JP2016057209A - Vehicle inspection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicle inspection device that can inspect a wide variety of vehicles and shorten inspection time.SOLUTION: A vehicle inspection device comprises a fixing unit having a first support part where a pair of right and left wheels of an inspection vehicle is placed and supported rotatably on the spot, and a movable unit provided rearward of the fixing unit in the travel direction of the inspection vehicle to be movable in the direction approaching to/separating from the fixing unit and having a second support part where the pair of right and left wheels of the inspection vehicle is placed and supported rotatably and a third support part rearward of the second support unit where the pair of right and left wheels of the inspection vehicle is placed and supported rotatably.SELECTED DRAWING: Figure 1

Description

  Embodiments of the present invention relate to a vehicle inspection apparatus installed in an automobile inspection place (hereinafter simply referred to as an automobile inspection place) that inspects and authenticates an automobile.

  An inspection device for inspecting automobile brakes and speedometers is installed at the vehicle inspection site. This type of inspection device includes a plurality of support portions on which the wheels of the inspection vehicle are mounted, and can rotate and stop only the wheels on the spot without running the vehicle. A general vehicle inspection apparatus has a movable unit provided with one support part that can be attached to and detached from a fixed unit provided with one support part. The movable unit is moved toward and away from the fixed unit according to a different wheel base depending on the vehicle to be inspected.

  In such an inspection apparatus, when the wheel base of the vehicle inspected first and the wheel base of the vehicle to be inspected after that are significantly different, it is necessary to move the movable unit relative to the fixed unit. For this reason, when such an inspection apparatus is used, it takes time to move the movable unit, and the total inspection time when inspecting a plurality of vehicles having different wheel bases becomes long.

  Therefore, as a solution, a vehicle inspection apparatus combining three support portions has been proposed. Specifically, a vehicle inspection apparatus having a fixed unit including two support portions and a movable unit including a single support portion provided in front of the moving direction of the inspection vehicle so as to be detachable from the fixed unit. Are known.

  This vehicle inspection apparatus can shorten the moving distance of the movable unit as compared with a vehicle inspection apparatus in which two inspection units are combined. For this reason, the total inspection time for continuously inspecting a plurality of vehicles can be shortened.

JP 2013-160746 A

  However, in the inspection apparatus having the fixed unit having the two support portions described above, it is necessary to put a front tire on the movable unit whose position is being adjusted in order to improve working efficiency. However, the operation of placing the front tire on the movable unit whose position is being adjusted is difficult and requires familiarity. And in the work by an unfamiliar operator, there is a possibility that the front tire may come off from the movable unit if there is a deficiency in overcoming the movable unit that comes toward the vehicle or how to put the tire on the movable unit. For this reason, the set time of the inspection vehicle is generated extra, and the total inspection time may be increased accordingly.

  Therefore, it is desired to develop a vehicle inspection apparatus that can set the inspection vehicle safely and accurately and can reduce the inspection time of the inspection vehicle.

  The vehicle inspection apparatus according to the embodiment includes a fixed unit including a first support portion that supports a pair of left and right wheels of the inspection vehicle and rotatably supports the vehicle on the spot, and the movement of the inspection vehicle relative to the fixed unit. A second support part which is provided so as to be movable in a direction to come in contact with and away from the fixed unit at the rear of the direction, and which rotatably supports the pair of left and right wheels of the inspection vehicle, and the inspection at the rear of the second support part And a movable unit including a third support portion that rotatably supports a pair of left and right wheels of the vehicle.

FIG. 1 is a plan view of the vehicle inspection apparatus according to the embodiment. FIG. 2 is a side view of the vehicle inspection apparatus of FIG. 3 is a cross-sectional view taken along the line AA of the vehicle inspection apparatus of FIG. FIG. 4 is a schematic view of a speed roller of the vehicle inspection apparatus of FIG. FIG. 5 is a schematic view showing a torque application mechanism installed in the fixed unit of the vehicle inspection apparatus of FIG. 6 is a schematic view showing a gear structure of a brake roller of the vehicle inspection apparatus of FIG. FIG. 7 is an explanatory diagram for explaining a driving method of the vehicle inspection apparatus of FIG. 1. FIG. 8 is an explanatory diagram for explaining a method of inspecting a biaxial vehicle using the vehicle inspection apparatus of FIG. 1. FIG. 9 is an explanatory diagram for explaining a method of inspecting a three-axis vehicle using the vehicle inspection device of FIG. 1. FIG. 10 is an explanatory diagram for explaining a method of inspecting a four-axis vehicle using the vehicle inspection device of FIG. 1. FIG. 11 is a control block diagram of the vehicle inspection apparatus of FIG.

  Hereinafter, the structure of the vehicle inspection apparatus 1 according to the embodiment will be described with reference to the drawings.

  The vehicle inspection device 1 is one of inspection devices arranged along with an exhaust gas inspection device, a headlight inspection device, a side slip inspection device, and the like on an inspection line of a vehicle inspection site. The inspection vehicle is sequentially subjected to various inspections using these inspection devices arranged on the inspection line.

  As shown in FIGS. 1 and 2, the vehicle inspection apparatus 1 is installed by being embedded in a hole (hereinafter referred to as a pit) provided on the floor surface of the vehicle inspection site. The vehicle inspection apparatus 1 includes a fixed unit 20 in front of the moving direction P of the inspection vehicle, and includes a movable unit 30 behind the fixed unit 20. In the following description, the moving direction P of the inspection vehicle is the front, and the direction opposite to the moving direction P is the rear.

  First, the fixed unit 20 will be described.

  The fixed unit 20 includes a first support portion 22 that rotatably supports the left and right tires of the inspection vehicle, a lateral flow prevention mechanism 40 for preventing the inspection vehicle from moving left and right during the inspection, And an inertial weight addition mechanism 60 that applies a rotational load to the tire.

  The first support portion 22 of the fixed unit 20 is arranged according to the height of the floor surface of the vehicle inspection site, and has an appropriate depth so that the unevenness is reduced when the inspection vehicle enters the first support portion 22. It is buried in the pit.

  The first support portion 22 includes a roller unit 24 and a roller unit 26 on which the left and right tires of the inspection vehicle are placed. The tire on the left side in the moving direction P of the inspection vehicle is put on the roller unit 24. The right tire of the inspection vehicle is placed on the roller unit 26.

  The roller unit 24 includes a speed roller 24 a disposed in front of the moving direction P and a brake roller 24 b disposed rearward in the moving direction P. The roller unit 26 includes a speed roller 26 a disposed in front of the moving direction P and a brake roller 26 b disposed rearward in the moving direction P.

  The speed roller 24a and the speed roller 26a are disposed coaxially and are connected via a clutch 21a and a coupling 21b.

  For example, in the brake inspection, it is necessary to measure the brake performance of each tire. Therefore, the clutch 21a disconnects the speed roller 24a and the speed roller 26a, and rotates the speed roller 24a and the speed roller 26a independently.

  Further, in the speed inspection, it is necessary to make the rotation speeds of both wheels of the inspection vehicle the same. Therefore, the clutch 21a connects the speed roller 24a and the speed roller 26a to rotate integrally.

  The fixed unit 20 is connected to a lateral flow prevention mechanism 40 and an inertial weight addition mechanism 60.

  The lateral flow prevention mechanism 40 includes a rod-shaped member, a cylinder, and a spring (not shown). When the inspection vehicle enters the fixed unit 20, the lateral flow prevention mechanism 40 extends the rod-shaped member from both sides toward the tire. Thereby, the lateral flow prevention mechanism 40 prevents the inspection vehicle from moving left and right during the inspection by supporting the tire from the side surface. The details of the structure of the inertial weight addition mechanism 60 will be described later.

  Next, the movable unit 30 will be described.

  As shown in FIGS. 1 and 2, the movable unit 30 includes a second support portion 32 and a third support portion 34. The 2nd support part 32 and the 3rd support part 34 are attached to the movable frame 36a, and can move integrally. The second support part 32 and the third support part 34 are arranged side by side behind the fixed unit 20 and are movable in a direction in which they are separated from and in contact with the fixed unit 20.

  The movable unit 30 is disposed on a pedestal rail 36b provided on a pedestal 36c in the pit (FIG. 2). Note that the pedestal rail 36b has two rails arranged behind the fixed unit 20 along the moving direction P of the vehicle. Similar to the fixed unit 20, the movable unit 30 has an appropriate depth in the pit so as to be uneven enough to prevent the inspection vehicle from entering the inspection device according to the height of the floor of the vehicle inspection site. Buried in

  The second support portion 32 includes a roller unit 33 and a roller unit 35 on which the left and right tires of the inspection vehicle are placed. The left tire in the moving direction of the inspection vehicle is placed on the roller unit 33. The right tire of the inspection vehicle is placed on the roller unit 35.

  The roller unit 33 includes a speed roller 33a disposed in front of the moving direction P and a brake roller 33b disposed rearward in the moving direction P. The roller unit 35 includes a speed roller 35a disposed in front of the moving direction P and a brake roller 35b disposed rearward in the moving direction P.

  The speed roller 33a and the speed roller 35a are disposed coaxially and are connected via the clutch 21a. A convex portion 38 is provided at the outer end of the roller unit 33 and the roller unit 35. The convex portion 38 is provided with a lamp 106 (see FIG. 11) for indicating to the driver a roller unit on which the tire of the inspection vehicle is placed at a position that can be confirmed from the driver's seat of the inspection vehicle using a mirror or the like.

  Similarly, convex portions 38 are provided on the outer ends of the roller unit 37 and the roller unit 39. The convex portion 38 is provided with a lamp 106 (see FIG. 11) for indicating to the driver a roller unit on which the tire of the inspection vehicle is placed at a position that can be confirmed from the driver's seat of the inspection vehicle using a mirror or the like.

  Further, a ramp 106 is similarly provided on the upper surface of the cross current preventing device 40 provided at the outer ends of the roller unit 24 and the roller unit 26. The lamp 106 emits light so as to indicate the inspection unit on which the tire of the inspection vehicle should be placed.

  That is, the ramp 106 is provided at the outer end of all the roller units 24, 26, 33, 35, 37, 39. That is, the lamps 106 are arranged at six locations.

  The third support portion 34 includes a roller unit 37 and a roller unit 39 for placing the left and right tires of the inspection vehicle. The left tire in the moving direction of the inspection vehicle is placed on the roller unit 37. The right tire of the inspection vehicle is placed on the roller unit 39.

  The roller unit 37 includes a speed roller 37a disposed in front of the moving direction P and a brake roller 37b disposed rearward in the moving direction P. The roller unit 39 includes a speed roller 39a disposed in front of the moving direction P and a brake roller 39b disposed rearward in the moving direction P.

  The speed roller 37a and the speed roller 39a are disposed coaxially and are connected via the clutch 21a. A convex portion 38 is provided at the outer end of the roller units 37 and 39. The convex portion 38 is provided with a lamp 106 (see FIG. 11) for indicating to the driver a roller unit on which the tire of the inspection vehicle is placed at a position that can be confirmed from the driver's seat of the inspection vehicle. The lamp 106 emits light so as to indicate an inspection unit on which the tire of the inspection vehicle should be put.

  In the present embodiment, one roller of the roller unit is called a speed roller and the other is called a brake roller. However, both rollers are provided with a drive mechanism and a brake mechanism. For this reason, both rollers can function as both driving and braking.

  Next, the roller synchronizer 200 that connects the speed roller 26a of the roller unit 26, the speed roller 35a of the roller unit 35, and the speed roller 39a of the roller unit 39 will be described.

  As shown in FIGS. 1 and 2, the speed roller 26 a and the speed roller 35 a include a plurality of pulleys 201, 202, 203, 204, 205, 206, 207, 208 and toothed belts 211, 212 that connect these pulleys. , 213, 214, 215, 216. In the present embodiment, a pulley and a toothed belt are used as the power transmission mechanism. However, for example, a V belt or a flat belt may be used as another power transmission means.

  The pulley 202 connected to the speed roller 26 a via the toothed belt 211 and the pulley 205 connected to the speed roller 35 a of the roller unit 35 via the toothed belt 214 are connected via a connecting arm 210. . The connecting arm 210 has a structure in which one end of two rod-like members are connected by a pulley 203 so as to be rotatable. In addition, pulleys 202 and 203 and a pulley 205 are rotatably provided at the end of the connecting arm 210. For this reason, even if the movable unit 30 moves, the toothed belts 212 and 213 do not loosen.

  The speed roller 39a of the roller unit 39 is coaxially connected to the pulley 208. The pulley 208 and the pulley 207 are connected by a toothed belt 216. The pulley 207 is connected to the pulley 205 by a toothed belt 215. Thereby, the rotation of the speed roller 26 a of the roller unit 26 is transmitted to the speed roller 39 a of the roller unit 39 by the roller synchronization unit 200.

  The speed roller 26 a of the roller unit 26 and the speed roller 35 a of the roller unit 35 can be selected to be connected or disconnected by the clutch 27 disposed in the roller synchronization unit 200.

  Similarly, the speed roller 26 a of the roller unit 26 and the speed roller 39 a of the roller unit 39 can be selected to be connected or disconnected by the clutch 27 disposed in the roller synchronization unit 200.

  Since the clutch 27 can select whether the roller tuning unit 200 and the speed rollers 35a and 39a are connected or disconnected, the roller unit to be used can be selected in accordance with the type of inspection. For example, in the inspection in which the tires of the inspection vehicle are put on the first support portion 22 and the second support portion 32 and the speed rollers 37a and 39a of the third support portion 34 are not used, the speed roller 39a of the third support portion 34 and Disconnect the connection. The vehicle inspection apparatus 1 can inspect only the speed roller 26 a of the first support portion 22 and the speed roller 35 a of the second support portion 32 that are necessary for the inspection by connecting them with the roller synchronization portion 200. For this reason, the vehicle inspection apparatus 1 according to the present embodiment is safe because a roller unit that is not used for inspection does not rotate. Furthermore, the vehicle inspection apparatus 1 can reduce the power required without the roller unit unnecessary for inspection rotating.

  In the vehicle inspection apparatus 1 of the embodiment, as shown in FIG. 1, a mechanism (roller tuning unit 220) similar to the roller tuning unit 200 can be preliminarily disposed on the opposite side. By providing the roller tuning portions 200 and 220 on the left and right, even when there is a problem with one roller tuning portion, the movement of the movable unit 30 can be ensured by starting the other roller tuning portion.

  Next, the structure of the brake rollers 24b and 26b will be described with reference to FIG. 1, FIG. 2, and FIG. Since the brake rollers 24b and 26b and the brake rollers 33b, 35b, 37b, and 39b have the same structure, only the brake rollers 24b and 26b will be described as a representative here.

  As shown in FIGS. 1 and 6, the brake rollers 24 b and 26 b provided inside the guide rails 10 and 11 are rotatably held by an inner frame (not shown) in the vicinity of both ends of the rotating shaft 84. Yes. A gear box 81 and a clutch 82 are attached to the outer end of the rotating shaft 84.

  The gear box 81 is connected to the electric motor 71 by a connecting belt 83. As the clutch 82, for example, a so-called one-way clutch is used.

  In the vehicle inspection apparatus 1 of the present embodiment, the gear box 81 connected to the brake rollers 24b and 26b is arranged coaxially with the brake rollers 24b and 26b, so that the gear box 81 and the clutch 82 can be arranged near the floor surface. Access to the gear box 81 and the clutch 82 is facilitated. Therefore, there is no need for an operator to enter under the roller units 24 and 26 to perform maintenance work on the gear box 81 and the clutch 82, and the workability is excellent.

  Next, the configuration of the mobile treads 50R and 50F will be described.

  As shown in FIG. 2, the movable unit 30 is provided to be movable in the front-rear direction (on the pedestal rail 36b) in the pit. A movable tread plate 50F is provided in front of the movable unit 30 in the moving direction. A movable tread plate 50 </ b> R is provided behind the movable unit 30 in the moving direction.

  As shown in FIG. 1, the vehicle inspection apparatus 1 includes a guide rail 10 on the left side in plan view along the front-rear direction of the pit, and a guide rail 11 on the right side in plan view. The left and right ends of each movable tread board 50F, 50R are slidably supported by these two guide rails 10 and 11 (see FIG. 3).

  Along the moving direction P, the front ends of the guide rails 10 and 11 are bent so as to fall toward the bottom of the pit behind the fixed unit 20. Similarly, the rear ends of the guide rails 10 and 11 are bent so as to fall toward the bottom of the pit near the rear end of the pit. That is, the guide rails 10 and 11 are bent in an inverted U shape.

  As shown in FIGS. 2 and 3, the mobile treads 50R and 50F have a structure in which a plurality of mobile tread units 50 are repeatedly connected in the moving direction. The structure of the movable tread unit 50 includes two large pipes 51 having a length extending between the guide rail 10 and the guide rail 11, and a small pipe 52 disposed below the two large pipes. And a tread plate 53 disposed on the traveling surface of the inspection vehicle so as to face the small pipe 52. The mobile treads 50R and 50F are configured by arranging a plurality of the mobile tread units 50 and connecting them with a connecting portion 55.

  Focusing on one mobile tread unit 50, rollers 54 for smoothly sliding the mobile tread 50F and the mobile tread 50R with respect to the guide rails 10 and 11 are attached to both ends of the large pipe 51. ing.

  The movable tread board unit 50 configured as described above is bent inward at an angle of about 90 degrees on the guide rail bent in an inverted U shape. Here, the mobile tread board unit 50 has a small pipe 52 arranged in a substantially inverted triangle below the large pipe 51 to reduce the turning radius when passing through the inverted U-shaped guide rail and to provide sufficient strength. Secured.

  Further, the movable tread board unit 50 is configured by combining the large pipe 51 and the small pipe 52 having a circular cross section so that the gap when the movable tread board unit 50 is bent can be minimized. .

  Thereby, the movable tread board unit 50 can prevent a foreign object from being caught in a gap between the inverted U-shaped portions of the guide rail and a peripheral portion such as a finger from being caught.

  For this reason, the mobile treads 50F and 50R according to the present embodiment have a structure in which a plurality of mobile tread units 50 are connected to each other, thereby maintaining sufficient strength to withstand passage of a vehicle of 10 tons with axle load. It is also effective in terms of safety.

  Here, the operation of the mobile treads 50R and 50F will be described below.

  When the movable unit 30 moves forward, the rear movable tread plate 50R slides on the guide rails 10 and 11 and is pulled out to the floor surface. As a result, most of the opening of the pit is closed by the movable unit 30 and the movable tread 50R.

  On the other hand, when the movable unit 30 moves rearward, the front movable tread 50F slides on the guide rails 10 and 11 and is pulled out to the floor surface. Similarly, the opening of the pit is closed by the movable unit 30 and the movable tread 50F. As the movable treads 50R and 50F are pulled out in the direction of closing the opening of the pit as the movable unit 30 moves back and forth, the opening is always closed. In addition, when one of the mobile treads 50F and 50R is exposed on the floor, the other is stored under the floor, so that the movement of the movable unit 30 is not hindered.

  Thus, since the opening of the pit is always closed by the movable treads 50F and 50R, the inspection vehicle can safely travel even when the movable unit 30 is moving.

  Furthermore, by using the above-described mobile tread unit 50, it is not necessary to install two mobile treads for each of the left and right tires of the inspection vehicle. That is, it is not necessary to provide another guide frame at the center of the pit and to provide two movable treads on which the left and right tires are respectively placed on the left and right sides of the guide frame.

  For this reason, the speed rollers 33a and 35a of the left and right roller units 33 and 35 of the movable unit 30 are connected in the same manner as the connection of the speed rollers 24a and 26a of the left and right roller units 24 and 26 of the fixed unit 20 (see FIG. 4). Can be coaxially connected via the coupling 21b and the clutch 21a. Similarly, the speed rollers 37a and 39a of the left and right roller units 37 and 39 of the movable unit 30 can be coaxially connected via the coupling 21b and the clutch 21a.

  Thereby, the coupling 21b and the clutch 21a can be disposed near the floor surface, and the coupling 21b and the clutch 21a can be easily accessed by removing the pit cover 90 of the vehicle inspection device 1. Therefore, it is easy to replace the parts of the coupling 21b and the clutch 21a, and the maintenance is excellent.

  In addition, since the clutch 21a is connected coaxially with the speed rollers 33a and 35a in the second support portion 32, the device configuration can be simplified and the number of parts can be reduced. Since the connection structure between the speed rollers 33a and 35a is simplified, the occurrence of a failure can be suppressed. Similarly, since the clutch 21a is connected coaxially with the speed rollers 37a and 39a in the third support portion 34, the device configuration can be simplified and the number of parts can be reduced. Since the connection structure between the speed rollers 37a and 39a is simplified, the occurrence of a failure can be suppressed.

  Further, since the clutch 21a is connected coaxially with the speed rollers 24a and 26a in the first support portion 22, the device configuration can be simplified and the number of parts can be reduced. Since the connection structure between the speed rollers 24a and 26a is simplified, the occurrence of failure can also be suppressed.

  Next, the inertia weight addition mechanism 60 connected with the fixed unit 20 of the vehicle inspection apparatus 1 will be described.

  The inertial weight addition mechanism 60 of the vehicle inspection apparatus 1 shown in the present embodiment is disposed in a pit further ahead of the fixed unit 20 (see FIG. 2).

  As shown in FIG. 5, the inertial weight addition mechanism 60 has two flywheels 61, two clutches 62, and two couplings 63 coaxially. A pulley 64 is provided at a substantially central portion of the inertial weight addition mechanism 60.

  On the other hand, a pulley 21 c is provided on the rotation shaft 84 of the speed roller 26 a of the first support portion 22. The pulley 64 and the pulley 21 c are connected by a connecting belt 25.

  Two clutches 62 are provided inside the two flywheels 61, and two couplings 63 are further provided inside.

  The inertia weight addition mechanism 60 is used, for example, when carrying out a speed inspection of a vehicle with a speed limiting device.

  When the driving tire of the inspection vehicle with the speed limiting device is put on the roller units 24 and 26 without using the inertia weight adding mechanism 60, and the engine is started and the driving tire is rotated, the roller units 24 and 26 become short. Rotate fast in time.

  For example, when a speed limiter of 90 km / h is attached, the speed limiter is activated when the speed reaches 90 km / h and stops driving the engine. In the inspection by the vehicle inspection device 1, the inertia including the vehicle weight does not work unlike road driving. For this reason, the control of the speed limiting device causes turbulence by repeating high-speed rotation and low-speed rotation, and the speed is not stable.

  Therefore, the vehicle inspection apparatus 1 connects the inertial weight addition mechanism 60 and the speed rollers 24a and 26a via the connecting belt 25 as shown in FIG. 5, and the inertial force of the flywheel 61 is connected to the speed rollers 24a and 26a. Can be added. And the vehicle inspection apparatus 1 makes the change of the speed of a tire gentle by the effect | action of the flywheel 61, and prevents disorder of a speed limiting device. By providing the inertial weight addition mechanism 60, the vehicle inspection apparatus 1 can moderate the speed change of the inspection vehicle and stabilize the control of the speed of the inspection vehicle.

  The two flywheels 61 are each attached to a rotating shaft 66 via a clutch 62. For this reason, the flywheel used according to the inertia weight required for an inspection vehicle can be selected. That is, both of the two flywheels 61 can be used by being connected to the rotating shaft 66, or can be used with one connected and the other disconnected. Of course, it is also possible to disengage the clutches 62 of both flywheels 61 (disengage the inertial weight addition mechanism 60 from the speed rollers 24a, 26a of the fixed unit 20). Also, the flywheel 61 can be replaced according to the weight of the inspection vehicle.

  In the inertial weight addition mechanism 60 of this embodiment, as shown in FIG. 2, a flywheel 61 is disposed immediately below a lid 90 that closes a pit. Therefore, the flywheel 61 can be easily accessed by removing the lid 90. For this reason, the exchange of the flywheel 61 is easy. In addition, the maintainability of the other clutch 62 and the coupling 63 is also good.

  Then, the control system which controls operation | movement of the vehicle inspection apparatus 1 of embodiment is demonstrated.

  As shown in FIG. 11, the control unit 100 of the vehicle inspection apparatus 1 controls the fixed unit 20, the movable unit 30, the inertia weight addition mechanism 60, and the roller tuning units 200 and 220. The control unit 100 also displays a camera 101 for confirming that the tire of the inspection vehicle is on the roller unit as instructed, and data from the camera 101 as an image, and provides information such as an explanation of the inspection process to the operator. A monitor 102 to be provided, an operation panel 103 that receives various operation inputs such as selection of inspection, various sensors 104, and roller units 24, 26, 33, 35, 37, and 39 on which the operator puts tires of the inspection vehicle. It is electrically connected to the lamp 106 for instructing and the pre-inspection device controller 105 in the previous process.

  Specifically, the control unit 100 controls the driving unit 71 a of the fixed unit 20 to operate the roller units 24 and 26 of the first support unit 22. Further, the actuator 72a is controlled to operate the clutch 21a. In addition, the control unit 100 controls the actuator 41 to operate the lateral flow prevention mechanism 40. Further, the control unit 100 controls the actuator 65 to operate the clutch 62 of the inertial weight addition mechanism 60.

  The control unit 100 controls the driving unit 71 b of the movable unit 30 to operate the roller units 33 and 35 of the second support unit 32. Further, the actuator 72b is controlled to operate the clutch 21a. Similarly, the control unit 100 controls the driving unit 71 c to operate the roller units 37 and 39 of the third support unit 34. Further, the actuator 72c is controlled to operate the clutch 21a.

  Further, the control unit 100 controls the driving unit 71 d to move the movable unit 30 in a direction in which it is separated from the fixed unit 20. More specifically, the control unit 100 acquires data related to the inspection vehicle from the previous inspection device control unit 105, and moves the movable unit 30 in accordance with the acquired wheel base data of the inspection vehicle.

  Then, the control unit 100 controls the actuator 271 to operate the roller tuning unit 200 and / or the clutch 27 of the 220.

  In addition, the control unit 100 acquires data of the inspection vehicle necessary for control of the fixed unit 20 and the movable unit 30 including the wheel base from the pre-inspection device control unit 105.

  Subsequently, a basic inspection process of the vehicle inspection apparatus 1 of the embodiment will be described.

  When performing an inspection, first, the operator inputs necessary vehicle information and an inspection item to be inspected on the operation panel 103. The necessary vehicle information is, for example, the vehicle type of the inspection vehicle (2-axle vehicle, 3-axle vehicle, 4-axle vehicle, etc.) and the drive shaft of the vehicle. In addition, the inspection items to be inspected can be selected from side slip inspection, brake inspection, speed inspection, and the like. After inputting the necessary items, the operator causes the inspection vehicle that has passed the previous inspection device to enter the vehicle inspection device 1 and moves it to the initial inspection position. Here, the initial inspection position refers to a position where the left and right tires of the inspection vehicle are placed on the first support portion 22.

  The control unit 100 guides the inspection vehicle based on the input information and the information on the inspection vehicle obtained from the previous inspection device control unit. Specifically, the control unit 100 turns on the lamp 106 provided at the end of the roller unit for setting the tire. Whether or not the left and right tires of the inspection vehicle are correctly set on the first support portion 22 of the fixed unit 20 is determined from signals from the plurality of sensors 104 arranged on the fixed unit 20 and images of the camera 101. When the tire of the inspection vehicle is correctly set on the first support portion 22, the control unit 100 displays on the monitor 102 that the tire is correctly set.

  At the same time, the control unit 100 acquires the data of the inspection vehicle from the pre-inspection apparatus control unit 105, and moves the movable unit 30 to an appropriate position based on various data and the type of inspection input via the operation panel 103. To do. The movement of the movable unit 30 can also be started from the time when the data related to the wheel base of the inspection vehicle is acquired from the previous inspection apparatus control unit 105. That is, the movable unit 30 can be moved while the operator moves the inspection vehicle to the initial inspection position.

  When the inspection vehicle is set to the initial inspection position, the control unit 100 drives the lateral flow prevention mechanism 40 to prevent the tire from sliding to the left and right if necessary based on the input data. The lateral flow prevention mechanism 40 is used particularly when the vehicle inspection apparatus 1 inspects a biaxial vehicle such as an ordinary passenger car. Furthermore, if necessary, the control unit 100 connects the inertial weight addition mechanism 60 and the fixed unit 20 using the clutch 62.

  The control unit 100 operates the clutch 27 of the roller tuning units 200 and 220 according to the inspection items necessary for the inspection vehicle. Specifically, in the case of an inspection using the first support portion 22 and the second support portion 32, the clutch 27 is controlled so that the third support portion 34 that is not used can be disconnected.

  As the drive means 71a, 71b, 71c, 71d, for example, an electric motor can be used, but a hydraulic motor or a pneumatic motor can be used for driving the roller unit instead.

  Then, the inspection process classified by vehicle type in the vehicle inspection apparatus 1 which concerns on this embodiment is demonstrated.

  As shown in FIG. 7, the vehicle inspection apparatus 1 according to this embodiment includes a fixed unit 20 at the front in the traveling direction and a movable unit 30 at the rear. The fixed unit 20 has a first support portion 22. And the movable unit 30 has the 2nd support part 32 and the 3rd support part 34 integrally with the movable frame 36a. The movable frame 36a is provided on the pedestal rail 36b.

  When the movable unit 30 is moved to the end of the movable range (shown state), the distance between the third support part 34 and the first support part 22 is 4000 mm. On the other hand, when the movable unit 30 is moved to the forefront of the movable range, the distance between them is 2575 mm. In addition, the distance between support parts said here is corresponded to the distance of the central axes of a wheel when each support part supports a wheel.

  When the movable unit 30 is moved to the end of the movable range, the distance between the second support portion 32 and the first support portion 22 is 2575 mm. On the other hand, the distance when the movable unit 30 is moved to the forefront of the movable range is 1150 mm.

  The moving stroke of the movable unit 30 is 1425 mm. The distance between the third support part 34 and the second support part 32 of the movable unit 30 is 1425 mm.

  For this reason, the vehicle inspection apparatus 1 can cope with wheel bases of various lengths from a bus having a wheel base of 4000 mm to a three-axis or four-axis vehicle such as a passenger car or a large truck.

  Furthermore, since the vehicle inspection apparatus 1 of this embodiment arrange | positions the 2nd support part 32 and the 3rd support part 34 continuously behind the 1st support part 22, not only 2 axis | shaft vehicle but 3 Even if the vehicle is a four-axis vehicle or a four-axis vehicle, the movement of the vehicle can be minimized (in this embodiment, once). In addition, since the vehicle inspection apparatus 1 can also reduce the amount of movement of the movable unit 30, the total inspection time can be shortened.

  Hereinafter, the vehicle inspection will be described with reference to FIGS. 8 to 10 as examples of the inspection vehicle of the two-axle to the four-axle.

  As shown in FIG. 8A, for example, when the vehicle inspection apparatus 1 inspects a passenger vehicle having the shortest wheelbase, the control unit 100 determines the wheel of the passenger car based on information from the previous inspection apparatus control unit 105. Confirm the base.

  The control unit 100 displays on the monitor 102 the tire T1 of the inspection vehicle to be put on the first support unit 22 of the fixed unit 20. The control unit 100 confirms the position of the tire T1 with the sensor 104 and the camera 101. Thereafter, the control unit 100 operates the lateral flow prevention mechanism 40 as necessary to restrict the lateral movement of the tire T1. In parallel with this operation, the control unit 100 moves the second support unit 32 to a position where the tire T2 of the inspection vehicle stops.

  Note that the control unit 100 can also start the movement of the movable unit 30 at the same time as acquiring the inspection vehicle data from the previous inspection device control unit 105.

  In this case, the movement of the movable unit 30 can be started before the inspection vehicle enters the vehicle inspection device 1. For this reason, the vehicle inspection apparatus 1 can reduce the waiting time until the start of inspection even when the moving distance of the movable unit 30 is long. In some cases, the operator of the inspection vehicle puts the tire T1 on the first support portion 22 of the fixed unit 20, and simultaneously puts the tire T2 on the second support portion 32 after the position of the tire T2 is adjusted. Since it can be placed, it is efficient.

  The control unit 100 starts a speed inspection and a brake inspection after confirming that all tires are on the first support unit 22 and the second support unit 32 based on a signal from the sensor 104 and an image from the camera 101.

  Next, the case of a large biaxial vehicle having a wheelbase length of 2575 mm to 4000 mm as shown in FIG.

  The control unit 100 confirms by the sensor 104 and the camera 101 that the tire T1 is placed on the first support portion 22 of the fixed unit 20 in the same manner as the above passenger car. In parallel with this operation, the control unit 100 moves the third support unit 34 to a position where the tire T2 of the inspection vehicle stops.

  Further, similarly to the passenger car, the control unit 100 can start the movement of the movable unit 30 at the same time as acquiring the inspection vehicle data from the pre-inspection device control unit 105.

  The control unit 100 confirms that the tire T1 of the inspection vehicle is mounted on the first support unit 22 and the tire T2 is mounted on the third support unit 34 from the signals of the camera 101 and the sensor 104, and then performs speed inspection and braking. Start the inspection.

  In the case of the biaxial vehicle as described above, the vehicle inspection apparatus 1 can perform speed inspection and brake inspection without moving the inspection vehicle after the inspection vehicle is set on the first support portion 22 of the fixed unit 20. .

  Next, an inspection method for a large multi-axle vehicle will be briefly described.

  As a large multi-axle vehicle, for example, a truck of a three-axis vehicle is shown in FIG. In addition, the driving wheel of the truck shown in the present embodiment is the front tire T2 of the two sets of wheels on the rear side of the truck.

  As shown in FIGS. 9A and 9B, the control unit 100 confirms that T <b> 1 of the inspection vehicle is set on the first support unit 22. In this state, the control unit 100 performs a brake inspection of the tire T1 of the inspection vehicle. Thereafter, the control unit 100 displays an instruction to move the position of the inspection vehicle on the operator on the monitor 102. The control unit 100 confirms from the signals from the camera 101 and the sensor 104 that the tire T2 of the inspection vehicle is set on the first support unit 22 of the fixed unit 20. The control unit 100 drives the movable unit 30 simultaneously with the instruction to move the position of the inspection vehicle. Then, the control unit 100 moves the second support unit 32 to a position where the tire T3 of the inspection vehicle stops.

  Note that the movable unit 30 can also start adjustment of the position of the movable unit 30 at the same time when the control unit 100 acquires the inspection vehicle data from the previous inspection apparatus control unit 105. By controlling in this way, it is possible to start moving the inspection vehicle immediately after the inspection of the tire T1 and to shorten the time until the inspection. In addition, the inspection vehicle only needs to be moved forward once, and the load on the operator is small and efficient. Moreover, the operator can easily align the tire T2 when the inspection vehicle is moved by using the fixed unit 20 as a mark. That is, since the position of the fixed unit 20 is always fixed, it is difficult for an operator to enter the vehicle too much to get over the roller unit or to cause an error such as the tire coming off after being set on the roller unit.

  Next, the case of a truck of a 4-axis vehicle as shown in FIGS. 10 (a) and 10 (b) will be considered.

  The truck shown in the embodiment shows a case where the two-wheel tires T3 and T4 of the rear wheels are drive wheels. The control unit 100 causes the monitor 102 to display the tire T <b> 1 of the inspection vehicle so as to be placed on the first support unit 22 of the fixed unit 20. The control unit 100 confirms the position of the tire T1 with the sensor 104 and the camera 101. And the control part 100 moves the 2nd support part 32 to the position where the tire T2 of an inspection vehicle stops.

  Note that the control unit 100 can also start the movement of the movable unit 30 at the same time as acquiring the inspection vehicle data from the previous inspection device control unit 105.

  In this case, the movement of the movable unit 30 can be started before the inspection vehicle enters the vehicle inspection device 1. For this reason, the operator of the inspection vehicle can put the tire T1 on the first support portion 22 of the fixed unit 20 and at the same time put the tire T2 on the second support portion 32 after the position of the tire T2 is adjusted. it can.

  The control unit 100 starts the brake inspection after confirming that the tire to be inspected is on the first support unit 22 and the second support unit 32 based on the signal from the sensor 104 and the image from the camera 101.

  Next, when the brake inspection of the tires T <b> 1 and T <b> 2 is completed, the control unit 100 displays an instruction to move the position of the inspection vehicle to the operator on the monitor 102. The operator moves the inspection vehicle in the movement direction P and puts the tire T3 on the first support portion 22 of the fixed unit 20. The control unit 100 confirms from the signals from the camera 101 and the sensor 104 that the tire T3 of the inspection vehicle is set on the first support unit 22 of the fixed unit 20. And the control part 100 moves the 2nd support part 32 to the position where the tire T4 of an inspection vehicle stops. Note that the control unit 100 can also start the movement of the movable unit 30 at the same time as acquiring the inspection vehicle data from the previous inspection device control unit 105.

  In this case, the movement of the movable unit 30 can be started before the inspection vehicle enters the vehicle inspection device 1. For this reason, the operator of the inspection vehicle can put the tire T3 on the first support portion 22 of the fixed unit 20 and at the same time put the tire T4 on the second support portion 32 after the position of the tire T4 is adjusted. it can.

  By controlling in this way, the inspection vehicle can start moving immediately after the inspection of the tires T1 and T2 is completed, and the time until the inspection can be shortened by the adjustment time of the position of the movable unit 30. In addition, the inspection vehicle only needs to be moved forward once, and the load on the operator is small and efficient.

  In this state, the control unit 100 performs a speed inspection and a brake inspection for the tires T3 and T4. Thus, the vehicle inspection apparatus 1 can perform the speed inspection and the brake inspection of all the tires T1 to T4 of the truck (four-axle vehicle) by one movement operation. In addition, since the fixed unit 20 is fixed, the operator can easily align the tire T3 when the inspection vehicle moves as described above.

  As described above, the vehicle inspection apparatus 1 of the present embodiment has the fixed unit 20 disposed in the front and the movable unit 30 disposed in the rear as a major feature. Therefore, the operator can position the tire by causing the inspection vehicle to enter the vehicle inspection apparatus 1 using the fixed unit 20 whose position does not change as a mark. Further, the control unit 100 can adjust the position of the movable unit 30 based on data from the pre-inspection device control unit 105 while the operator is performing the work of putting the tire to be inspected on the fixed unit 20. it can. Therefore, the vehicle inspection apparatus 1 hardly generates a waiting time for adjusting the position of the movable unit 30.

  The vehicle inspection apparatus 1 according to the present embodiment reduces the waiting time when the inspection vehicle enters and the waiting time when changing the inspection tire in the middle when the inspection vehicle having various types of wheelbases enters at random. In addition, the total inspection time can be shortened. Therefore, the vehicle inspection apparatus 1 can inspect more vehicles.

  Moreover, the vehicle inspection apparatus 1 has the lateral flow prevention mechanism 40 attached to the fixed unit 20 located in front. The lateral flow prevention mechanism 40 has a convex structure that protrudes further outward than the vehicle width. The lateral flow prevention mechanism 40 is for preventing the tire from rotating in conjunction with an inadvertent handle operation and moving the vehicle body from side to side during inspection. The lateral flow prevention mechanism 40 is usually provided in front of the vehicle inspection device. Here, in the vehicle inspection apparatus 1, since the first support portion 22 is fixed, the installation of the lateral flow prevention mechanism 40 is also simple.

  Further, the lateral flow prevention mechanism 40 is disposed so as to protrude in the short direction of the pit. For this reason, when the lateral flow prevention mechanism moves in the longitudinal direction of the pit, special consideration is necessary so that an operator or the like does not enter the movement line of the lateral flow prevention mechanism when moving. In the inspection apparatus 1, since the lateral flow prevention mechanism 40 is disposed in the fixed unit 20, it is not necessary.

  The present invention is not limited to the above embodiment. For example, as an example of the inspection vehicle in the present embodiment, a biaxial vehicle, a triaxial vehicle, and a 4-axle vehicle are listed, but a vehicle that can be tested is not limited thereto. The inspection vehicle data is acquired from the previous inspection apparatus control unit, but may be acquired by accessing a server or the like that collectively manages data obtained by various inspections. Of course, various modifications can be made without departing from the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Vehicle inspection apparatus, 10 ... Guide rail, 11 ... Guide rail, 20 ... Fixed unit, 22 ... 1st support part, 24 ... Roller unit, 26 ... Roller unit, 24a ... Speed roller, 26a ... Speed roller, 24b ... Brake roller, 26b ... Brake roller, 21a ... Clutch, 21b ... Coupling, 21c ... Pulley, 25 ... Connection belt, 201 ... Pulley, 202 ... Pulley, 203 ... Pulley, 204 ... Pulley, 205 ... Pulley, 206 ... Pulley, 207 ... Pulley, 208 ... Pulley, 27 ... Clutch, 271 ... Actuator, 200 ... Roller tuning unit, 211 ... Toothed belt, 212 ... Toothed belt, 213 ... Toothed belt, 214 ... Toothed belt, 215 ... Toothed Belt, 216 ... toothed belt, 30 ... movable unit, 32 ... second support, 33 ... b La unit, 35 ... roller unit, 33a ... speed roller, 35a ... speed roller, 33b ... brake roller, 35b ... brake roller, 34 ... third support, 37 ... roller unit, 39 ... roller unit, 36a ... movable frame, 36b: Pedestal, 36c: Pedestal rail, 38: Protruding part, 40 ... Side flow prevention mechanism, 41 ... Actuator, 50 ... Mobile tread unit, 50F, 50R ... Mobile tread, 51 ... Large pipe, 52 ... Small pipe, 53 ... Tread board, 54 ... Roll, 55 ... Connecting part, 60 ... Inertial weight addition mechanism, 61 ... Flywheel, 62 ... Clutch, 63 ... Coupling, 64 ... Pulley, 65 ... Actuator, 66 ... Rotating shaft, 71 ... Electric motor 71a ... Driving means, 71b ... Driving means, 71c ... Driving means, 71d ... Driving means, 72a ... Acti Eta, 72b ... actuator, 72c ... actuator, 81 ... gear box, 82 ... clutch, 83 ... connection belt, 84 ... rotary shaft, 90 ... lid, 100 ... control unit, 101 ... camera, 102 ... monitor, 103 ... operation panel , 104 ... sensor, 105 ... pre-inspection device controller, 106 ... lamp.

Claims (2)

A fixed unit provided with a first support portion that supports a pair of left and right wheels of the inspection vehicle and rotatably supports the vehicle on the spot;
A second support portion that is provided so as to be movable in a direction in which the inspection unit is separated from and in contact with the fixed unit at a rear side in the moving direction of the inspection vehicle, and that rotatably supports a pair of left and right wheels of the inspection vehicle. And a movable unit including a third support part that rotatably supports a pair of left and right wheels of the inspection vehicle behind the second support part,
A vehicle inspection apparatus.   The vehicle inspection apparatus according to claim 1, further comprising a control unit that adjusts a position of the movable unit based on vehicle data of the inspection vehicle.

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