11 on the tension adjusting device 10A side, the rotation angles _θWA1 , ..., _θWAN of the pulley 13 on the tension adjusting device 10A side, the inclination angles _θYB1 , ..., _θYBN of the yoke 11 on the tension adjusting device 10B side, the rotation angles _θWB1 , ..., _θWWN of the pulley 13 on the tension adjusting device 10B side, and the air temperatures _T1 , ..., _TN at the time of shooting in the order of the shooting date and time _D1 , ..., _DN for each drum _ID1 , ..., _IDM .

The plot diagram generating unit 19h shown in Fig. 3 is a means for generating a plot diagram plotting the relationship between the amount of change in the yoke 11 and pulley 13 of the tension adjusting device 10A, 10B and the air temperature at the time of taking the photographed image. The plot diagram generating unit 19h plots the inclination angles θ _YA1 , ..., θ _YAN , θ _YB1 , ..., θ _YBN of the yoke 11 and the rotation angles θ _WA1 , ..., θ _WAN , θ _WB1 , ..., θ _WWN of the pulley 13 shown in Fig. 6 in correspondence with the air temperatures T ₁ ..., _TN on a graph, and generates a plot diagram like a scatter diagram or a distribution diagram as shown in Fig. 7. The plot diagram generating unit 19h generates a graph showing the relationship between the inclination angle θ _Y of the yoke 11 and the air temperature T as variables as shown in Fig. 7(A), and generates a graph showing the relationship between the rotation angle θ _W of the pulley 13 and the air temperature T as variables as shown in Fig. 7(B). Here, the vertical axis shown in Fig. 7(A) is the inclination angle θ _Y of the yoke 11, the vertical axis shown in Fig. 7(B) is the rotation angle θ _W of the pulley 13, and the horizontal axis shown in Fig. 7(A) and (B) is the air temperature T. The plot chart generating unit 19h outputs the generated plot chart to the control unit 19p as plot chart data.

The plot diagram storage unit 19i shown in Fig. 3 is a means for storing the plot diagram generated by the plot diagram generating unit 19h. The plot diagram storage unit 19i is a storage device that stores plot diagrams such as those shown in Fig. 7 as plot diagram data for each drum _ID1 , ..., _IDM . The plot diagram storage unit 19i updates and stores the plot diagram every time the change amount measuring unit 19f measures the change amount of the yoke 11 and the pulley 13 of the tension adjusting devices 10A and 10B.

The tension evaluation unit 19j shown in Fig. 3 is a means for evaluating the tension of the overhead wire 6 based on the measurement result of the change amount measurement unit 19f. The tension evaluation unit 19j evaluates the tension of the overhead wire 6 based on the amount of change of the yoke 11 and the pulley 13 of the tension adjustment devices 10A, 10B and the air temperature at the time of taking the photographed image. As shown in Fig. 7, the tension evaluation unit 19j evaluates the tension of the overhead wire 6 based on whether or not a plot exists within a predetermined range Th of the plot diagram. When the plot of the plot diagram exists within the predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead wire 6 is normal, and when the plot of the plot diagram exists outside the predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead wire 6 is abnormal. Here, the predetermined range Th is a threshold value for judging whether the tension of the overhead wire 6 is appropriate or not, and is _a range that is normally allowed for the inclination angle θ _Y of the yoke 11 and the rotation angle θ _W of _the pulley 13 based on the relationship between these angles and the air temperature T.

The tension evaluation unit 19j also evaluates the _state of the overhead wire 6, such as whether the tension of the overhead wire 6 is lower than a predetermined value, whether it is greater than a predetermined value, or whether it is a predetermined value but uneven, based on the inclination angle _θY of the yoke 11 of the tension adjustment devices 10A, 10B and the rotation angle _θW of the pulley 13. The tension evaluation unit 19j determines that the state of the overhead wire 6 is abnormal when there is a difference in the magnitude of the inclination angle _θY of both yokes 11, such as when the inclination angle _θY of one yoke 11 of the tension adjustment devices 10A, 10B shown in Fig. 1 is large and the inclination angle θY of the other yoke 11 is small, or when only one yoke 11 is rotating. The tension evaluation unit 19j determines that the state of the overhead wire 6 is abnormal when there is a difference in magnitude between the rotation angles θ _W of the pulleys 13 of one of the tension adjustment devices 10A, 10B shown in Fig. 1 such that the rotation angle θ _W of the pulley 13 is large and the rotation angle θ _W of the other pulley 13 is small, or when only one of the pulleys 13 is rotating. The tension evaluation unit 19j determines that the state of the overhead wire 6 is abnormal when the yoke 11 is not inclined or the pulley 13 is not rotating despite a large change in air temperature. The tension evaluation unit 19j outputs the evaluation results of the tension of the overhead wire 6 and the state of the overhead wire 6 to the control unit 19p as evaluation result data.

The evaluation result storage unit 19k is a means for storing the evaluation results of the tension evaluation unit 19j. The evaluation result storage unit 19k is a storage device that stores the evaluation results of the tension of the overhead wire 6 in chronological order as tension diagnosis results for each drum _ID1 , ..., _IDM shown in Fig. 6. The evaluation result storage unit 19k updates and stores the evaluation result every time the tension evaluation unit 19j evaluates the tension of the overhead wire 6.

The tension diagnostic program memory unit 19m is a means for storing a tension diagnostic program for diagnosing the tension of the overhead wire 6 based on images of the tension adjustment devices 10A, 10B captured by the imaging device 18 of the vehicle 2 while the vehicle 2 is traveling. The tension diagnostic program memory unit 19m is a storage device that stores a tension diagnostic program read from an information recording medium or a tension diagnostic program downloaded via an electric communication line.

The display unit 19n is a means for displaying various information related to the tension diagnosis device 19. The display unit 19n is a display device that displays various data on a screen. The display unit 19n displays, for example, the captured image after the search as shown in Figs. 4 and 5, the measurement results of the change amount measurement unit 19f as shown in Fig. 6, a plot diagram as shown in Fig. 7, the evaluation results of the tension evaluation unit 19j, etc.

The control unit 19p is a central processing unit (CPU) that controls various operations related to the tension diagnosis device 19. The control unit 19p reads out a tension diagnosis program from the tension diagnosis program memory unit 19m and executes tension diagnosis processing according to this tension diagnosis program. The control unit 19p, for example, outputs the photographed image data received from the receiving unit 19a to the photographed image storage unit 19b, commands the photographed image storage unit 19b to store the photographed image data, reads out the photographed image data from the photographed image storage unit 19b and outputs it to the photographed image correction unit 19c, commands the photographed image correction unit 19c to correct the photographed image, outputs the photographed image data corrected by the photographed image correction unit 19c to the photographed image storage unit 19b, commands the photographed image storage unit 19b to store the corrected photographed image data, reads out template image data from the template image storage unit 19d and outputs it to the search processing unit 19e and the change amount measurement unit 19f, commands the search processing unit 19e to search for a template image from the photographed image, outputs the photographed image data searched by the search processing unit 19e to the photographed image storage unit 19b, commands the photographed image storage unit 19b to store the photographed image data after the search, reads out the photographed image data after the search from the photographed image storage unit 19b and measures the change amount. The control unit 19n outputs the plot diagram data output by the plot diagram generating unit 19h to the plot diagram memory unit 19i, instructs the plot diagram memory unit 19i to store the plot diagram data, reads out the plot diagram data from the plot diagram memory unit 19i and outputs it to the tension evaluation unit 19j, instructs the tension evaluation unit 19j to evaluate the tension of the overhead wire 6, outputs the evaluation result data output by the tension evaluation unit 19j to the evaluation result memory unit 19k, instructs the evaluation result memory unit 19k to store the evaluation result data, and instructs the display unit 19n to display various data. The control unit 19p is connected to a receiving unit 19a, a captured image storage unit 19b, a captured image correction unit 19c, a template image storage unit 19d, a search processing unit 19e, a change amount measurement unit 19f, a change amount storage unit 19g, a plot diagram generation unit 19h, a plot diagram storage unit 19i, a tension evaluation unit 19j, an evaluation result storage unit 19k, a tension diagnosis program storage unit 19m, and a display unit 19n so that they can communicate with each other.

Next, a method for diagnosing tension of an electric rail according to a first embodiment of the present invention will be described.
The following description will focus on the operation of the control unit 19p.
8, the control unit 19p reads the tension diagnostic program from the tension diagnostic program storage unit 19m, and as a result, the control unit 19p starts a series of tension diagnostic processes.

In S200, the control unit 19p commands the search processing unit 19e to perform a search process for the yoke 11 and pulley 13 of the tension adjusting device 10A, 10B. The control unit 19p reads out the photographed image data from the photographed image storage unit 19b and outputs the photographed image data to the search processing unit 19e, and also reads out the template image data from the template image storage unit 19d and outputs the template image data to the search processing unit 19e. As a result, in order to detect the yoke 11 and pulley 13, which are the search targets, as shown in Figures 4 and 5, from the photographed image, the search processing unit 19e searches for an area that matches the template image _P0 shown in Figures 4 and 5 from the photographed image. When the search processing unit 19e specifies the photographed image P _N after the search for the yoke 11 and pulley 13 as shown in Figures 4 and 5, the search processing unit 19e outputs the photographed image data after the search to the control unit 19p, and the photographed image data after the search is stored in the photographed image storage unit 19b.

In S300, the control unit 19p commands the change amount measuring unit 19f to measure the change amount of the yoke 11 and the pulley 13 of the tension adjusting device 10A, 10B. The control unit 19p reads out the photographed image data after the search from the photographed image storage unit 19b and outputs the photographed image data to the change amount measuring unit 19f, and also reads out the template image data from the template image storage unit 19d and outputs the template image data to the change amount measuring unit 19f. As a result, as shown in FIG. 4, the change amount measuring unit 19f refers to the template image P ₀ of the yoke 11 and the photographed image P _N of the yoke 11 after the search, and measures the inclination angle θ _Y of the yoke 11. Similarly, as shown in FIG. 5, the change amount measuring unit 19f refers to the template image P ₀ of the pulley 13 and the photographed image P _N of the pulley 13 after the search, and measures the rotation angle θ _W of the pulley 13. When the change amount measuring section 19f outputs the change amount data after measurement to the control section 19p, this change amount data after measurement is stored in the change amount storage section 19g as shown in FIG.

In S400, the control unit 19p commands the plot chart generating unit 19h to create a plot chart. The control unit 19p reads out the change amount data from the change amount storage unit 19g, and outputs this change amount data to the plot chart generating unit 19h. As a result, the plot chart generating unit 19h generates a plot chart that shows the relationship between the inclination angle θ _Y of the yoke 11 and the rotation angle θ _W of the pulley 13, and the air temperature T, as shown in Figure 7. When the plot chart generating unit 19h outputs the plot chart data to the control unit 19p, this plot chart data is stored in the plot chart storage unit 19i.

In S500, the control unit 19p commands the tension evaluation unit 19j to evaluate the tension of the overhead wire 6. The control unit 19p reads out plot diagram data from the plot diagram storage unit 19i, and outputs this plot diagram data to the tension evaluation unit 19j. As a result, as shown in FIG. 7, the tension evaluation unit 19j evaluates whether the plot of the plot diagram is within a predetermined range Th. When the plot of the plot diagram is within the predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead wire 6 is normal, and when the plot of the plot diagram is outside the predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead wire 6 is abnormal.

An abnormality in the tension ratio between the contact wire 6a and the catenary wire 6b can be evaluated from the inclination angle θ _Y of the yoke 11 shown in FIG. 4. For example, when the yoke 11 is inclined significantly to the positive side, the elongation of the contact wire 6a is greater than that of the catenary wire 6b. In this case, it is possible that the tension of the catenary wire 6b decreases, causing the elongation of the catenary wire 6b to decrease, and/or the tension of the catenary wire 6a increases, causing the elongation of the catenary wire 6a to increase. When the inclination angle θ _Y of the yoke 11 is inclined to the negative side more than a predetermined value as shown in FIG. 4(A), or when the inclination angle θ _Y of the yoke 11 is inclined to the positive side more than a predetermined value as shown in FIG. 4(B), the tension evaluation unit 19j evaluates that the tension ratio between the contact wire 6a and the catenary wire 6b of the catenary wire 6 is abnormal. When the rotation angle θ _W of the pulley 13 is rotated to the negative side more than a predetermined value as shown in FIG. 5(A), the tension evaluation unit 19j evaluates that the tension of the catenary wire 6 is excessive. On the other hand, as shown in FIG. 5B, when the rotation angle θ _W of the pulley 13 rotates to the positive side by a value greater than the predetermined value, the tension evaluation unit 19j evaluates that the tension in the overhead wire 6 is insufficient.

When the inclination angles θ _Y of the yokes 11 of both tension adjusters 10A and 10B shown in Fig. 1 are inclined in the same direction at approximately the same degree, or when the rotation angles θ _W of the pulleys 13 of both tension adjusters 10A and 10B are rotating in the same direction at approximately the same degree, the tension evaluation unit 19j evaluates that a drift is occurring in the overhead wire 6. When the inclination angle θ _Y of one yoke 11 of the tension adjusters 10A and 10B shown in Fig. 1 is different from the inclination angle θ _Y of the other yoke 11 and both are inclined in the same direction, or when the rotation angle θ _W of one pulley 13 of the tension adjusters 10A and 10B is different from the rotation angle θ _W of the other pulley 13 and both pulleys 13 rotate in the same direction, the tension evaluation unit 19j evaluates that the loads of the tension adjusters 10A and 10B shown in Fig. 1 are uneven and a drift is occurring in the overhead wire 6. When the tension evaluation unit 19j outputs the evaluation result data to the control unit 19p, the evaluation result data is stored in the evaluation result storage unit 19k.

In S600, the control unit 19p commands the display unit 19n to display. As a result, the display unit 19n displays the evaluation results of the tension of the overhead line 6, etc., on the screen.

The electric rail tension diagnostic device and tension diagnostic method according to the first embodiment of the present invention have the following effects.
(1) In this first embodiment, the change amount measuring unit 19f measures the amount of change in the yoke 11 and the pulley 13 of the tension adjusting devices 10A, 10B based on the images captured by the photographing device 18, and the tension evaluating unit 19j evaluates the tension of the overhead wire 6 based on the measurement result of the change amount measuring unit 19f. Therefore, the rotation amount and the movement amount of the yoke 11 and the pulley 13 can be measured using the photographed images acquired from the photographing device 18, and abnormalities in the overhead wire 6 can be easily detected. As a result, the tension of the overhead wire 6 can be periodically diagnosed by a test vehicle, and the tension of the overhead wire 6 can be frequently diagnosed by a commercial vehicle, thereby improving the reliability of the overhead wire facilities.

(2) In the first embodiment, the tension evaluation unit 19j evaluates the tension of the overhead wire 6 based on the amount of change in the yoke 11 and the pulley 13 of the tension adjustment devices 10A, 10B and the air temperature when the captured image was taken. Therefore, the inclination angle θ _Y of the yoke 11 and the rotation angle θ _W of the pulley 13 are detected from the captured image of the tension adjustment devices 10A, 10B, and abnormalities in the overhead wire 6 can be easily detected from the behavior of the yoke 11 and the pulley 13 and the air temperature. As a result, abnormalities that lead to deterioration of current collection performance, such as, for example, one-sided drift of the overhead wire 6, tension reduction, and excessive tension, can be detected early.

(3) In the first embodiment, the plot diagram generating unit 19h generates a plot diagram plotting the relationship between the amount of change in the yoke 11 and the pulley 13 of the tension adjusting devices 10A, 10B and the air temperature at the time of taking the photographed image, and the tension evaluating unit 19j evaluates the tension of the overhead wire 6 based on whether the plot is within a predetermined range Th of the plot diagram. For this reason, photographed images of the tension adjusting devices 10A, 10B are periodically acquired, and the relationship between the inclination angle θ _Y of the yoke 11 and the rotation angle θ _W of the pulley 13 and the air temperature T is plotted on a graph, and a warning can be issued if the plot is significantly out of the range in which it normally exists.

(4) In the first embodiment, when the tension adjusting devices 10A, 10B are pulley-type automatic tension adjusting devices, the change amount measuring unit 19f measures the rotation angle θ _W of the pulley 13 of the pulley-type automatic tension adjusting device and the inclination angle θ _Y of the yoke 11 of the pulley-type automatic tension adjusting device. Therefore, for example, the yoke 11 and the pulley 13, which are the upper movable parts of the tension adjusting devices 10A, 10B and which could not be photographed by the conventional weight position detection device, can be reliably photographed from the vehicle 2 running on the track 1 by the photographing device 18 mounted on the body upper surface 4a of the vehicle 2. As a result, the state of the tension adjusting devices 10A, 10B can be monitored from the images of the yoke 11 and the pulley 13 acquired by the running vehicle 2, the inclination angle θ _Y and the rotation angle θ _W of the pulley 13 can be automatically measured, and the presence or absence of an abnormality in the tension of the overhead wire 6 can be easily diagnosed. In addition, visual inspection by foot patrol of the tension adjusting devices 10A, 10B is no longer necessary, and the efficiency of the inspection work can be significantly improved.

Second Embodiment
In the following, the same parts as those shown in FIGS. 1 to 7 are denoted by the same reference numerals and detailed description thereof will be omitted.
Unlike the tension diagnostic device 19 shown in Fig. 3, the tension diagnostic device 19 shown in Fig. 9 includes a calculation condition storage unit 19q, a theoretical value calculation unit 19r, a theoretical value storage unit 19s, etc. The change amount measurement unit 19f measures the amount of change in the yoke 11 and the pulley 13 of the tension adjusting devices 10A, 10B based on the current captured image and the previous captured image captured by the imaging device 18. As shown in Figs. 10 and 11, the change amount measurement unit 19f calculates the inclination angle θ _Y of the yoke 11 and the rotation angle θ _W of the pulley 13 as the amount of change based on the current captured image P _N and the previous captured image P _N-1 searched by the search processing unit 19e.

As shown in Fig. 10(A), when the yoke 11 rotates counterclockwise around the mounting portion 11c, the change amount measuring unit 19f measures the tilt angle θ _Y of the yoke 11 with reference to the previously captured image P _N-1 and the currently captured image P _N. On the other hand, as shown in Fig. 10(B), when the yoke 11 rotates clockwise around the mounting portion 11c, the change amount measuring unit 19f measures the tilt angle θ _Y of the yoke 11 with reference to the previously captured image P _N-1 and the currently captured image P _N. As shown in Fig _{. 11} (A), when the tension of the overhead wire 6 increases and the pulley 13 rotates counterclockwise around the center, the change amount measuring unit 19f measures the rotation angle θ _W of the pulley 13 with reference to the previously captured image P N-1 and the currently captured image P _N. On the other hand, as shown in FIG. 11(B), when the tension of the overhead wire 6 decreases and the pulley 13 rotates clockwise around the center, the change amount measuring unit 19f measures the rotation angle θ _W of the pulley 13 by referring to the previous captured image P _N-1 and the current captured image P _N.

The tension evaluation unit 19j evaluates the tension of the overhead line 6 based on the measurement result of the change amount measurement unit 19f and the calculation result of the theoretical value calculation unit 19r. The tension evaluation unit 19j compares the measured value of the change amount of the yoke 11 and the pulley 13 measured by the change amount measurement unit 19f with the theoretical value of the change amount of the yoke 11 and the pulley 13 calculated by the theoretical value calculation unit 19r to evaluate whether the tension of the overhead line 6 is normal. For example, when the difference between the measured value of the change amount of the yoke 11 and the pulley 13 and the theoretical value of the change amount of the yoke 11 and the pulley 13 is within a predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead line 6 is normal. On the other hand, when the difference between the measured value of the change amount of the yoke 11 and the pulley 13 and the theoretical value of the change amount of the yoke 11 and the pulley 13 is outside the predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead line 6 is abnormal.

The control unit 19p, for example, reads out calculation condition data from the calculation condition storage unit 19q and outputs it to the theoretical value calculation unit 19r, instructs the theoretical value calculation unit 19r to calculate the theoretical values of the changes in the yoke 11 and pulley 13, instructs the theoretical value storage unit 19s to store the theoretical value data after calculation, and reads out the theoretical value data from the theoretical value storage unit 19s and outputs it to the tension evaluation unit 19j. The calculation condition storage unit 19q, the theoretical value calculation unit 19r, and the theoretical value storage unit 19s are connected to the control unit 19p so that they can communicate with each other.

The calculation condition storage unit 19q is a means for storing conditions necessary for calculating theoretical values of the amount of change of the yoke 11 and the pulley 13 of the tension adjusting devices 10A and 10B. The calculation condition storage unit 19q is a storage device that stores, as calculation condition data, specifications (basic data) related to the overhead wire 6 and the tension adjusting devices 10A and 10B necessary for calculating theoretical values of the inclination angle θ _Y of the yoke 11 and the rotation angle θ _W of the pulley 13 as shown in Figures 10 and 11. The calculation condition storage unit 19q stores in advance, as calculation conditions, for example, the drum length (detached section length) of the overhead wire 6, both ends of which are supported by the tension adjusting devices 10A and 10B, the wire type of the overhead wire 6, the linear expansion coefficients of the contact wire 6a and the messenger wire 6b, the diameter of the pulley 13, and the pulley ratio of the pulley 13.

The theoretical value calculation unit 19r is a means for calculating theoretical values of the amount of change of the yoke 11 and the pulley 13 of the tension adjusting devices 10A and 10B. The theoretical value calculation unit 19r calculates theoretical values of the amount of change of the yoke 11 and the pulley 13 of the tension adjusting devices 10A and 10B based on the air temperature at the time of capturing the image captured by the image capturing device 18. The theoretical value calculation unit 19r calculates theoretical values of the inclination angle θ Y of the yoke 11 and the rotation angle θ W of the pulley 13 of the tension adjusting devices 10A and 10B based on the air temperature T _N-1 at the time of capturing the previous captured image P _N-1 shown in Fig. 10 and Fig. 11 and the air temperature _{T N} at the time of capturing the current captured image P _N. The theoretical value calculation _unit 19r calculates the amount of expansion and contraction of the overhead wire 6 based on, for example, the calculation conditions stored in the calculation condition storage unit 19q and the difference in air temperature between the time of the current capture and the time of the previous capture, to calculate the theoretical value of the amount of change of the yoke 11 and the pulley 13. The theoretical value calculation unit 19r outputs the calculated theoretical values of the inclination angle θ _Y of the yoke 11 and the rotation angle θ _W of the pulley 13 to the control unit 19p as theoretical value data.

The theoretical value storage unit 19s is a means for storing the calculation results of the theoretical value calculation unit 19r. The theoretical value storage unit 19s is a storage device that stores the theoretical values of the amounts of change of the yoke 11 and the pulley 13 as theoretical value data in chronological order in association with the air temperature at the time of photographing the photographed image. The theoretical value storage unit 19s stores the theoretical values of the amounts of change for each drum ID ₁ , ..., ID _M in the order of the photographing date and time D ₁ , ..., D _N.

Next, a method for diagnosing tension of an electric rail according to a second embodiment of the present invention will be described.
In the following, the same steps as those shown in FIG. 8 are denoted by the same reference numerals and detailed description thereof will be omitted.
In S410, the control unit 19p commands the theoretical value calculation unit 19r to calculate the theoretical values. The control unit 19p reads out the calculation condition data from the calculation condition storage unit 19q and outputs the calculation condition data to the theoretical value calculation unit 19r. As a result, the theoretical value calculation unit 19r calculates the theoretical value of the inclination angle θ _Y of the yoke 11 and the theoretical value of the rotation angle θ _W of the pulley 13 based on the air temperature T _N-1 at the time of the previous shooting, the air temperature T _N at the time of the current shooting, and the calculation conditions. When the theoretical value calculation unit 19r outputs the calculated theoretical value data to the control unit 19p, the calculated theoretical value data is stored in the theoretical value storage unit 19s.

In S500, the control unit 19p commands the tension evaluation unit 19j to evaluate the tension of the overhead wire 6. The control unit 19p reads out the change amount data from the change amount storage unit 19g and outputs this change amount data to the tension evaluation unit 19j, and also reads out the theoretical value data from the theoretical value storage unit 19s and outputs this theoretical value data to the tension evaluation unit 19j. As a result, the tension evaluation unit 19j compares the measured value and theoretical value of the inclination angle θ _Y of the yoke 11, and also compares the measured value and theoretical value of the rotation angle θ _W of the pulley 13. For example, when the difference between the measured value and the theoretical value is within a predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead wire 6 is normal, and when the difference between the measured value and the theoretical value is outside the predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead wire 6 is abnormal.

The electric rail tension diagnostic device and tension diagnostic method according to the second embodiment of the present invention have the following advantages in addition to the advantages of the first embodiment.
(1) In this second embodiment, the theoretical value calculation unit 19r calculates theoretical values of the amounts of change of the yoke 11 and pulley 13 of the tension adjustment devices 10A and 10B, and the tension evaluation unit 19j evaluates the tension of the overhead wire 6 based on the measurement results of the change amount measurement unit 19f and the calculation results of the theoretical value calculation unit 19r. Therefore, by comparing the amounts of rotation of the yoke 11 and pulley 13 with these calculated values, it is possible to detect abnormalities that could lead to deterioration of current collection performance, such as whether the movement of the overhead wire 6 inside the drum is being hindered by suppression resistance due to the structure of the support point P, whether the rotation is in accordance with the adjusted length, whether there is unilateral pulling, etc.

(2) In this second embodiment, the theoretical value calculation unit 19r calculates the theoretical value of the amount of change in the yoke 11 and pulley 13 of the tension adjustment devices 10A and 10B based on the air temperature at the time the image captured by the image capture device 18 was captured. Therefore, for example, by determining the theoretical value of the temperature change in the length of the wires of the overhead line 6 and comparing it with the measured value from the captured image, it is possible to detect an abnormality in the overhead line 6.

Third Embodiment
3 and 9, the tension diagnostic device 19 shown in Fig. 13 includes a slack amount measuring unit 19t and a slack amount storage unit 19u. The control unit 19p, for example, reads out calculation condition data from the calculation condition storage unit 19q and outputs it to the theoretical value calculation unit 19r and the slack amount measuring unit 19t, commands the slack amount measuring unit 19t to measure the amount of slack, outputs slack amount data output by the slack amount measuring unit 19t to the slack amount storage unit 19u, commands the slack amount storage unit 19u to store the slack amount data, reads out the slack amount data from the slack amount storage unit and outputs it to the theoretical value calculation unit 19r. The slack amount measuring unit 19t and the slack amount storage unit 19u are connected to the control unit 19p so as to be able to communicate with each other. The calculation condition storage unit 19q stores in advance, as calculation conditions, for example, the distance (span length) between the support points P shown in FIG. 1, the weight per unit length of the messenger wire 6b, the cross-sectional area, and Young's modulus.

The theoretical value calculation unit 19r predicts a theoretical value of the amount of change in the yoke 11 and the pulley 13 of the tension adjustment devices 10A, 10B based on the slackness of the overhead wire 6 photographed by the photographing device 18. The theoretical value calculation unit 19r calculates a theoretical value of the tension of the overhead wire 6 based on the measurement result of the slackness measurement unit 19t, and also calculates a theoretical value of the amount of change in the yoke 11 and the pulley 13 of the tension adjustment devices 10A, 10B based on this theoretical value of the tension of the overhead wire 6. The theoretical value calculation unit 19r calculates a theoretical value (estimated value) of the tension of the overhead wire 6 based on, for example, the calculation conditions stored in the calculation condition storage unit 19q, the amount of slack in the messenger wire 6b of the overhead wire 6 calculated by the slackness measurement unit 19t, and the inclination angle θ _Y of the yoke 11 measured by the change measurement unit 19f. The theoretical value calculation unit 19r calculates theoretical values of the amounts of change in the yoke 11 and the pulley 13 based on, for example, the calculation conditions stored in the calculation condition storage unit 19q and the theoretical value of the tension of the overhead wire 6.

The slack measurement unit 19t is a means for measuring the amount of slack in the overhead line 6 based on the images captured by the imaging device 18. The slack measurement unit 19t measures the slack amount, sag amount s, of the catenary 6b of the overhead line 6 shown in FIG. 1 based on the three-dimensional images captured by the imaging device 18. Here, sag refers to a state in which the catenary height at the center between support points P (span) is lower than the catenary height at support point P. The slack amount s refers to the degree of slack in the catenary 6b at the center between support points P. The slack measurement unit 19t outputs the measured slack amount s to the control unit 19p as slack amount data.

The slack amount storage unit 19u is a means for storing the amount of slack in the overhead wire 6. The slack amount storage unit 19u is a storage device that stores the amount of slack in the overhead wire 6b as slack amount data in chronological order in association with the photographing dates and times _D1 , ..., _DN of the photographed images and the air temperatures _T1 , ..., _TN at the time of photographing. The change amount storage unit 19g stores the amount of slack in the overhead wire 6b for each drum _ID1 , ..., _IDM shown in Fig. 6.

Next, a method for diagnosing tension of an electric rail according to a third embodiment of the present invention will be described.
In the following, the same steps as those shown in FIG. 8 are denoted by the same reference numerals and detailed description thereof will be omitted.
In S310, control unit 19p commands slack amount measurement unit 19t to measure the amount of slack. As a result, slack amount measurement unit 19t measures the amount of sag s shown in Fig. 1 based on the three-dimensional photographed image stored in photographed image storage unit 19b and the calculation conditions stored in calculation condition storage unit 19q. When slack amount measurement unit 19t outputs the measured slack amount data to control unit 19p, this measured slack amount data is stored in slack amount storage unit 19u.

In S410, the control unit 19p commands the theoretical value calculation unit 19r to calculate a theoretical value. As a result, the theoretical value calculation unit 19r calculates a theoretical value of the tension of the messenger wire 6b based on the amount of slack stored in the slack amount storage unit 19u and the calculation conditions stored in the calculation condition storage unit 19q. The theoretical value calculation unit 19r also calculates an amount of expansion/contraction of the messenger wire 6b based on the theoretical value of the tension of the messenger wire 6b _and the calculation conditions stored in the calculation condition storage unit 19q. The theoretical value calculation unit 19r also calculates a theoretical value of the inclination angle θ _Y of the yoke 11 and a theoretical value of the rotation angle θ _W of the pulley 13 based on the theoretical value of the amount of expansion/contraction of the messenger wire 6b and the calculation conditions stored in the calculation condition storage unit 19q.

In S500, the control unit 19p commands the tension evaluation unit 19j to evaluate the tension of the overhead wire 6. As a result, the tension evaluation unit 19j compares the measured value of the inclination angle _θY of the yoke 11 with the theoretical value, and also compares the measured value of the rotation angle _θW of the pulley 13 with the theoretical value. For example, when the difference between the measured value and the theoretical value is within a predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead wire 6 is normal, and when the difference between the measured value and the theoretical value is outside the predetermined range Th, the tension evaluation unit 19j evaluates that the tension of the overhead wire 6 is abnormal.

The electric rail tension diagnostic device and tension diagnostic method according to the third embodiment of the present invention have the following advantages over the first and second embodiments.
In this third embodiment, a theoretical value calculation unit 19r calculates theoretical values of the amounts of change in the yokes 11 and pulleys 13 of the tension adjustment devices 10A, 10B based on the slackness of the overhead wire 6 photographed by the photographing device 18. Therefore, a three-dimensional image of the overhead wire 6b is obtained using a contactless measuring device, and the tension of the overhead wire 6b can be estimated based on the three-dimensional shape of the overhead wire 6b, making it possible to diagnose the tension of the overhead wire 6 or the condition of the overhead wire 6.

Fourth Embodiment
The tension adjusting devices 10A, 10B shown in Figures 15 and 16 are spring tension balancers (STBs) that use a spring to keep constant the tension change in the overhead wire 6 caused by temperature change, etc. The tension adjusting devices 10A, 10B are spring balancers that adjust the tension of the overhead wire 6 by utilizing the elasticity of the spring. As shown in Figure 16, the tension adjusting devices 10A, 10B include a yoke 11, an outer cylinder 20, an inner cylinder 21, a spring 22, a retaining material 23, and a support portion 24.

The outer tube 20 shown in FIG. 16 is a member that houses the inner tube 21 and the spring 22. The outer tube 20 has a spring bearing portion 20a that receives one end of the spring 22 on the inner periphery of the outer tube 20. The inner tube 21 is a part that moves freely forward and backward while being housed inside the outer tube 20. The inner tube 21 has a spring bearing portion 21a that receives the other end of the spring 22 on the outer periphery of the inner tube 21, and an indicator portion 21b that moves forward and backward together with the inner tube 21 to visually confirm the forward and backward position from the outside to check whether the tension of the overhead line 6 is appropriate. The spring 22 is a member that applies tension to the overhead line 6. The spring 22 is a coil spring that constantly applies a spring force to the overhead line 6. The spring 22 is inserted into the outer periphery of the inner tube 21 while being sandwiched between the spring bearing portion 20a and the spring bearing portion 21a.

The retaining material 23 is a member that connects the yoke 11 and the inner tube 21. The retaining material 23 is, for example, a wire such as a retaining wire or a retaining chain, with one end attached to the mounting portion 11c of the yoke 11 and the other end attached to the tip of the inner tube 21. The support portion 24 is a portion that supports the outer tube 20 to the support structures 8A, 8B. The support portion 24 has a fixing band that can be detachably attached to the support structures 8A, 8B so as to connect the rear end of the outer tube 20 to the outer periphery of the support structures 8A, 8B.

The change amount measuring unit 19f shown in FIG. 3, FIG. 9, and FIG. 13 measures the change amount of the inner tube 21 of the tension adjusting device 10A, 10B based on the photographed image photographed by the photographing device 18. The change amount measuring unit 19f calculates the expansion/contraction amount (stroke) S of the inner tube 21 as the change amount based on the photographed image searched by the search processing unit 19e. The change amount measuring unit 19f shown in FIG. 3 measures the expansion/contraction amount S of the inner tube 21 by referring to the template image P ₀ and the photographed image P _N as shown in FIG. 17. The change amount measuring unit 19f shown in FIG. 9 and FIG. 13 measures the expansion/contraction amount S of the inner tube 21 by referring to the previous photographed image P _N-1 and the current photographed image P _N as shown in FIG. 17. The change amount measuring unit 19f outputs the expansion/contraction amount S of the inner tube 21 after measurement as the change amount data to the control unit 19p. The plot generating unit 19h generates a plot similar to the plot shown in FIG. 7, which plots the relationship between the expansion/contraction amount S of the inner cylinder 21 of the tension adjusting devices 10A, 10B and the air temperature T at the time the captured image was taken.

The tension evaluation unit 19j shown in FIG. 3 evaluates the tension of the overhead wire 6 based on the amount of change in the inner tube 21 of the tension adjustment devices 10A, 10B and the air temperature at the time the captured image was taken. The tension evaluation unit 19j evaluates the tension of the overhead wire 6 based on whether or not a plot exists within a predetermined range Th of a plot diagram such as that shown in FIG. 7. The tension evaluation unit 19j shown in FIG. 9 and FIG. 13 evaluates the tension of the overhead wire 6 based on the measurement result of the change amount measurement unit 19f and the calculation result of the theoretical value calculation unit 19r. The tension evaluation unit 19j compares the measured value of the amount of change in the inner tube 21 measured by the change amount measurement unit 19f with the theoretical value of the amount of change in the inner tube 21 calculated by the theoretical value calculation unit 19r to evaluate whether the tension of the overhead wire 6 is normal.

9 and 13 stores conditions necessary for calculating a theoretical value of the amount of change in the inner tube 21 of the tension adjusting device 10A, 10B. The calculation condition storage unit 19q stores, for example, the spring constant of the spring 22 as a calculation condition in advance. The theoretical value calculation unit 19r calculates a theoretical value of the amount of change in the inner tube 21 of the tension adjusting device 10A, 10B. The theoretical value calculation unit 19r calculates a theoretical value of the amount of expansion/contraction S of the inner tube 21 of the tension adjusting device 10A, 10B based on the air temperature T _N-1 at the time of shooting the previous captured image P _N-1 and the air temperature T _N at the time of shooting the current captured image P _N.

The electric rail tension diagnostic device and tension diagnostic method according to the fourth embodiment of the present invention have the following advantages in addition to the advantages of the first and second embodiments.
In the third embodiment, when the tension adjusting devices 10A, 10B are spring-type automatic tension adjusting devices, the change amount measuring unit 19f measures the expansion/contraction amount S of the inner cylinder 21 of the spring-type automatic tension adjusting device. Therefore, for example, the inner cylinder 21, which is the upper movable part of the tension adjusting devices 10A, 10B, which could not be photographed by the conventional weight position detection device, can be reliably photographed from the vehicle 2 running on the track 1 by the photographing device 18 mounted on the body top surface 4a of the vehicle 2. As a result, the state of the tension adjusting devices 10A, 10B can be monitored from the image of the inner cylinder 21 acquired by the running vehicle 2, the expansion/contraction amount S can be automatically measured, and the presence or absence of an abnormality in the tension of the overhead wire 6 can be easily diagnosed.

Other Embodiments
The present invention is not limited to the above-described embodiment, and various modifications and variations are possible as described below, which are also within the scope of the present invention.
(1) In this embodiment, an overhead electric train line such as the overhead line 6 has been described as an example, but the present invention can also be applied to overhead lines such as electric power lines in the field of electricity that are erected on supports such as electric wires. In addition, in this embodiment, a case has been described in which the overhead line 6 is an overhead line of a simple catenary type, but the present invention is not limited to such an overhead line type. For example, the present invention can also be applied to an overhead line of a compound catenary type in which one auxiliary catenary is erected between the contact wire 6a and the contact wire 6b of the overhead line 6, and the contact wire 6a is suspended from the auxiliary catenary by a hanger 6c. Similarly, the present invention can also be applied to an overhead line of a twin simple catenary type in which two sets of overhead lines of a simple catenary type are erected in parallel with a predetermined interval between them.

(2) In the first to third embodiments, the change amount measuring unit 19f measures the amount of change in the yoke 11 and the pulley 13, but the present invention can also be applied to cases where the change amount measuring unit 19f measures the amount of change in either the yoke 11 or the pulley 13. Also, in the first to third embodiments, the pulley 13 in which the step portion 13c exists on the outer periphery of the large pulley portion 13b is used as an example, but the present invention can also be applied to a pulley in which the step portion 13c does not exist on the outer periphery of the large pulley portion 13b.

(3) In the first to third embodiments, the change amount measuring unit 19f measures the rotation angle θ _W of the pulley 13 with the template image P ₀ as a reference, but the present invention is not limited to such a measurement method. For example, the present invention can be applied to a case where the change amount measuring unit 19f measures the rotation angle θ _W with the position of the step portion 13c of the pulley 13 as a reference. In this case, the change amount measuring unit 19f measures how much the position of the step portion 13c on the captured image P _N has rotated from the position of the step portion 13c on the template image P ₀ , and the rotation angle θ _W of the pulley 13 can be measured. In the second and third embodiments, the measured values of the inclination angle θ _Y and the rotation angle θ _W are compared with the theoretical values of the inclination angle θ _Y and the rotation angle θ _W to evaluate the tension, but the present invention is not limited to such an evaluation method. For example, the present invention can be applied to a case where the tilt angle θ _Y of the yoke 11 is converted into the actual amount of expansion and contraction of the overhead wire 6, and the rotation angle θ _W of the pulley 13 is converted into the actual amount of expansion and contraction of the overhead wire 6 taking into account the pulley ratio, and the measured value is compared with the theoretical value to evaluate the tension. Furthermore, in the third embodiment, the theoretical value of the tension of the overhead wire 6 is calculated based on the sag amount s of the messenger wire 6b, and the theoretical value of the change amount of the yoke 11 and the pulley 13 is calculated based on this theoretical value of tension, but the present invention is not limited to such a calculation method. For example, the present invention can be applied to a case where the theoretical value of the tension of the overhead wire 6 is calculated based on the sag amount of the trolley wire 6a, or the theoretical value of the tension of the overhead wire 6 is calculated based on the sag amount of the trolley wire 6a and the messenger wire 6b.

(4) In the third embodiment, the theoretical values of the changes in the yoke 11, the pulley 13, and the inner tube 21 are calculated based on the slack of the catenary 6b, but the invention is not limited to the slack of the catenary 6b. For example, the invention can be applied to a case where the theoretical values of the changes in the yoke 11, the pulley 13, and the inner tube 21 are calculated based on the slack of wires constituting the electric rail, such as the trolley wire 6a, other than the catenary 6. In addition, in the fourth embodiment, the tension adjusting devices 10A and 10B in which one inner tube 21 is housed in the outer tube 20 so as to be freely movable forward and backward are described as an example, but the invention can be applied to a tension adjusting device in which multiple inner tubes are housed in the outer tube so as to be freely movable forward and backward. Furthermore, in the fourth embodiment, an example has been described in which the change amount measuring unit 19f measures the amount of change in the inner tube 21 of the tension adjustment devices 10A, 10B. However, the present invention can also be applied to a case in which the change amount measuring unit 19f measures the amount of change in the indicator portion 21b of the tension adjustment devices 10A, 10B.

1 Track 2 Vehicle 5 Current collector 5a Contact strip 6 Overhead wire (electrical line)
6a: contact wire; 6b: messenger wire; 10A, 10B: tension adjusting device; 11: yoke (upper movable part);
13 Pulley (upper movable part)
15 Weight (lower movable part)
17 Tension diagnostic system 18 Imaging device 19 Tension diagnostic device 19f Change amount measuring unit 19h Plot diagram generating unit 19j Tension evaluation unit 19r Theoretical value calculation unit 20 Outer tube 21 Inner tube (tubular portion (upper movable portion))
22 Spring P Support point P ₀ Template image P _N-1 Photographed image (previously photographed image)
P _N image (image taken this time)
θ _Y , θ _YA1 , ..., θ _YAN , θ _YB1 , ..., θ _YBN Tilt angle (amount of change)
θ _W , θ _WA1 , ..., θ _WAN , θ _WB1 , ..., θ _WBN rotation angles (amount of change)
T, _T1 , ..., T _N Temperature _D1 , ..., D _N Photo date and time
ID ₁ , …, ID _N drum
Th: Predetermined range s: Amount of sag (degree of slack (amount of change))
S Amount of expansion/contraction (amount of change)

Claims (4)

A train tension diagnosis device for diagnosing the tension of a train wire based on an image of a tension adjusting device for adjusting the tension of the train wire taken by a photographing device of a vehicle while the vehicle is traveling, comprising:
a change amount measuring unit that measures a rotation angle of a pulley or an inclination angle of a yoke of the tension adjusting device based on an image captured by the imaging device;
a theoretical value calculation unit that calculates a theoretical value of a rotation angle of the pulley or a tilt angle of the yoke based on the slackness of the electric rail photographed by the photographing device;
a tension evaluation unit that evaluates a tension of the electric rail based on a measurement result of the change amount measurement unit and a calculation result of the theoretical value calculation unit;
A train line tension diagnostic device comprising: A train tension diagnosis device for diagnosing the tension of a train wire based on an image of a tension adjusting device for adjusting the tension of the train wire taken by a photographing device of a vehicle while the vehicle is traveling, comprising:
a change amount measuring unit that measures an amount of expansion and contraction of an inner cylinder of the spring type automatic tension adjusting device based on an image captured by the imaging device;
a theoretical value calculation unit that calculates a theoretical value of the amount of expansion and contraction of the inner cylinder based on the slackness of the electric rail photographed by the photographing device;
a tension evaluation unit that evaluates a tension of the electric rail based on a measurement result of the change amount measurement unit and a calculation result of the theoretical value calculation unit;
A train line tension diagnostic device comprising: A method for diagnosing tension of an electric train wire, based on an image of a tension adjusting device that adjusts tension of the electric train wire taken by an image taking device of a vehicle while the vehicle is traveling, comprising:
a change amount measuring step of measuring a rotation angle of a pulley or an inclination angle of a yoke of the tension adjusting device based on an image captured by the imaging device;
a theoretical value calculation step of calculating a theoretical value of a rotation angle of the pulley or a tilt angle of the yoke based on the slackness of the electric rail photographed by the photographing device;
a tension evaluation step of evaluating the tension of the electric rail based on a measurement result in the change amount measurement step and a calculation result in the theoretical value calculation step;
A method for diagnosing tension in a contact line, comprising: A method for diagnosing tension of an electric train wire, based on an image of a tension adjusting device that adjusts tension of the electric train wire taken by an image taking device of a vehicle while the vehicle is traveling, comprising:
a change amount measuring step of measuring an amount of expansion and contraction of an inner cylinder of a spring-type automatic tension adjusting device based on an image captured by the imaging device;
a theoretical value calculation step of calculating a theoretical value of the amount of expansion and contraction of the inner cylinder based on the slackness of the electric rail photographed by the photographing device;
a tension evaluation step of evaluating the tension of the electric rail based on a measurement result of the change amount measurement step and a calculation result of the theoretical value calculation step ;
A method for diagnosing tension in a train line comprising:

Images