JPH08313331A - Apparatus for measuring axle load - Google Patents

Abstract

PURPOSE: To precisely measure the axle load weight of a vehicle independently of the running speed of the vehicle. CONSTITUTION: Displacement in the vertical direction of a vehicle 32 is detected by an ITV camera 10 and according to the detected displacement, the acceleration of the vehicle 32 in the vertical direction is detected by a support measuring part 20. The load of the vehicle 32 loaded on a mounting plate 12 is detected by load cells 14, 16 and according to the load detected by the load cells 14, 16 and the acceleration of the vehicle 32, the axle load weight of the vehicle 32 is calculated by the support measuring part 20.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shaft load measuring device, and more particularly to a shaft load measuring device suitable for measuring the shaft weight of a vehicle such as an automobile.

[0002]

2. Description of the Related Art Traffic on highways tends to increase year by year, and road pain is becoming severe. For this reason, the axle load measuring device is indispensable for designing and maintaining the road such as strength of bridge girder and thickness of asphalt pavement while protecting the road by reducing the number of times of loading of vehicles with large axle weight.

Conventionally, as an axle load measuring device for measuring the axle weight of a traveling vehicle, one shown in FIG. 5 is known. Figure 5
In the axial load measuring device, the loading plate 50 and the load cell 5 are
2, connection box 54, instruction measuring unit 56, photography device 58,
The warning display device 60, the booth printer 62, and the personal computer 64 are provided.

Next, a conventional axial load measuring method in the above device will be described. When the vehicle 66 passes the 50 loading plates, the load of the vehicle 66 is detected by the load cell 52,
The detected load is input to the instruction measuring unit 56 via the connection box 54. The instruction measuring unit 56 measures the axle weight of the vehicle 66 based on the load, and the measurement result is output from the booth printer 62.

It is known that the main component of axial vibration when the vehicle 66 passes over the loading plate 50 is a sine wave of about 3 Hz as shown in FIG. 6 (a). The length of the loading plate 50 in the traveling direction of the vehicle is usually 800
Since it is designed to be about mm, assuming that the tire installation length of the passing vehicle 66 is 300 mm, the range in which the total load of the vehicle 66 is applied to the loading plate 50 is about 500 mm. Considering such a matter, the traveling speed of the passing vehicle 66 and the measurement time are represented as shown in FIGS. 6 (a) to 6 (d). 6A shows a vehicle 66 passing speed of 5 km / h, FIG. 6B shows a vehicle 66 passing speed of 10 km / h, and FIG. 6C shows a vehicle 66 passing speed of 15 km / h. ) Indicates that the passing speed of the vehicle 66 is 2
The shaft vibration waveforms at 0 km / h are shown. Then, in order to measure the sine wave of 3 Hz for one cycle or more, a measurement time of 330 ms or more is required. Further, from FIG. 6, the traveling speed at which the waveform of 3 Hz can be continued for one cycle or more is 5 km / h or less, and at the traveling speed higher than that, only a part of the vibration data can be continued.

[0006] Specifically, at a traveling speed of 10 km / h, 0.5
4 cycles, 0.36 cycles at 15km / h, 0.27 at 20km / h
It is a cycle, and in general, if a quarter cycle can be measured, the waveform can be reproduced. Therefore, in the conventional method, the fundamental frequency of the vibration and the position of the vibration measured are calculated from the direction and magnitude of the waveform inclination of 20 km / h or less, and only the vibration component is reproduced and calculated. , A dynamic correction processing method that subtracts this vibration component from the measured data is adopted. Furthermore, at traveling speeds of 20 km / h or more, the measurable vibration cycle becomes minute, and it is difficult to reproduce the vibration waveform from the measured data. Therefore, the peak value or average value of the measured data is used as the shaft weight. The method is adopted.

[0007]

In the conventional shaft load measuring method, the measurable vibration cycle is short when the traveling speed, which is the boundary point between the dynamic correction process and the peak value / average value process, is around 20 km / h. As the reproducibility of the vibration waveform due to the dynamic correction process deteriorates, the measurement error increases, and the running speed of the vehicle increases, it is not known which part of the vibration waveform was measured, and the peak value of the measurement data・ In the average value processing,
It is difficult to find the true value. Moreover, when the amplitude of the vertical movement of the vehicle is large, the measurement accuracy deteriorates significantly. Further, it is impossible to detect an error due to acceleration / deceleration of the vehicle and an error in vehicle vibration due to the unevenness of the road, which causes the measurement accuracy to deteriorate.

The present invention solves the above-mentioned conventional problems, and an object thereof is to provide an axle load measuring device capable of measuring the axle load of a vehicle regardless of the traveling speed of the vehicle.

[0009]

In order to achieve the above objects, the present invention detects a load detecting means for detecting a load due to traveling of a vehicle and an acceleration in a vertical direction of the vehicle due to an axial vibration of the vehicle. The axle load measuring device is provided with an acceleration detecting means and an axle weight calculating means for calculating the axle weight of the vehicle from the detection outputs of the load detecting means and the acceleration detecting means.

Further, according to the present invention, a load detecting means for detecting a load due to traveling of the vehicle, a displacement detecting means for detecting a vertical displacement of the vehicle due to an axial vibration of the vehicle, and a vehicle based on a detection output of the displacement detecting means. A shaft load measuring device including an acceleration detecting unit that detects an acceleration in the vertical direction of the vehicle, and a shaft weight calculating unit that calculates a shaft weight of a vehicle from a detection output of the load detecting unit and a detection output of the acceleration detecting unit. It is composed.

[0011]

According to the present invention, with the above structure, the load accompanying the traveling of the vehicle is detected, the vertical acceleration of the vehicle due to the axial vibration of the vehicle is detected, and the axial weight of the vehicle is calculated based on the load and the acceleration. Therefore, the axle load of the vehicle can be accurately measured regardless of the traveling speed of the vehicle.

[0012]

An embodiment of the present invention will be described below with reference to the drawings. (Embodiment 1) FIG. 1 is an overall configuration diagram showing an embodiment of the present invention. In FIG. 1, an axial load measuring device for measuring the axial load of a vehicle such as an automobile includes an ITV camera 10, a loading plate 12, a pair of load cells 14 and 16, a connection box 18, an instruction measuring unit 2
0, a photographing device 22, a warning display device 24, a booth printer 26, and a personal computer 28.

The ITV camera 10 is used as a vehicle height measuring device.
It is located above the vehicle 32 traveling on the road 30,
The displacement detecting means is configured to detect the displacement of the vehicle 32 in the vertical direction due to the axial vibration of the vehicle 32. The image signal captured by the ITV camera 10 is input to the instruction measuring unit 20. The loading plate 12 is buried near the toll of the road 30, is configured to receive the load of the traveling vehicle 32, and a pair of load cells 14 and 16 are arranged on the bottom surface side of the loading plate 12. Each load cell 14, 16 detects the load of the vehicle 32 applied to the loading plate 12 and outputs the detected load to the connection box 18. The connection box 18 is, as shown in FIG.
The detection loads of 4 and 16 are totaled, and a signal related to the total detected load is output to the instruction measuring unit 20.
The instruction measuring unit 20 synchronizes the image data picked up by the ITV camera 10 with the load data detected by the load cells 14 and 16, and at the same time, the vehicle 3 from the image data.
The acceleration in the vertical direction of the vehicle 32 due to the axial vibration of No. 2 is calculated, and the axial load of the vehicle 32 is calculated based on the calculated acceleration and load data. And the instruction measuring unit 2
The measurement result of 0 is output to each device.
That is, the vehicle 32 is photographed by the photographing device 22, the axle load is displayed on the warning display device 24, the warning about the additional loading and the information regarding the guidance are output to the booth printer 26, and the past data is displayed by the personal computer 28. Data processing is performed for storage and post analysis.

Next, the operation of the apparatus in the configuration will be described with reference to the flowchart of FIG. First, when the vehicle 32 approaches the loading plate 12 while the vehicle 32 is traveling on the road 30, it is determined whether the vehicle 32 has entered the sensing area of the ITV camera 10 (step S20). ,
When the vehicle 32 enters the sensing area of the ITV camera 10, the ITV camera 10 starts photographing the vertical displacement of the vehicle 32 (step S21). At this time, the measurement of the load is executed in parallel with the photographing of the vehicle 32. That is, the sensing area of the ITV camera 10 is the vehicle 32.
In the area including the loading plate 12 from the front in the traveling direction of, the photographing is continued until the vehicle 32 leaves the sensing area. Then, as the load applied to the loading plate 12 from the time when the wheels 34 of the vehicle 32 approach the loading plate 12 to the passage thereof,
The load including the shaft vibration is measured (step S22).
The load data measured here includes shaft vibration,
The vertical displacement of the vehicle 32 is extracted from the captured image of the ITV camera 10 by pattern recognition (step S2).
3) The instruction measuring unit 20 calculates the vertical acceleration of the vehicle 32 based on the vertical displacement (vertical direction) of the vehicle 32 (step S24). After that, the measured load data and the calculated acceleration data are synchronized (step S25) to calculate the axle weight of the vehicle 32 (step S26). From the calculation result, when the vehicle 32 is regarded as a violating vehicle due to additional loading, the booth printer 26 issues a warning and the personal computer 2
The vehicle 32 and the axle load data are recorded by 8, the axle display is displayed by the warning display device 24, and the violating vehicle is photographed by the photographing device 22.

As described above, according to this embodiment, the ITV camera 10 detects the vertical displacement of the vehicle 32, and based on this displacement, the vertical acceleration of the vehicle 32 is detected to detect the loading plate 12 and the load cell. Since the load of the vehicle 32 is detected by 14 and 16 and the axial load of the vehicle 32 is calculated based on the detected acceleration and the detected load, the axial load of the vehicle 32 is accurately measured regardless of the traveling speed of the vehicle 32. It can be measured. (Embodiment 2) FIG. 4 is an overall configuration diagram showing another embodiment of the present invention.

In this embodiment, instead of the ITV camera 10 shown in FIG. 1, ultrasonic vehicle detectors 36a, 36b ... 36 are used.
n, the integrated box 38 is provided, and the other configurations are the same as those in FIG. 1. Therefore, the same components as those in FIG. 1 are designated by the same reference numerals, and their description will be omitted.

The vehicle detectors 36a to 36n irradiate ultrasonic waves toward the vehicle 32, receive ultrasonic waves reflected from the vehicle 32, and detect vertical displacement of the vehicle 32 due to axial vibration of the vehicle 32. It is configured as a displacement detecting means that operates. Then, a signal regarding the displacement of the vehicle 32 detected by each of the vehicle detectors 36a to 36n is input to the instruction measuring unit 20 via the integrated box 38.

Next, the operation of the apparatus in this embodiment will be described. The vehicle 32 approaches the front of the loading plate 12, and the vehicle 3
When 2 enters the sensing area of the vehicle detector 36a, the vehicle detector 36a starts measuring the displacement of the vehicle 32 in the vertical direction. Then, when the vehicle 32 moves on the loading plate 12 due to the traveling of the vehicle 32, as the vehicle 32 moves,
The displacement (vehicle height) of the vehicle 32 in the vertical direction is measured by the vehicle detectors 36a to 36n. Each vehicle detector 36a
The data on the displacement measured at ~ 36n is integrated box 38.
Are collected into one data, and the collected data is input to the instruction measuring unit 20. On the other hand, the wheels 34 of the vehicle 32
The load cell 14, 16 measures the load of the vehicle 32 applied to the loading plate 12 from the time when the vehicle approaches the loading plate 12 until the vehicle passes. This measurement data is junction box 1
It is input to the instruction measuring unit 20 via 8. This measurement data includes shaft vibration, but the vehicle detectors 36a to 36n
The axial load of the vehicle 32 can be calculated with high accuracy by synchronizing with the data measured by. That is, the instruction measuring unit 20 detects the acceleration of the vehicle 32 in the vertical direction based on the data on the displacement of the vehicle 32 in the vertical direction measured by the vehicle detectors 36a to 36n. Then, the axle weight of the vehicle 32 is calculated from the detected acceleration data and the load data measured by the load cells 14 and 16.

Next, the method of calculating the axial load will be described.
Now, assuming that the entire load of the vehicle 32 is applied to the loading plate 12, the load f applied to the loading plate 12 is the axial weight m.
And the acceleration in the vertical direction of the vehicle 32 is α, the load f is expressed by the following equation (1).

F = m (g + α) (1) Here, g represents gravity.

In the formula (1), the load cells 14 and 16 are
Α is unknown only by the load data by the detection of
With the TV camera 10 or the vehicle detectors 36a to 36n, the vehicle height change amount Δh during the minute time Δt can be obtained by the following equation (2).

Α = dΔh ² / d ² Δt (2) From the equation (2), the acceleration α in the vertical direction of the vehicle 32 can be calculated.

Actually, when the ITV camera 10 is used as the vehicle height measuring device, since the photographing is performed in frame units with a sampling cycle of about 30 ms, the sensing area is measured immediately after the vehicle 32 enters the sensing area. The displacement of the vehicle height until the vehicle comes out is measured, and the acceleration at t _n is calculated from the data of the minimum frame n including the time t _n of the peak value of the measurement data of the load cells 14 and 16 and the immediately preceding frame (n-1). α is calculated from the equation (2).

Here, by substituting α in equation (2) into equation (1) and modifying the equation, the following equation (3) is obtained.

M = f / (g + α) = f / (g + dΔh ² / d ² Δt) (3) However, Δt = t _n −t _n−1 It is possible to calculate the shaft weight n from the formula (3). Becomes

[0026]

As described above, according to the present invention,
The load accompanying the running of the vehicle is detected, the acceleration accompanying the shaft vibration of the vehicle is detected, and the axle weight of the vehicle is calculated based on the detected load and the detected acceleration. The axle weight of the vehicle can be calculated accurately.

[Brief description of drawings]

FIG. 1 is an overall configuration diagram showing an embodiment of the present invention.

FIG. 2 is a block configuration diagram for explaining the operation of the apparatus shown in FIG.

FIG. 3 is a flowchart for explaining the operation of the apparatus shown in FIG.

FIG. 4 is an overall configuration diagram showing another embodiment of the present invention.

FIG. 5 is an overall configuration diagram of a conventional example

FIG. 6A is a waveform diagram for explaining the relationship between vehicle speed and load. FIG. 6B is a waveform diagram for explaining the relationship between vehicle speed and load. Waveform diagram for explaining the relationship with the load (d) is a waveform diagram for explaining the relationship between the vehicle speed and the load

[Explanation of symbols]

 10 ITV camera 12 loading plate 14, 16 load cell 18 connection box 20 instruction measuring unit 22 imaging device 24 warning display device 26 booth printer 28 personal computer 32 vehicle 36a to 36n ultrasonic vehicle detector

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location G08G 1/04 G08G 1/04 D

Claims (2)

[Claims] 1. A load detecting means for detecting a load due to traveling of a vehicle, an acceleration detecting means for detecting an acceleration in a vertical direction of the vehicle due to an axial vibration of the vehicle, a detection output of the load detecting means and an acceleration detecting means. An axle load measuring device comprising an axle weight calculating means for calculating the axle weight of the vehicle from the detected output. 2. A load detecting means for detecting a load due to traveling of the vehicle, a displacement detecting means for detecting a displacement in the vertical direction of the vehicle due to an axial vibration of the vehicle, and a vertical direction of the vehicle from a detection output of the displacement detecting means. An axle load measuring device comprising: an acceleration detecting means for detecting the acceleration of the vehicle; and an axle weight calculating means for calculating the axle weight of the vehicle from the detection output of the load detecting means and the detection output of the acceleration detecting means.