JP5751956B2 - Track running vehicle - Google Patents

Description

  The present invention relates to a track traveling vehicle configured to be able to travel on a track.

  An example of such an orbital traveling vehicle is a railroad work vehicle. The track-and-rail work vehicle has road traveling wheels such as tires and track traveling wheels such as iron wheels, and when traveling on the track, the left and right track traveling wheels are driven by the respective traveling hydraulic motors to travel on the track. There are some possible configurations. In the case of a track-and-rail work vehicle having such a configuration, there may be cases where the vehicle travels alone on the track for movement to the work destination or overhead line work, etc. There are many (see, for example, Patent Document 1).

JP 2010-195381 A

  By the way, in such a track traveling vehicle, for example, an operator may be working around the vehicle, such as an operation of connecting a plurality of vehicles. In this way, if the vehicle is started without being aware of the fact that the worker is around the vehicle, a contact accident between the worker and the vehicle may occur, so the worker is notified of the vehicle start. It is necessary to prompt them to leave the vehicle. Conventionally, surrounding safety checks and cues at the start are only made by the operator, and neglecting safety checks and cues is a direct cause of an accident.

  The present invention has been made in view of such a problem, and when starting a track-running vehicle, a track capable of notifying an operator around the vehicle of the start of the vehicle and prompting the worker to leave the vehicle. An object is to provide a traveling vehicle.

In order to solve the above-mentioned problem, a track traveling vehicle according to the first aspect of the present invention is a vehicle having a vehicle body having a plurality of wheels capable of traveling on a track and capable of traveling on the track, Front illumination means (for example, the headlamp 14 in the embodiment) provided at the front part of the vehicle body and illuminating the rear of the vehicle body (for example, the headlamp 14 in the embodiment). When the start of the vehicle is detected by the tail light / brake light 18) in the embodiment, the vehicle start detecting means for detecting the start of the vehicle (for example, the parking brake operation detector 43a in the embodiment), and the vehicle start detecting means. to, the front illumination means and lighting control means for lighting the at least one lighting means of the rear lighting unit (e.g., the controller 51 in the embodiment) Ru a. The front illumination means is configured to be able to switch between horizontal illumination and downward illumination, and the illumination control means detects the front illumination when the vehicle start detection means detects the start of the vehicle. When lighting the means, the horizontal illumination and the lower illumination are switched to perform passing that alternately turns on .

According to such a configuration, when starting the track vehicle, at least one of the front illumination means and the rear illumination means provided on the vehicle body is turned on. Even when there is an operator, the operator can be informed that the vehicle starts and prompted to leave the vehicle, so that the safety for the operator can be improved. Further, since the front illumination means performs passing, it is possible to more reliably notify the operator of the start of the vehicle than simply lighting the illumination means. Further, for example, even at night when the front illumination unit and the rear illumination unit are already lit, it is possible to notify the worker that the vehicle is starting.

  The track traveling vehicle having the above-described configuration includes a traveling direction detection unit that detects a traveling direction of the vehicle, and the illumination control unit detects the start of the vehicle by the vehicle start detection unit and It is preferable that the illumination means on the traveling direction side of the vehicle detected by the traveling direction detection means among the rear illumination means is configured to be turned on.

  According to such a configuration, when the track traveling vehicle is started, the illumination unit on the traveling direction side of the vehicle is turned on among the front illumination unit and the rear illumination unit. It is possible to more reliably notify the worker who is present that the vehicle starts.

  Further, in the track traveling vehicle having the above configuration, when the vehicle start is detected by the alarm sound generating means (for example, the start buzzer 19 in the embodiment) provided on the vehicle body and the vehicle start detection means, It is preferable to include an alarm sound control means (for example, the controller 51 in the embodiment) that operates the alarm sound generating means to generate an alarm sound.

  According to such a configuration, an alarm sound is generated from the alarm sound generating means together with lighting, blinking or passing of the illumination means. The start of the vehicle can be notified more reliably.

  In order to solve the above problems, a track traveling vehicle according to a second aspect of the present invention includes a vehicle body, a plurality of wheels capable of traveling on a track provided in the vehicle body, and a front portion and a rear portion of the vehicle body, respectively. Connecting means for connecting to another vehicle, and configured to be able to travel on a track in a state where a plurality of vehicles are connected by the connecting means. In addition, each of the plurality of track traveling vehicles connected by the connecting means is provided at a front portion of the vehicle body and illuminates the front of the vehicle body (for example, the headlamps 14 and 114 in the embodiment). ), Rear illumination means (for example, taillight / brake lights 18 and 118 in the embodiment) provided at the rear of the vehicle body, and whether or not other vehicles are connected in the connection device; A connection detecting means for detecting which of the front part and the rear part of the other vehicle is connected, and vehicle connection information detected by the connection detecting means is transmitted between the plurality of track traveling vehicles connected by the connecting means. Communication means. And the vehicle start detection means (for example, parking brake in an embodiment) which detects the start of a connection vehicle in the state where a plurality of the above-mentioned connection track vehicles are connected by the connection means, and the connection detection means detects the connection. Illumination control means for turning on at least one of the front illumination means and the rear illumination means in the connected vehicle when the operation detector 43a) and the start of the connected vehicle are detected by the vehicle start detection means. (For example, the controller 51 in the embodiment).

  According to such a configuration, when starting the connected vehicle, at least one of the front lighting means and the rear lighting means in the connected vehicle is turned on. Even when there is an operator, it is possible to notify the operator that the connected vehicle starts and prompt the user to leave the connected vehicle, so that the safety for the operator can be improved. it can.

  The track traveling vehicle having the above configuration includes a traveling direction detection unit that detects a traveling direction of the connected vehicle, and the illumination control unit detects each vehicle when the vehicle start detection unit detects the start of the connected vehicle. Of the front illumination means and the rear illumination means, the illumination means on the traveling direction side of the vehicle detected by the traveling direction detection means is preferably turned on. Alternatively, the illumination control means is preferably configured to turn on all the front illumination means and the rear illumination means in the connected vehicle when the vehicle start detection means detects the start of the connected vehicle.

  According to such a configuration, when starting the connected vehicle, the lighting means on the traveling direction side of the connected vehicle among the front lighting means and the rear lighting means in each vehicle is turned on. It is possible to more reliably notify the worker on the traveling direction side that the connected vehicle starts. Or, when starting the connected vehicle, all the front lighting means and the rear lighting means in the connected vehicle are turned on, so that the worker who is between the vehicles or the worker in the traveling direction side of the connected vehicle It can be more reliably notified that the connected vehicle starts.

Moreover, in the track traveling vehicle configured as described above, it is preferable that the illumination control unit is configured to blink the illumination unit when the vehicle start detection unit detects the start of the connected vehicle. Alternatively, the front illumination unit is configured to be able to switch between horizontal illumination and lower illumination, and the illumination control unit detects the front of the connected vehicle when the vehicle start detection unit detects the start of the connected vehicle. When lighting the lighting means , it is preferable that switching is performed between the horizontal lighting and the lower lighting to alternately turn on.

  According to such a configuration, when starting the connected vehicle, the illumination means blinks, or the front illumination means performs passing, so that the work is performed rather than simply lighting the illumination means. The start of the vehicle can be more reliably notified to the person. In addition, for example, even at night when the front illumination unit and the rear illumination unit are already turned on, it is possible to notify the worker that the connected vehicle starts.

  Further, in the track traveling vehicle configured as described above, when the start of the connected vehicle is detected by the warning sound generating means (for example, the start buzzers 19 and 119 in the embodiment) and the vehicle start detecting means, the warning sound is generated. It is preferable to include an alarm sound control means (for example, the controller 51 in the embodiment) that operates the sound generation means to generate an alarm sound.

  According to such a configuration, an alarm sound is generated from the alarm sound generating means together with lighting, blinking or passing of the illumination means. The start of the connected vehicle can be notified more reliably.

  According to the track traveling vehicle of the present invention, when starting the track traveling vehicle, it is possible to notify the worker around the vehicle of the start of the vehicle and urge the worker to leave the vehicle. It is possible to improve safety against.

It is a side view of the track-and-rail work vehicle which concerns on this invention. It is a hydraulic circuit diagram which shows the hydraulic drive system which has the traveling control apparatus of the said track and field work vehicle. It is a side view which shows the whole structure at the time of driving | running | working on a track | orbit by connecting three track-and-rail work vehicles. It is a figure explaining the structure of the connection connector for detecting the front-back connection state of the own vehicle. It is a front-back connection state table which shows all the patterns of the front-back connection state of the own vehicle. It is a connection combination table which shows the connection combination state in the case of 3 units | sets connection.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a track-and-rail work vehicle 1 as an example of a track traveling vehicle according to the present invention. The track-and-work vehicle 1 includes a traveling body 10 based on a truck vehicle having a driving cab 11, a vertical lifting device 20 provided on the traveling body 10, and an operator supported by the vertical lifting device 20. And a workbench 30 for boarding.

  The traveling body 10 includes tire wheels 12 that are road traveling wheels on the front, rear, left, and right sides of the vehicle body, and an engine (not shown) inside the vehicle body. The tire wheels 12 are driven by the engine on the road. It is possible to run. In addition, the traveling body 10 includes iron wheels 15 that are track traveling wheels via iron wheel support members 13 on the front, rear, left, and right sides of the vehicle body (the rear side of each tire wheel 12). The rotary drive shafts of motors 16L and 16R (see FIG. 2) are connected, and the left and right traveling hydraulic motors 16L and 16R drive the front left and right iron wheels 15 to travel on the track (railway rail) R. Be able to.

  The iron ring support member 13 is supported by the traveling body 10 so as to be swingable in the vertical direction, and is pivoted up and down by an expansion and contraction operation of an iron ring extension cylinder (hydraulic cylinder) provided inside the traveling body 10 to thereby cause the iron ring 15 to move. The tire wheel 12 can be extended downward or stored upward. In order to overhang and store the iron wheel 15 in this way (in order to transfer and move the track work vehicle 1 on the track), the traveling body 10 includes a turntable 17 at the lower center of the vehicle body and a turntable inside. An overhanging cylinder (hydraulic cylinder), and a state in which the turntable 17 is extended downward by the telescopic operation of the turntable overhanging cylinder to lift the track work vehicle 1 (a state where the tire wheel 12 is lifted from the ground); Can be done.

  A pair of left and right headlamps (headlights) 14 are provided at the front portion of the traveling body 10, and a pair of left and right taillights integrally formed with a taillight and a brake light at the rear portion of the traveling body 10. A cum brake lamp (tail brake lamp) 18 is provided. These lamps receive power from the vehicle battery and are normally turned on by operating an illumination light switch provided in the driver's seat of the driving cab 11 or a brake switch that operates in response to an operation of a brake pedal or the like. ing. The headlamp 14 can be turned on by switching between a high beam (horizontal illumination) and a low beam (downward illumination) by operating an illumination lamp switch. Further, the traveling body 10 is provided with a start buzzer 19 (see FIG. 2) that emits an alarm sound when the vehicle starts moving on the track R.

  The vertical elevating device 20 is provided in a pair in the vehicle width direction on the traveling body 10 behind the driving cab 11 via the bodywork frame 21 and crosses two link bars so that the intersection is rotatably connected. A scissor link mechanism (not shown) and an elevating cylinder (hydraulic cylinder) provided across the scissor link mechanism and the body frame 21 are configured, and the upper end of the scissor link mechanism is extended by an expansion / contraction operation of the elevating cylinder. The work table 30 attached to the part can be moved up and down. In addition, the operation | movement of the vertical raising / lowering apparatus 20 (elevating cylinder) can be actuated by the operation | work operation apparatus (not shown) provided in the traveling body 10 and the workbench 30, respectively.

  In the track-and-rail work vehicle 1 having such a configuration, the vehicle travels on the track R and moves to the destination, and the vertical lifting device 20 is operated to move the work table 30 to a desired height position. While stopped or traveling on the track R, an operator who has boarded the work table 30 can perform construction of railway facilities such as an extension line or a trolley line on the track R. In addition, although the driving | running | working at the time of driving | running | working a general road is performed from the inside of the driving cab 11, the driving | running | working at the time of driving | running | working on the track | truck R can be performed from the work bench 30 besides the driving cab 11. Hereinafter, the travel control device 50 when the track-and-work vehicle 1 travels on the track R will be described with reference to FIG.

  The travel control device 50 sends an operation control signal to a travel operation device 40 for performing a travel operation when traveling on the track R, and to a travel hydraulic circuit 60 (to be described later) according to an operation signal input from the travel operation device 40. And a controller 51 for outputting.

  The travel operation device 40 includes a power switch 41, a travel speed setting dial 42, a parking brake operation lever 43, a travel operation lever 44, and a travel mode changeover switch 45. And the work table 30. When the power switch 41 is turned ON, a power ON signal is input from the power switch operation detector 41a to the controller 51, and the traveling operation device 40 is electrically connected to the power supply side so that the operator can perform a traveling operation. It is configured.

  The traveling speed setting dial 42 is a dial that can be twisted clockwise (clockwise) or counterclockwise (counterclockwise) within a predetermined range, and can set a maximum speed during trajectory traveling by the traveling operation device 40. It is configured. The operation state (twisting operation position) of the traveling speed setting dial 42 is detected by the speed setting operation detector 42a. When the traveling speed setting dial 42 is twisted, the twisting speed is detected from the speed setting operation detector 42a. A set maximum speed signal corresponding to the operation position is input to the controller 51.

  The parking brake operation lever 43 is an operation lever for locking or unlocking the iron wheel drive shafts of the left and right traveling hydraulic motors 16L and 16R by a parking brake device 95 described later. The operation state of the parking brake operation lever 43 is detected by the parking brake operation detector 43a. When the parking brake operation lever 43 is moved to the lock position, the drive shaft lock signal is transmitted from the parking brake operation detector 43a to the controller. When the parking brake operation lever 43 is moved to the unlock position, the drive shaft unlock signal is input to the controller 51 from the parking brake operation detector 43a.

  The traveling operation lever 44 is positioned at the neutral position in the non-operating state, and can be tilted forward or backward with reference to the neutral position. When the hand is released from the tilting operating state, the traveling operation lever 44 is built-in. It is configured to automatically return to the neutral position by the force of the spring. The operation state (the operation direction and the operation amount with reference to the neutral position) of the travel operation lever 44 is detected by the travel operation detector 44a, and the operation of the travel operation lever 44 detected by the travel operation detector 44a is detected. Information on the state (traveling operation signal) is input to the controller 51. The tilting operation forward from the neutral position of the travel operation lever 44 sets the traveling direction of the traveling body 10 forward, and the tilting operation backward from the neutral position sets the traveling direction of the traveling body 10 backward. This corresponds to a command for setting the traveling speed corresponding to the tilting operation amount with respect to the traveling direction. The travel speed set at this time is set within a range from zero speed to the maximum speed set by the travel speed setting dial 42. Further, the operation of returning the traveling operation lever 44 to the neutral position corresponds to a command for stopping the traveling body 10.

  By the way, in the track-and-rail work vehicle 1, the left and right traveling hydraulic motors 16 </ b> L and 16 </ b> R are driven at high speed by supplying hydraulic oil in series to the left and right traveling hydraulic motors 16 </ b> L and 16 </ b> R to travel on the track R. High-speed traveling mode and low-speed traveling mode in which the left and right traveling hydraulic motors 16L and 16R are driven to rotate at low speed by supplying hydraulic oil in parallel to the left and right traveling hydraulic motors 16L and 16R. And a high-speed driving mode and a low-speed driving mode can be switched and set by the driving mode changeover switch 45. When the traveling mode changeover switch 45 is switched, a traveling mode switching signal is input to the controller 51 from the traveling mode switching operation detector 45a.

  The traveling body 10 includes a traveling hydraulic pump 61 that is driven by a power source PS composed of an electric motor, a small engine, and the like to discharge hydraulic oil, and left and right traveling that rotates by receiving hydraulic oil from the hydraulic pump P. Hydraulic motors 16L, 16R, a flow dividing valve 63 for diverting and collecting the flow rate of hydraulic oil from the traveling hydraulic pump 61, and a hydraulic fluid from the traveling hydraulic pump 61 to the left and right traveling hydraulic motors 16L, There is provided a flow path switching means 65 for switching whether to supply in parallel or in series to 16R, and these are connected by oil paths 71 to 81 to form a traveling hydraulic circuit 60.

  The traveling hydraulic pump 61 is a swash plate type variable displacement hydraulic pump, and the swash plate tilt direction and tilt angle are controlled by a swash plate control actuator 62. The operation of the swash plate control actuator 62 is controlled based on an operation control signal sent from the controller 51. One suction discharge port of the traveling hydraulic pump 61 is connected to the P port of the flow collecting valve 63 via the oil passage 71, and the other suction discharge port of the traveling hydraulic pump 61 is connected to the left and right sides via the oil passage 80. It is connected to one of the travel hydraulic motors 16L, 16R (in this embodiment, one suction discharge port of the right travel hydraulic motor 16R).

  The diversion valve 63 functions as a diversion valve when the P port is used as an inlet and the A and B ports are used as an outlet, and substantially reduces the flow rate of hydraulic oil from the traveling hydraulic pump 61 that has flowed from the P port via the oil passage 71. It is configured so as to be divided into half and to flow out from the A and B ports. That is, the flow rate of the hydraulic fluid flowing out from the A and B ports is approximately half of the flow rate of the hydraulic fluid discharged from the traveling hydraulic pump 61, respectively. Further, the branch flow valve 63 functions as a flow collecting valve when the A and B ports are used as the inlet and the P port is used as the outlet, so that the hydraulic oils flowing in from the A and B ports respectively merge and flow out from the P port. It is configured.

  The flow path switching means 65 includes a first flow path switching valve 65a and a second flow path switching valve 65b, which are electromagnetically controlled 4-port 2-position switching valves, and the first and second flow path switching valves 65a. , 65b are controlled based on an operation control signal from the controller 51. The first flow path switching valve 65a is such that the P port, the T port, the A port, and the B port are all closed in the non-excited state, and the P port and the A port are communicated and the B port and the T port are communicated in the excited state. It has become. In the non-excited state, the second flow path switching valve 65b communicates with the P port and the A port, and communicates with the B port and the T port. In the excited state, the P port and the T port are closed, and the A port and the B port communicate with each other. It has become.

  The A port of the flow collecting valve 63 is connected to the P port of the first flow path switching valve 65 a via the oil path 72, and the P of the second flow path switching valve 65 b is connected to the P path of the second flow path switching valve 65 b via the oil path 73 branched from the oil path 72. Connected to the port. The B port of the diversion valve 63 is connected to one suction discharge port of the left traveling hydraulic motor 16L through an oil passage 74. The A port of the first flow path switching valve 65 a is connected to the oil path 74 via the oil path 75. The other suction discharge port of the left traveling hydraulic motor 16L is connected to the B port of the first flow path switching valve 65a via the oil path 76, and is switched to the second flow path via the oil path 77 branched from the oil path 76. It is connected to the B port of the valve 65b. The A port of the second flow path switching valve 65b is connected to one suction / discharge port of the right traveling hydraulic motor 16R via an oil path 79. The T port of the first flow path switching valve 65 a is connected to the oil path 79 via the oil path 78. The other suction / discharge port of the right traveling hydraulic motor 16 </ b> R is connected to the suction / discharge port on the opposite side to the oil passage 71 of the traveling hydraulic pump 61 via the oil passage 80. The T port of the second flow path switching valve 65 b is connected to the oil path 80 via the oil path 81.

  In addition, the traveling body 10 is provided with a brake hydraulic pump 91 driven by a drive source PS in the same manner as the traveling hydraulic pump 61, and hydraulic oil discharged from the brake hydraulic pump 91 is supplied to each iron wheel 15. Are supplied to a brake device 92 provided in the vicinity of the vehicle and a parking brake device 95 provided respectively inside the left and right traveling hydraulic motors 16L, 16R.

  The brake device 92 includes a cylinder 92a, a piston 92b provided in the cylinder 92a so as to be extended and retractable, a disk 92c provided at the tip of the piston 92b, and a cylinder 92a provided with the piston 92b in the storage direction ( In the case of FIG. 2, it has a piston spring 92d biased upward). When the hydraulic oil from the brake hydraulic pump 91 is supplied to the cylinder chamber of the cylinder 92a through the oil passage 82, the piston 92b opposes the urging force of the piston spring 92d (in the case of FIG. 2). The disk 92c is pressed against the iron wheel 15 to brake the iron wheel 15.

  A relief valve 93 and a shut-off valve 94 are respectively provided in the oil passages 83 and 84 branched from the oil passage 82 and connected to the oil passage 87 connected to the oil tank T. The relief valve 93 is an electromagnetic control type valve, and its operation is controlled based on an operation control signal from the controller 51. When the relief valve 93 is in a non-excited state, the valve is completely opened, and when excited by an operation control signal from the controller 51, the relief valve 93 is proportionally throttled according to the operation control signal. Further, the relief valve 93 is configured to open the valve and relieve the hydraulic oil when the hydraulic pressure exceeds a predetermined pressure in a state where the valve is completely closed.

  The shutoff valve 94 is an electromagnetic control type valve, and its operation is controlled based on an operation control signal from the controller 51. The shutoff valve 94 closes the oil passage 84 as shown in FIG. 2 when in the non-excited state, and opens the oil passage 84 when excited by an operation control signal from the controller 51. The brake device 92 controls the hydraulic pressure of the oil passage 82 by controlling the relief pressure of the hydraulic oil by the relief valve 93 and the shut-off valve 94 in this way, and the operation thereof is controlled.

  The parking brake device 95 includes a cylinder 95a, a piston 95b provided in the cylinder 95a so as to be extended and retractable, a disk 95c provided at the tip of the piston 95b, and a piston 95b provided in the cylinder 95a. The piston spring 95d is configured to be biased in the direction (upward in the case of FIG. 2). When the hydraulic pressure is not supplied to the parking brake device 95, the piston 95b is pushed by the piston spring 95d and moves in the extending direction, and the disk 95c is provided inside the left and right traveling hydraulic motors 16L and 16R. By pressing a multi-plate brake (not shown), the iron wheel drive shafts of the left and right traveling hydraulic motors 16L and 16R are locked.

  On the other hand, when the hydraulic oil from the brake hydraulic pump 91 is supplied into the cylinder chamber of the cylinder 95a through the oil passage 85 and the oil passage 86 branched from the oil passage 82, the piston 95b resists the urging force of the piston spring 95d. Then, it moves in the retracted direction (downward in the case of FIG. 2), the disk 95c is separated from the multi-plate brake, and the locks of the iron wheel drive shafts of the left and right traveling hydraulic motors 16L, 16R are released. .

  A parking brake control valve 96 is provided between the oil passage 85 and the oil passage 86. The parking brake control valve 96 is an electromagnetic control type valve, and its operation is controlled based on an operation control signal from the controller 51. When the parking brake control valve 96 is in a non-excited state, as shown in FIG. 2, one end of the oil passage 85 is closed, and the oil passage 86 and the oil passage 87 connected to the oil tank T are connected to each other. When excited by the operation control signal from, the one end of the oil passage 87 is closed and the oil passage 85 and the oil passage 86 are connected. In this way, the parking brake device 95 performs connection / disconnection control between the oil passage 85 and the oil passage 86 by the parking brake control valve 96 to control the operation thereof.

  According to the traveling control device 50 having such a configuration, when the operator operates the traveling cab 11 or the traveling operation device 40 in the work table 30 to travel on the track R, first, the power switch 41 is turned on. After the traveling operation by the traveling operation device 40 is enabled, the parking brake operation lever 43 is operated to unlock the iron wheel drive shafts of the left and right traveling hydraulic motors 16L and 16R by the parking brake device 95. At this time, an off signal is input from the parking brake operation detector 43 a to the controller 51, and the controller 51 outputs an operation control signal for connecting the oil passage 85 and the oil passage 86 to the parking brake control valve 96, and the parking brake device 95. The hydraulic oil is supplied to unlock the iron wheel drive shafts of the left and right traveling hydraulic motors 16L and 16R.

  Further, the parking brake operation lever 43 is operated, and a signal for releasing the lock of the iron wheel drive shafts of the left and right traveling hydraulic motors 16L and 16R by the parking brake device 95 from the parking brake operation detector 43a is input to the controller 51. Then, the controller 51 outputs a lighting control signal to the headlamp 14 and the tail lamp / brake lamp 18 to light the head lamp 14 and the tail lamp / brake lamp 18. At this time, the controller 51 outputs an alarm control signal to the start buzzer 19 and generates an alarm sound from the start buzzer 19.

  When the parking brake operating lever 43 is operated in this manner and the lock of each traveling hydraulic motor by the parking brake device 95 is released, that is, when the track work vehicle 1 is about to start (immediately before the vehicle starts), Since the headlamp 14 and the tail lamp / brake lamp 18 are turned on and an alarm sound is generated by the start buzzer 19, even if there is an operator around the vehicle, the worker Therefore, it is possible to notify the vehicle to start and prompt the vehicle to leave the vehicle, so that the safety for the worker can be improved.

  For example, when the headlamp 14 and the tail lamp / brake lamp 18 are already lit at night or the like, the controller 51 outputs a blinking control signal to the headlamp 14 and the tail lamp / brake lamp 18. The headlamp 14 and the tail lamp / brake lamp 18 are blinked. Alternatively, the controller 51 outputs a high / low switching control signal to the headlamp 14, and performs passing that causes the headlamp 14 to alternately switch on a high beam (horizontal illumination) and a low beam (downward illumination). Thus, when the track-and-work vehicle 1 is going to start, the headlamp 14 and the tail lamp / brake lamp 18 are blinked, or the headlamp 14 is passed and an alarm sound is generated by the start buzzer 19. Therefore, even when the headlamp 14 and the tail lamp / brake lamp 18 are already lit at night or the like, the workers around the vehicle are informed that the vehicle starts. be able to.

  The tail lamp / brake lamp 18 is also configured to be able to switch between high beam and low beam so that when passing through the headlamp 14, the tail lamp / brake lamp 18 also switches between high beam and low beam and alternately lights. You may make it perform passing.

  When the headlamp 14 and tail lamp / brake lamp 18 are turned on, blinking, or passing when the track work vehicle 1 is about to start, a predetermined time elapses from the start of these controls or the vehicle starts. The control is continued until the predetermined speed is reached, and after the predetermined time has passed or when the predetermined speed is exceeded, the original state is controlled. That is, before the parking brake operation lever 43 is operated, if the headlamp 14 and the tail lamp / brake lamp 18 are not lit, the predetermined time has elapsed or the predetermined speed has been exceeded. When the headlamp 14 and the tail lamp / brake lamp 18 are turned off and the head lamp 14 and the tail lamp / brake lamp 18 have already been turned on, after the predetermined time has elapsed, or more than the predetermined speed. At this time, the headlamp 14 and the tail lamp / brake lamp 18 are turned on.

  When the traveling hydraulic motor is unlocked by the parking brake device 95, the traveling speed setting dial 42 is then twisted to set a desired maximum speed. At this time, the set maximum speed signal is input from the speed setting operation detector 42 a to the controller 51. Then, the traveling operation lever 44 is tilted forward or backward. At this time, information on the operation state (the operation direction and the operation amount based on the neutral position) of the travel operation lever 44 is input from the travel operation detector 44a to the controller 51, and the controller 51 starts from the speed zero to the travel speed setting dial 42. Is output to the swash plate control actuator 62 to tilt the swash plate of the traveling hydraulic pump 61 so that the traveling hydraulic pump 61 is tilted. Hydraulic oil is supplied from left and right traveling hydraulic motors 16L and 16R. That is, the iron wheels 15 and 15 are rotated by the left and right traveling hydraulic motors 16L and 16R, and the track work vehicle 1 travels on the track R.

  When the traveling operation lever 44 is tilted forward, a forward traveling operation signal is input from the traveling operation detector 44 a to the controller 51, and the controller 51 travels hydraulic pressure so that the swash plate control actuator 62 advances the railroad work vehicle 1. An operation control signal for tilting the swash plate of the pump 61 is output. Further, when the traveling operation lever 44 is tilted rearward, a reverse traveling operation signal is input from the traveling operation detector 44 a to the controller 51, and the controller 51 causes the traveling hydraulic pressure so that the railroad work vehicle 1 moves backward to the swash plate control actuator 62. An operation control signal for tilting the swash plate of the pump 61 is output.

  The traveling speed of the track-and-work vehicle 1 changes the tilting angle of the swash plate of the traveling hydraulic pump 61 by changing the operation amount (tilting amount) of the traveling operation lever 44, and is discharged from the traveling hydraulic pump 61 to the left and It is controlled by changing the flow rate of hydraulic oil supplied to the right traveling hydraulic motors 16L, 16R. The traveling speed of the railroad work vehicle 1 is a speed according to the operation amount of the traveling operation lever 44 within a range from zero speed to the maximum speed set by the traveling speed setting dial 42.

  When the operator operates the travel operation device 40 to travel on the track R, the travel mode changeover switch 45 can switch between the high speed travel mode and the low speed travel mode. When the travel mode switching switch 45 is switched to the low speed travel mode, a low speed travel mode switching signal is input from the travel mode switching operation detector 45a to the controller 51, and the controller 51 is a solenoid for the first and second flow path switching valves 65a and 65b. In the non-excited state, the first and second flow path switching valves 65a and 65b are switched to the left switching position shown in FIG. Then, a parallel hydraulic circuit is configured in which the left and right traveling hydraulic motors 16L and 16R are connected in parallel to the traveling hydraulic pump 61, and hydraulic oil is supplied in parallel to the left and right traveling hydraulic motors 16L and 16R. Thus, the track-and-rail work vehicle 1 performs high-torque low-speed traveling.

  On the other hand, when the travel mode switch 45 is switched to the high speed travel mode, a high speed travel mode switching signal is input from the travel mode switching operation detector 45a to the controller 51, and the controller 51 receives the first and second flow path switching valves 65a and 65b. The operation control signal is output to turn each solenoid in an excited state, and the first and second flow path switching valves 65a and 65b are switched to the right switching position shown in FIG. Then, a series hydraulic circuit in which the left and right traveling hydraulic motors 16L and 16R are connected in series to the traveling hydraulic pump 61 is configured, and hydraulic oil is supplied in series to the left and right traveling hydraulic motors 16L and 16R. Thus, the track-and-rail work vehicle 1 performs low-torque high-speed traveling.

  In order to stop the track-and-rail work vehicle 1 traveling on the track R, the traveling operation lever 44 is returned to the neutral position. At this time, a travel stop signal is input from the travel operation detector 44a to the controller 51, and the controller 51 outputs an operation control signal for making the discharge amount of the travel hydraulic pump 61 zero to the swash plate control actuator 62, and travels left and right. The supply of hydraulic oil to the hydraulic motors 16L and 16R is stopped, an operation control signal for opening the oil passage 84 is output to the shutoff valve 94, and an operation control signal for restricting the valve by a predetermined amount is output to the relief valve 93. Then, the hydraulic oil from the brake hydraulic pump 91 is supplied to the brake device 92, and the brake device 92 is caused to brake the iron wheel 15 with a predetermined brake pressure.

  The operation control signal is output to the relief valve 93 and the shut-off valve 94 for a predetermined time (for example, about 15 seconds) from the start of braking. When the predetermined time elapses, the controller 51 supplies the oil path 84 to the shut-off valve 94. An operation control signal for closing the valve is output, and an operation control signal for causing the relief valve 93 to completely open the valve is output, thereby stopping the supply of hydraulic oil to the brake device 92. Further, after a predetermined time (for example, about 10 seconds) has elapsed from the start of braking, the controller 51 shuts off the oil passage 85 and the oil passage 86 from the parking brake control valve 96 and stops supplying hydraulic oil to the parking brake device 95. And the parking brake device 95 locks the iron wheel drive shafts of the left and right traveling hydraulic motors 16L and 16R. Thereby, the track-and-rail work vehicle 1 will be in a stop state.

  The track-and-rail work vehicle 1 configured in this way may travel on the track R independently in movement to the work destination or overhead work, but a plurality of vehicles are connected as shown in FIG. In some cases, the vehicle travels on the track R. The track-and-rail work vehicle 100 includes a traveling body 110 configured based on a truck vehicle having a driving cab 111, and drives tire wheels 112 provided on the front, rear, left and right of the vehicle body by an engine inside the vehicle body. You can drive on the road. The track-and-rail work vehicle 100 includes iron wheels 115 via iron wheel support members 113 on the front, rear, left and right of the vehicle body, and the left and right traveling hydraulic motors 16L and 16R (see FIG. 2) drive the front left and right iron wheels 115. The vehicle can travel on the track R.

  A pair of left and right headlamps (headlights) 114 are provided at the front of the traveling body 110, and a pair of left and right taillights integrally formed with a taillight and a brake light at the rear of the traveling body 110. A double brake lamp (tail brake lamp) 118 is provided. These lamps receive power from the vehicle battery and are normally turned on by operating an illumination light switch provided in the driver's seat of the driving cab 111 or a brake switch that operates in response to an operation of a brake pedal or the like. ing. The headlamp 114 can be turned on by switching between a high beam (horizontal illumination) and a low beam (downward illumination) by operating an illumination lamp switch. Further, the traveling body 110 is provided with a start buzzer 119 (see FIG. 2) that emits an alarm sound when the vehicle starts moving on the track R.

  On the traveling body 110, an aerial work device 120, a drum driving device 130, and a central cabin 140 are provided. The aerial work device 120 includes a telescopic lift post 121 vertically installed on the rear side of the driving cab 111, and a work board 122 for boarding a worker attached to the top of the lift post 121. The work table 122 can be moved up and down by an expansion and contraction operation of a lifting cylinder (not shown) built in the lifting post 121. A lifting / lowering operation device (not shown) for operating the lifting / lowering movement of the working table 122 is provided in the working table 122.

  The drum driving device 130 is configured to rotate and drive a drum 135 capable of winding an overhead wire around an outer peripheral portion thereof to feed and wind the overhead wire. The drum driving device 130 rotates the winding drum 135 in the winding direction (clockwise in FIG. 3) while the railroad working vehicle 100 travels forward, so that the overhead wire from the front upper side of the working vehicle 100 is drummed. It operates to wind up to 135. At this time, the drum driving device 130 rotates the drum 135 at a rotation speed corresponding to the traveling speed of the railroad work vehicle 100, and acts a tension within a predetermined range on the overhead wire wound by this. On the other hand, when the overhead wire is fed out, the drum 135 around which the newly installed overhead wire is wound is rotated in the direction opposite to the feeding direction (counterclockwise in FIG. 3), and the overhead wire is fed out from the drum 135 to the upper rear side of the work vehicle 100. Operates as follows. At this time, the drum driving device 130 rotates the drum 135 in the reverse direction at a rotational speed (predetermined torque) corresponding to the traveling speed of the railroad work vehicle 100, and thereby the overhead line fed from the drum 135 is within a predetermined range. Apply tension.

  The central cabin 140 is a box-shaped operation room that is provided between the aerial work device 120 and the drum drive device 130 and on which an operator can ride, and an operator seat (see FIG. And a travel operation device (having the same configuration as the travel operation device 40 described above) for performing a travel operation on the track R of the track-and-work vehicle 100, and will be described in detail below as the travel operation device 40. And a work operation device (not shown) for operating each device disposed on the vehicle body, such as the aerial work device 120 and the drum drive device 130. The central cabin 140 is provided so as to be able to turn 180 degrees horizontally on the vehicle body. An operator who has boarded the central cabin 140 operates a turning motor (not shown) to turn the central cabin 140 horizontally. Various operation inputs can be performed with the vehicle facing forward or rearward. The traveling operation device 40 is provided not only in the central cabin 140 but also in the driving cab 111. In the track-and-rail work vehicle 100, the driving when traveling on the track R is performed in the driving cab 111 and the central cabin. It can be performed from any one of 140.

  The railroad work vehicle 100 is input from the travel operation device 40, the travel hydraulic circuit 60, and the travel operation device 40 for performing a travel operation when traveling on the track R, similarly to the above-described trackway work vehicle 1. A travel control device 50 having a controller 51 that outputs an operation control signal to the travel hydraulic circuit 60 in response to an operation signal is provided (see FIG. 2). Since these configurations are the same as those described above, the same reference numerals are given and detailed descriptions thereof are omitted. Moreover, since the track-and-rail work vehicle 200 is the same vehicle as the above-described track-and-work vehicle 1, the configuration of the track-and-work vehicle 200 is also denoted by the same reference numerals and detailed description thereof is omitted.

  As shown in FIG. 3, the track-and-rail work vehicles 1, 100 and 200 configured as described above are respectively connected using connection rods 55 and connection means 56 and 156 arranged before and after each of the work vehicles. . The connecting rod 55 is made of a metal rod-like member that does not easily bend or expand and contract, and is fixed to the connecting means 56 and 156 provided in each work vehicle. Inside the connecting rod 55, a communication cable (not shown) is provided for enabling vehicle information to be mutually communicated between the vehicles. When 200 is connected, the travel control device 50 of each work vehicle is connected via this communication cable, and the vehicle information can be communicated with each other.

  The connecting means 56 and 156 include a fixing bracket for fixing the connecting rod 55 and connection detectors 57 and 157 for detecting whether the connecting rod 55 is attached to the fixing bracket and another vehicle is connected (FIG. 2). And are provided at the front and rear portions of the traveling bodies 10 and 110, respectively. The connection detectors 57 and 157 are configured to include connection connectors 58 and 158 (see FIG. 4) that can be connected to the communication cable. When the communication cable is connected to this connector, another vehicle is connected. A detection signal (vehicle connection signal) is output to the traveling control device 50 of the host vehicle. As shown in FIG. 4, the connection connectors 58 and 158 detect the front part in order to detect which of the front part and the rear part of the other vehicle is connected to the front and rear of the own vehicle (the front and rear connection state of the own vehicle). The first port A for transmission, the second port B for rear detection, and the third port C for other information communication are configured. Note that the communication cable in the connecting rod 55 also includes three signal lines corresponding to these three ports.

  Next, a method for detecting the front and rear connection state of the host vehicle will be described. The travel control device 50 provided in each work vehicle includes a memory 52 in which the front-rear connected state of the host vehicle and the connected combination of the number of connected vehicles are stored in advance. The controller 51 recognizes whether or not another vehicle is connected in the connection means 56 and 156 based on the vehicle connection signal input from the connection detectors 57 and 157 before and after the vehicle. A connection recognition signal is output to the vehicle travel control device (controller). At this time, the connection recognition signal is output to the other vehicle via the first port A of the connection connectors 58 and 158 in the connection means 56 and 156 in the front part of the vehicle, and the connection connector 58 is output in the connection means 56 and 156 in the rear part of the vehicle. , 158, the connection recognition signal is output to the other vehicle via the second port B. Due to the difference in the ports, the travel control device of the other vehicle can recognize which one of the front and rear of the partner vehicle is connected. Similarly, in the controller 51, a connection recognition signal is input from the travel control device of the other vehicle via the first port A or the second port B of the connection connectors 58 and 158. It is possible to recognize which of the front and rear of the vehicle is connected (the front and rear connection state of the host vehicle).

  The memory 52 includes a front / rear connection state table BT (see FIG. 5) showing all the patterns of the front and rear connection states of the host vehicle, and a connection combination table VT (FIG. 6) showing all patterns of the connection combinations for each number of connected vehicles. Are stored in advance.

  As shown in FIG. 5, the front / rear connected state table BT is a table showing all patterns of the front / rear connected state of the host vehicle. As shown in the rightmost column (front / rear connected state) of the table, this front / rear connected state is all There are 8 types (front-rear connected state = 0 to 7). Here, the FF row indicates whether the front portion of the other vehicle is connected to the front portion of the own vehicle, the FR row indicates whether the rear portion of the other vehicle is connected to the front portion of the own vehicle, and the RF row indicates the own row. Whether the front part of the other vehicle is connected to the rear part of the vehicle, the RR column is a column indicating whether the rear part of the other vehicle is connected to the rear part of the host vehicle. When the controller 51 recognizes the front-rear connection state of the host vehicle as described above, the controller 51 determines from the front-rear connection state table BT whether the front-rear connection state = 0 to 7, and recognizes the front-rear connection state based on the state number. To do. For example, when the rear part of the other vehicle is connected to the front part of the own vehicle and the front part of the other vehicle is connected to the rear part of the own vehicle, the controller 51 recognizes that the front and rear connection state = 4. When the front part of the other vehicle is connected to the front part of the own vehicle and the front part of the other vehicle is connected to the rear part of the own vehicle, the controller 51 recognizes that the front and rear connection state = 7.

  As shown in FIG. 6, the connection combination table VT is a table showing all patterns of connection combinations when the number of connected units is three, and in the case of connecting three units, there are eight types of combinations. Here, the connection combination is a combination of the above-described front and rear connection states in each vehicle in the order of vehicle connection. The column of the connection direction in this table shows the information on the direction (connection direction) of each vehicle by the difference in the code (“1” or “−1”). Different vehicles are reversed. In addition to these three units connected to the memory 52, two units (all four types of combinations), four units (16 types of combinations), five units (32 types of combinations), and five units are connected. The connection combination table of the above connection is also stored.

  The travel control by the travel control device 50 of each work vehicle when the track-and-work vehicles 1, 100, 200 configured as described above are connected as shown in FIG. . When the three track-and-rail work vehicles 1, 100, 200 are connected using the connecting rod 55 and the connecting means 56, 156, first, the front-rear connection state of the host vehicle is detected (recognized) in each work vehicle.

  At this time, in the track-and-rail work vehicle 1, a vehicle connection signal is input from the connection detector 57 at the rear of the vehicle to the controller 51, but no signal is input from the connection detector 57 at the front of the vehicle to the controller 51. At the same time, the controller 51 outputs a connection recognition signal to the controller 51 of the work vehicle 100 via the second port B of the connection connectors 58 and 158, and outputs the first port A from the controller 51 of the work vehicle 100. A connection recognition signal is input through the terminal. As a result, the controller 51 of the work vehicle 1 recognizes that there is no connection of the other vehicle at the front part of the own vehicle, and that the front part of the work vehicle 100 is connected to the rear part of the own vehicle. It is recognized from the connection state table BT that the front and rear connection state = 1.

  In the railroad work vehicle 100, vehicle connection signals are input to the controller 51 from the connection detectors 157 and 157 before and after the vehicle. At the same time, the controller 51 outputs a connection recognition signal to the controller 51 of the work vehicle 1 via the first port A of the connection connectors 158 and 58, and the connection connector 158, 58, the connection recognition signal is output via the second port B, and the connection recognition signal is input from the controller 51 of the work vehicle 1 via the second port B, and the second port B is output from the controller 51 of the work vehicle 200. A connection recognition signal is input through the terminal. Thus, the controller 51 of the work vehicle 100 recognizes that the rear portion of the work vehicle 1 is connected to the front portion of the host vehicle, and the rear portion of the work vehicle 200 is connected to the rear portion of the host vehicle, due to the difference in port. It is recognized from the front / rear connection state table BT in the memory 52 that the front / rear connection state = 3.

  Further, in the track-and-rail work vehicle 200, a vehicle connection signal is input from the connection detector 57 at the rear of the vehicle to the controller 51, but no signal is input from the connection detector 57 at the front of the vehicle to the controller 51. At the same time, the controller 51 outputs a connection recognition signal to the controller 51 of the work vehicle 100 via the second port B of the connection connectors 58 and 158, and outputs the second port B from the controller 51 of the work vehicle 100. A connection recognition signal is input through the terminal. Thereby, the controller 51 of the work vehicle 200 recognizes that there is no connection of the other vehicle at the front part of the own vehicle and the rear part of the work vehicle 100 is connected to the rear part of the own vehicle, and the front-rear connection in the memory 52 is performed. It is recognized from the state table BT that the front and rear connection state = 0.

  Next, in each work vehicle, the number of connected vehicles (the total number of vehicles connected) and the connection number (connection order position) are input. At this time, in each vehicle, the worker selects and inputs the number of connected units (here, three units) by using a connected number selection volume (not shown) provided in the travel operation device 40 and is provided in the travel operation device 40. The connection number of the vehicle is selected and input by a connection order selection volume (not shown). The connection numbers are input in order from the beginning or the end of all connected vehicles. In the following description, as shown in FIG. 5, a case will be described in which the roadway working vehicle 1 is input as the first car, the roadway working vehicle 100 is input as the second car, and the roadway working vehicle 200 is input as the third car.

  In each work vehicle, when the detection of the front and rear connection state and the input of the number of connected units and the connection number are completed, a connection combination (a combination of front and rear connection states) is detected based on these information, and this combination is stored in the memory 52. It is determined whether or not it exists in the connected combination table VT. The controller 51 of each work vehicle detects the connection combination by combining the front and rear connection states detected in each vehicle in the order of the connection numbers input from the connection order selection volume of each vehicle, and the connection combination is the connection combination in the memory. It is determined whether or not it exists in the table VT. Here, the connection combination is {1, 3, 0} in order from the first car (work vehicle 1), and this combination exists in the connection combination table VT as indicated by an ellipse A in FIG.

  Thus, when a combination exists in the connection combination table VT, the controller 51 of each work vehicle permits the vehicle to travel. At this time, the operator can perform a traveling operation from any of the traveling operation devices 40 in the connected work vehicles 1, 100, 200. However, when the operation is started with any of the travel operation devices, the operation input by the other operation devices is restricted. In addition, a priority switch may be provided in each traveling operation device, and only the operation of the traveling operation device in which the priority switch is operated may be effective. In addition, the controller 51 of each work vehicle recognizes the direction (connection direction) of the host vehicle with respect to the operated vehicle from the detected connection combination information (connection direction of the connection combination table VT), and from this, a travel operation signal ( It is possible to determine which direction the host vehicle should proceed with respect to the command value), and it is possible to ensure that all the vehicles travel in the same traveling direction.

  In addition, when the railroad work vehicle 200 is input as the first car, the railroad work vehicle 100 is the second car, and the railroad work vehicle 1 is input as the third car, the combination is {0, 3, 1} in order from the first car (work vehicle 200). However, as indicated by an ellipse B in FIG. 6, this combination also exists in the linked combination table VT. Therefore, it is understood that the connection numbers may be input in order from the head or the tail of all the connected vehicles.

  For example, in the connection combination {1, 3, 0} described above, the traveling operation device 40 of the railroad work vehicle 100 (No. 2 car) is operated, and the direction in which the railroad work vehicle 1 (No. 1 car) becomes the head (in FIG. 3). When the connected vehicle is driven to the left), the controller 51 of each work vehicle uses the work vehicle 1 (No. 1 car) and the work vehicle that are “same symbols” from the connection combination information (the connection direction of the connection combination table VT). 100 (No. 2 car) is connected in the same direction, and it is determined that work vehicle 200 (No. 3 car) that is “different code” is connected to work cars 1 and 100 in the opposite direction.

  Then, after the power switch 41 is turned ON to enable the traveling operation by the traveling operation device 40, the parking brake operation lever 43 is operated and the left and right traveling hydraulic motors 16L and 16R are driven by the parking brake device 95. Release the lock. At this time, an off signal is input from the parking brake operation detector 43a to the controller 51 of each work vehicle, and in each work vehicle, the controller 51 causes the parking brake control valve 96 to connect the oil passage 85 and the oil passage 86. And hydraulic oil is supplied to the parking brake device 95 to unlock the iron wheel drive shafts of the left and right traveling hydraulic motors 16L and 16R.

  Further, when the parking brake operation lever 43 is operated, a signal for releasing the lock of the iron wheel drive shafts of the left and right traveling hydraulic motors 16L and 16R by the parking brake device 95 from the parking brake operation detector 43a is sent to the controller 51 of each work vehicle. In each work vehicle, the controller 51 turns on the headlights 14 and 114 and the taillight / brake lights 18 and 118 in the host vehicle. At this time, in each work vehicle, the controller 51 outputs a warning control signal to the start buzzers 19 and 119 in the own vehicle, and generates a warning sound from the start buzzers 19 and 119.

  When the parking brake operating lever 43 is operated in this way and the lock of each traveling hydraulic motor by the parking brake device 95 is released, that is, when the track work vehicle 1, 100, 200 (connected vehicle) is to be started ( Since all the headlamps 14 and 114 and tail and brake lights 18 and 118 in the connected vehicle are turned on immediately before the start of the connected vehicle), an alarm sound is generated by the start buzzers 19 and 119. In addition, it is possible to notify the worker who is between the vehicles and the worker in the traveling direction side of the vehicle that the connected vehicle starts, and to urge the worker to leave the connected vehicle, thereby improving the safety for the worker. be able to.

  For example, when the headlamps 14 and 114 and the tail lamps and brake lamps 18 and 118 are already lit at night or the like, the controller 51 of each work vehicle has the headlamps 14 and 114 in its own vehicle. Then, a blinking control signal is output to the taillight / brake lights 18, 118, and the headlights 14, 114 and the taillight / brake lights 18, 118 are blinked. Alternatively, the controller 51 of each work vehicle outputs a high / low switching control signal to each of the headlamps 14 and 114, and switches between a high beam (horizontal illumination) and a low beam (lower illumination) at the headlamps 14 and 114. Passing that turns on alternately is performed. Thus, when the track work vehicle 1,100,200 (connected vehicle) is about to start, the headlights 14,114 and the taillight / brake lights 18,118 are blinked, or the headlights 14,114 In addition to performing passing, an alarm sound is generated by the start buzzers 19 and 119, so that the headlamps 14 and 114 and the taillight / brake lights 18 and 118 are already lit at night. Moreover, it can alert | report that a connection vehicle starts to the worker who exists around a connection vehicle.

  The tail and brake lights 18 and 118 are also configured to be able to switch between high beam and low beam so that when passing through the headlights 14 and 114, the tail and brake lights 18 and 118 also have high and low beams. It is also possible to perform passing that switches on and turns on alternately.

  When the headlamps 14 and 114 and the taillight / brake lights 18 and 118 are turned on, blinking, or passing when trying to start such a connected vehicle, the predetermined time has elapsed from the start of these controls, or the connected vehicle. Is started until the vehicle reaches a predetermined speed, and after the predetermined time has elapsed or when the predetermined speed is exceeded, the original state is controlled. That is, before the parking brake operation lever 43 is operated, if the headlights 14 and 114 and the taillight / brake lights 18 and 118 are not lit, the predetermined time has elapsed or the predetermined speed is reached. When the headlamps 14 and 114 and the taillight / brake lights 18 and 118 are extinguished and the headlamps 14 and 114 and the taillight / brake lights 18 and 118 are already lit, After a predetermined time has elapsed or when the speed exceeds the predetermined speed, the headlamps 14 and 114 and the tail / brake lights 18 and 118 are turned on.

  When the lock of each traveling hydraulic motor by the parking brake device 95 is released in each work vehicle, the traveling speed setting dial 42 is then twisted to set a desired maximum speed. At this time, a set maximum speed signal is input from the speed setting operation detector 42a to the controller 51 of each work vehicle. Then, the traveling operation lever 44 is tilted forward or backward. At this time, information on the operation state (the operation direction and the operation amount with reference to the neutral position) of the travel operation lever 44 is input from the travel operation detector 44a to the controller 51 of each work vehicle. An operation control signal corresponding to the amount of tilting operation of the travel operation lever 44 is output to the swash plate control actuator 62 within a range from zero speed to the maximum speed set by the travel speed setting dial 42, and the swash plate of the travel hydraulic pump 61 is output. The hydraulic oil is supplied from the traveling hydraulic pump 61 and the left and right traveling hydraulic motors 16L and 16R rotate. That is, the iron wheels 15 and 115 are rotated by the left and right traveling hydraulic motors 16L and 16R, and the track-and-rail work vehicles 1, 100 and 200 (connected vehicles) travel on the track R.

  When the travel operation lever 44 is tilted forward, a forward travel operation signal is input from the travel operation detector 44a to the controller 51 of each work vehicle, and in each work vehicle, the controller 51 advances the vehicle to the swash plate control actuator 62. In this manner, an operation control signal for tilting the swash plate of the traveling hydraulic pump 61 is output. Further, when the traveling operation lever 44 is tilted rearward, a reverse traveling operation signal is input from the traveling operation detector 44a to the controller 51 of each work vehicle, and in each work vehicle, the controller 51 causes the swash plate control actuator 62 to move the vehicle backward. In this manner, an operation control signal for tilting the swash plate of the traveling hydraulic pump 61 is output.

  The traveling speed of the railroad work vehicles 1, 100, 200 (connected vehicles) changes the tilt angle of the swash plate of the traveling hydraulic pump 61 by changing the operation amount (tilting amount) of the traveling operation lever 44. It is controlled by changing the flow rate of the hydraulic oil discharged from the hydraulic pump 61 and supplied to the left and right traveling hydraulic motors 16L, 16R. The travel speed of the connected vehicle is a speed corresponding to the operation amount of the travel operation lever 44 within a range from zero speed to the maximum speed set by the travel speed setting dial 42.

  Even in such a connected vehicle, the operator can switch between the high-speed driving mode and the low-speed driving mode by operating the driving mode changeover switch 45. Because the hydraulic circuit configuration and the operation control are the same as those in the case where the above-described track-and-rail work vehicle 1 travels alone, detailed description thereof is omitted here.

  Although the embodiment according to the present invention has been described so far, the scope of the present invention is not limited to that shown in the above-described embodiment. For example, in the above-described embodiment, it is determined that the time when the parking brake operation lever 43 is operated and the lock of each traveling hydraulic motor by the parking brake device 95 is released is the time when the track work vehicle is about to start. Thus, the headlamp, tail lamp and brake lamp are turned on. However, instead of when the parking brake operation lever 43 is operated, for example, when the power switch 41 is turned on, or when there is a time lag from when the traveling operation lever 44 is tilted to when the vehicle actually starts. Is configured to turn on the headlight and taillight / brake light, etc., by judging when to start the railroad work vehicle based on other judgment criteria, such as when the traveling operation lever 44 is tilted. May be.

  Further, in the above-described embodiment, when the track-and-work vehicle 1 is about to start, both the headlamp 14 and the tail lamp / brake lamp 18 are turned on. What is necessary is just to comprise so that at least one illumination lamp among the tail lamps and the brake lights 18 may be lighted. Also, in the connected vehicle, all the headlights 14 and 114 and the taillight / braking lights 18 and 118 are configured to be turned on. However, all the headlights 14 and 114 and the taillight / brake lights in the connected vehicle are used. What is necessary is just to comprise so that at least 1 illuminating lamp among 18 and 118 may be lighted. If comprised in this way, it can alert | report that a vehicle starts to the operator who exists in the circumference | surroundings of a vehicle, and can be encouraged to leave | separate from a vehicle.

Moreover, in the track-and-work vehicle 1 and the connected vehicle, for example, the travel operation lever does not have a function of switching the vehicle forward and backward, and the vehicle operation direction is set in accordance with the operation amount of the travel operation lever set by the forward / reverse switch. When the vehicle is configured to travel at a traveling speed, the traveling direction of the vehicle is detected based on a forward / reverse switching signal input from a forward / reverse switching switch (forward / reverse switching detector), and is thus detected. Alternatively, only the illumination lamp on the traveling direction side of the vehicle may be turned on. At this time, the forward / reverse changeover switch (forward / reverse changeover detector) functions as a traveling direction detection means for detecting the traveling direction of the vehicle. If comprised in this way, it can alert | report more reliably that the vehicle starts with respect to the worker who exists in the advancing direction side of a vehicle. As the traveling direction detection means, when the traveling operation lever has a function of switching the vehicle forward and backward as in the above-described embodiment, the traveling direction of the vehicle is determined based on the operating direction of the traveling operation lever. You may comprise so that it may detect.

  In the above-described embodiment, when the illuminating lamp and the tail lamp / braking lamp are already lit, the illuminating lamp and the tail lamp / braking lamp are configured to blink or pass. In a state in which is turned off, the illumination light and the tail light / braking light may be blinked or passed when the track work vehicle is about to start.

  Further, in the above-described embodiment, when the track work vehicle is about to start, the headlight and taillight / braking light are turned on and the warning sound is generated by the start buzzer. You may comprise so that only any one of lighting of an illumination lamp etc. and generation | occurrence | production of an alarm sound may be performed. Or you may comprise so that the switch means which can be switched so that only any one of lighting of an illumination lamp, etc. and generation | occurrence | production of an alarm sound may be provided. In addition, when the warning sound is generated by the start buzzer, a different warning sound may be generated from the start buzzer depending on whether the vehicle traveling direction is forward or reverse. For example, the traveling direction of the vehicle can be notified to the operator by the difference in the warning sound.

  In the above-described embodiment, the headlamp and the tail lamp / braking lamp are turned on when the track work vehicle is about to start. For example, an auxiliary lamp (fog lamp), a direction indicator (blinker), a vehicle width lamp (small lamp), and a start notification lamp separately provided on the vehicle body are turned on. You may comprise.

  Moreover, although the above-mentioned embodiment demonstrated the railroad working vehicle as an example of the track traveling vehicle to which this invention is applied, this invention is not limited to a railroad working vehicle, The track | truck which can drive | work on a track | orbit The present invention can be applied to any traveling vehicle.

1,100,200 Railroad work vehicle (orbital vehicle)
10,110 traveling body (vehicle body)
14,114 Headlight (front illumination means)
15,115 Iron wheel (wheel)
18,118 Taillight / braking light (rear lighting)
19,119 Start buzzer (alarm sound generating means)
40 travel operation device 50 travel control device 51 controller (lighting control means, alarm sound control means)
56,156 Connection means 57,157 Connection detection means

Claims (9)

A vehicle having a vehicle body having a plurality of wheels capable of traveling on a track and capable of traveling on the track,
A front illumination means provided at a front portion of the vehicle body for illuminating the front of the vehicle body;
A rear illumination means provided at a rear portion of the vehicle body for illuminating the rear of the vehicle body;
Vehicle start detection means for detecting the start of the vehicle;
Illumination control means for turning on at least one of the front illumination means and the rear illumination means when the vehicle start detection means detects the start of the vehicle ,
The front illumination means is configured to be able to illuminate by switching between horizontal illumination and downward illumination,
The lighting control means performs passing to alternately turn on the horizontal illumination and the lower illumination when the front illumination means is turned on when the vehicle start detection means detects the start of the vehicle. Orbital vehicle. Providing traveling direction detection means for detecting the traveling direction of the vehicle,
The illumination control means is an illumination means on the traveling direction side of the vehicle detected by the traveling direction detection means among the front illumination means and the rear illumination means when the vehicle start detection means detects the start of the vehicle. The track traveling vehicle according to claim 1, wherein: Alarm sound generating means provided on the vehicle body for generating an alarm sound;
3. An alarm sound control means for operating the alarm sound generating means to generate an alarm sound when the vehicle start detecting means detects the start of the vehicle. Orbital vehicle described in 1. A vehicle body, a plurality of wheels that can travel on a track provided in the vehicle body, and a connecting means that is provided at a front portion and a rear portion of the vehicle body, respectively, and is connected to another vehicle. In a track traveling vehicle capable of traveling on a track with the vehicles connected,
Each of the plurality of track traveling vehicles connected by the connecting means is provided at a front portion of the vehicle body to illuminate the front of the vehicle body, and is provided at a rear portion of the vehicle body to illuminate the rear of the vehicle body. Detected by a back lighting means, a connection detecting means for detecting whether or not another vehicle is connected in the connecting means, and which one of the front part and the rear part of the other vehicle is connected, and detected by the connection detecting means Communication means for transmitting vehicle connection information between a plurality of track traveling vehicles connected by the connection means;
In a state where a plurality of the connected track traveling vehicles are connected by the connecting means and the connection is detected by the connection detecting means, a vehicle start detecting means for detecting the start of the connected vehicle, and a vehicle connected by the vehicle start detecting means. An orbital traveling vehicle comprising: an illumination control unit that turns on at least one of the front illumination unit and the rear illumination unit in the connected vehicle when the start of the vehicle is detected. . Providing traveling direction detection means for detecting the traveling direction of the connected vehicle,
The lighting control means detects the progress of the vehicle detected by the traveling direction detection means among the front lighting means and the rear lighting means in each vehicle when the vehicle start detection means detects the start of the connected vehicle. 5. The track traveling vehicle according to claim 4 , wherein the illuminating means on the direction side is turned on. Said lighting control means, when detecting the start of the articulated vehicle by the vehicle start detection means, according to claim 4, characterized in that turning on all of the front lighting unit and the back-illumination means in combination vehicle Orbital vehicle. The track traveling vehicle according to any one of claims 4 to 6 , wherein the illumination control unit blinks the illumination unit when the vehicle start detection unit detects the start of the connected vehicle. The front illumination means is configured to be able to illuminate by switching between horizontal illumination and downward illumination,
The lighting control means, when detecting the start of the connected vehicle by the vehicle start detection means, performs lighting that alternately turns on the horizontal illumination and the lower illumination when the front illumination means is turned on. The track vehicle according to any one of claims 4 to 6 . A warning sound generating means for generating a warning sound;
5. An alarm sound control means for operating the alarm sound generating means to generate an alarm sound when the vehicle start detecting means detects the start of a connected vehicle . The track vehicle according to any one of 8 .

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