JPH10267797A - Measuring device for rolling resistance of vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicle rolling resistance measuring device capable of measuring rolling resistance as an entire vehicle with high accuracy and ease. SOLUTION: Once a wheel 12a of a vehicle 12 is determined to be rotated at a predetermined speed by the driving drum 30 of a chassis dynamo part 18, a lift control pact in a control unit 28 lifts the vehicle 12 using a vehicle restraint part 14 to remove radial load working on the driving drum 30, and a reactive force sensor 36 placed on the driving drum 30 is used to measure reactive force working on the driving drum 30, thereby measuring rolling resistance.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring rolling resistance of a vehicle, and more particularly, to an apparatus for measuring rolling resistance of a vehicle capable of measuring an accurate rolling resistance of the entire vehicle.

[0002]

2. Description of the Related Art In recent years, as the performance of automobiles has been improved, the fuel consumption of vehicles has been actively reduced. One of the important considerations for realizing this fuel economy is the rolling resistance of the vehicle. In order to minimize the loss of driving energy generated by a motor in an engine for an gasoline-powered vehicle and to transmit the driving energy to the wheels while minimizing the loss, the rolling resistance is desirably as small as possible. Various measures such as a design change have been taken to reduce the rolling resistance of the unit.

[0003] When the rolling resistance is measured for each unit, it can be measured to some extent accurately. Further, the rolling resistance of the entire vehicle in the completed vehicle state is determined by a chassis dynamometer 10 as shown in FIG.
It can be measured by a measuring device utilizing 0.
When measuring the value of the rolling resistance of the vehicle as a whole, after the transmission of the vehicle 102 to be measured is in the neutral state, the wheel 1 of the vehicle 102 is placed on a drum 108 connected to a dynamo 104 via a shaft 106.
02a is stopped. In this state, the dynamo 104 is rotationally driven to rotate the drum 108. By rotating the wheels 102a of the vehicle 102 together with the rotation of the drum 108, the vehicle 102 is brought into the same state as when the vehicle 102 is running at a constant speed. At that time, Dynamo 104
Is measured as rolling resistance.

In addition, the aforementioned chassis dynamometer 10
The measurement of the rolling resistance value of the vehicle 102 using the zero is performed by using the shaft 10 existing between the wheel 102a and the dynamo 104.
6 due to transmission loss due to the bearing 6 and the bearing 110
There is also a rolling resistance measuring device in which a sensor for detecting a reaction force is arranged at 08 to improve the measurement accuracy of the rolling resistance.

[0005]

In the measurement of the rolling resistance for the entire vehicle as described above, the dynamo 1
As shown in FIG. 6, since the radial load N due to the weight of the vehicle acts on the drum 108, only the rolling resistance f cannot be detected. There is a problem that can not be obtained. That is, the drum 108 and the wheel 102
When a is rotating, when a radial load N is applied, a friction coefficient μ and a frictional force μN corresponding to the radial load N are generated between the drum 108 and the wheel 102a. The value F detected by the disposed sensor is the resultant of the rolling resistance f and the frictional force μN. Therefore, the rolling resistance required for evaluating the vehicle cannot be measured with high accuracy.

Further, in order to measure the change in rolling resistance when the radial load acting on the axles and wheels changes front-to-back and left-right depending on the vehicle condition, preparation for measurement such as weight adjustment becomes complicated, and a stable measurement result is quickly obtained. There is a problem that it is difficult to obtain.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and provides a vehicle rolling resistance measuring apparatus capable of easily and easily measuring the rolling resistance of the entire vehicle. The purpose is to do.

It is another object of the present invention to provide a rolling resistance measuring device capable of easily measuring a change in rolling resistance when a radial load changes according to a state of a vehicle.

[0009]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention is directed to a reaction force generated when a wheel of a vehicle is rotated by a driving drum which is rotatable and capable of contacting the wheel. In a rolling resistance measuring device that detects the rolling resistance of a vehicle by detecting the vehicle, a vehicle restraining portion that supports the vehicle so as to be able to be lifted vertically and a radial that acts on the driving drum by adjusting a lifting force of the vehicle restraining portion. And a lifting control unit for changing and controlling the magnitude of the load, wherein a reaction force is detected and a rolling resistance of the vehicle is measured in the selected radial load applied state.

Here, the lifting control section can change the radial load applied to the drive drum by the vehicle from zero to an arbitrary value. Actually, if the radial load is reduced to zero, a slip occurs between the drive drum and the wheels, and it becomes impossible to maintain the constant speed rotation of the wheels.Therefore, when measuring rolling resistance, the radial load is the minimum value at which no slip occurs. It will be.

According to this configuration, the magnitude of the radial load received by the drive drum from the vehicle can be arbitrarily increased or decreased. Therefore, if the radial load is reduced to a necessary minimum by the lifting portion, the rolling resistance of the entire vehicle is increased. It becomes possible to measure with accuracy. In addition, when a desired radial load is applied, the rolling resistance of the vehicle in that state can be easily measured.

[0012] In order to achieve the above object, the configuration of the present invention is characterized in that the lifting control unit controls the lifting force independently for each axle of the vehicle.

According to this configuration, the radial load before and after the vehicle can be arbitrarily changed. When the radial load changes for each axle depending on the state of the vehicle, what kind of influence is exerted on the change in rolling resistance? Can be easily recognized.

[0014] In order to achieve the above object, the configuration of the present invention is characterized in that the lifting control section controls the lifting force independently for each wheel of the vehicle.

According to this configuration, the radial load can be arbitrarily changed for each wheel, so that it is possible to easily recognize how the change in the balance of the radial load affects the change in the rolling resistance. .

In order to achieve the above object, according to the configuration of the present invention, the lifting control unit applies a predetermined amount of radial load to the rotating drum when the rotating drum accelerates and rotates the wheel. At the time of constant speed rotation, control for reducing the radial load is performed.

According to this configuration, a stable rotation state of the wheel can be quickly obtained, so that the rolling resistance can be measured smoothly.

In order to achieve the above object, according to the present invention, the drive drum includes an inner wheel formed of a heavy member, an outer wheel formed of a lighter member than the inner wheel, And a plurality of spoke members formed of a member having a lower rigidity than the outer wheel and connecting the inner wheel and the outer wheel. Each spoke member has a reaction force detection sensor.

Here, the weight member forming the inner wheel is, for example, iron, and the lightweight member forming the outer wheel is, for example, FRP. Also, the spoke members are
For example, the reaction force detection sensor formed of super-geralmine is, for example, a strain gauge or a piezoelectric element, and performs bending stress detection, shear stress detection, compression stress detection, and the like.

According to this configuration, by forming the outer hole with a lightweight member, a phenomenon occurring on the vehicle side can be transmitted to the reaction force detecting sensor without being affected by inertia, and the inner wheel can be weighted. By forming it with a member, stable wheel rotation can be realized, and stable measurement of rolling resistance can be performed. In addition, by arranging the reaction force detection sensor on a spoke member formed of a member having a lower rigidity than the outer wheel, accurate reaction force detection becomes possible, and highly accurate rolling resistance can be measured.

[0021]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention (hereinafter referred to as embodiments) will be described below with reference to the drawings. FIG. 1 shows a configuration diagram of a vehicle rolling resistance measuring device 10 of the present embodiment. This rolling resistance measuring device 10
Four fork-shaped claws are brought into contact with a part (for example, a jack-up point) of a body of the vehicle 12 to be measured, and are disposed below the floor surface 16 and a vehicle restraining portion 14 for lifting and supporting the vehicle 12. And a chassis dynamo portion 18 partially exposed from the floor surface 16 so that the wheels 12a of the vehicle 12 can come into contact therewith.

The feature of this embodiment is that the vehicle restraining portion 1
4, the support state of the vehicle 12 is adjusted, and the rolling resistance is measured while arbitrarily adjusting the magnitude of the radial load acting on the chassis dynamo unit 18. Another characteristic point is that a reaction force detection sensor for measuring rolling resistance is arranged at a spoke portion of a drive drum of the chassis dynamo unit 18.

As shown in FIGS. 1A and 1B, the vehicle restraining portion 14 has a moving block 22 slidably mounted on an overhead rail 20, and is provided with a piezoelectric element (for example, a load cell). A restraining arm 26 is connected to the moving block 22 via a pressure gauge block 24 having a load measuring sensor. As shown in FIG. 1 (b), the restraining arm 26 has a substantially U-shape, and an opening / closing actuator 26a (for example, And a load adjusting actuator 26b (for example, a hydraulic cylinder) that expands and contracts in the height direction of the vehicle 12 in the middle vertical portion. In addition, the vehicle 12
Is formed with a fork-like claw 26c that engages with the jack-up point of the vehicle and restrains and supports the vehicle 12. The stop position of the moving block 22 and the drive timing and drive amount of the opening / closing actuator 26a and the load adjustment actuator 26b of the restraining arm 26 are collectively controlled by a lifting control unit included in the control unit 28, and the chassis dynamo unit Vehicle 12 against 18
Accurate positioning.

On the other hand, the chassis dynamo unit 18
Of the dynamo 34 via a shaft 32. In the case of the embodiment of FIG. 1, the dynamo 34 is a twin shaft type in which the same rotation shaft protrudes left and right, and two drive drums 30 on the front wheel side and two drive drums 30 on the rear wheel side are individually provided. It is connected to dynamo 34. When the rolling resistance is measured, each dynamo 34 functions as a motor, and the rotating drive drum 3 rotates.
A reaction force generated in a direction opposite to the driving direction generated when the wheels 12a that come into contact with 0 rotates together is detected by a reaction force detection sensor described later.

A key groove is formed on the shaft 32, and a key is formed on the drive drum 30 side (the key groove and the key may be arranged in reverse order). Therefore, the drive drum 30 can be arbitrarily moved in the vehicle width direction of the vehicle 12, and the drive drum 30 is fixed at an arbitrary position in accordance with the vehicle width of the vehicle to be measured. Good contact can be achieved. In addition, it is desirable to provide a moving mechanism or the like to the mounting table 34a of the dynamo 34 for vehicles having different wheelbases. Further, the movement adjustment of the drive drum 30 may be automatically performed by controlling the actuator such as the hydraulic cylinder by the control unit 28 described above.

Further, the driving drum 30 is shown in FIG.
As shown in (a) and (b), it has a shape in which the inner wheel 30a and the outer wheel 30b are connected by a spoke member 30c. The inner wheel 30a is provided with a key as described above, is slidable and fixable on the shaft 32, and is made of a heavy member having a large mass, for example, iron. On the other hand, the outer wheel 30b is made of a light member having high rigidity and small mass, for example, fiber reinforced plastic (FRP).
And CFRP containing carbon or the like.

The spoke member 30c is formed of a material having a lower rigidity than the outer wheel 30b, for example, super-geralmine, and a reaction force detecting sensor 36 such as a strain gauge or a piezoelectric element is disposed on the surface thereof. This reaction force detection sensor 3
6 detects the reaction force generated in the direction opposite to the rotational driving direction generated when the drive drum 30 rotates the wheels 12a together, as described above. In this manner, by forming the outer hole 30b with a lightweight member, a phenomenon (rolling resistance) occurring on the vehicle 12 side can be transmitted to the reaction force detection sensor 36 without being affected by inertia generated by rotation. At the same time, by forming the inner wheel 30a by a weight member, a stable rotation of the wheel 12a is realized,
Stable measurement of rolling resistance can be performed. Also,
By arranging the reaction force detection sensor 36 on the spoke member 30c formed of a member having a lower rigidity than the outer wheel 30b, accurate reaction force detection becomes possible, and highly accurate rolling resistance can be measured.

FIG. 2 shows an example in which a reaction force detection sensor 36 is arranged on the spoke member 30c. It is desirable to select an arrangement method and a sensor type of the reaction force detection sensor 36 according to the type of stress to be detected. FIG. 2 (a)
In the case where the rolling resistance is measured based on the bending stress acting on the drive drum 30, a strain gauge 36a is attached in the radial direction of the drive drum 30. FIG.
(B) shows a case where the rolling resistance is measured based on the shearing stress acting on the drive drum 30, and the two strain gauges 36a
Is pasted in a cross. Further, FIG.
Is a case where the rolling resistance is measured based on the compressive stress acting on the driving drum 30. The piezoelectric element 36b is used as the reaction force detection sensor 36, and the piezoelectric element 36b is claw 30a ₁ erected on the inner wheel 30a. sandwiching the pawl 30b ₁ was erected on the outer wheel 30b with. In any case, a deformation due to a reaction force acting in a direction opposite to the rotational driving direction of the driving drum 30 is detected as a voltage change, and transmitted to a measurement calculation unit by a telemeter or a slip ring (not shown). Then, the measurement calculation unit takes an average value of the detection results from the reaction force detection sensors 36. This average is
Since the rolling resistance is proportional to the value of the rolling resistance, the rolling resistance is converted from the average value. In the case of the present embodiment, it is assumed that the measurement calculation unit is provided in the control unit 28 shown in FIG.

In order to detect an accurate reaction force by the reaction force detection sensor 36, it is preferable to eliminate external force acting on the driving drum 30 as much as possible. Therefore, as shown in FIG. 3, by forming the spoke member 30 into a wing shape,
The aerodynamic resistance of the drive drum 30 can be reduced, and windage loss can be reduced.

In the case of FIGS. 1A and 1B, the spoke member 30c is connected to the three members with an emphasis on minimizing windage loss.
Although this example is used, it is desirable to form six or eight drive drums in consideration of the strength of the entire drive drum 30 and the uniform distribution of the reaction force acting between the spoke members 30c.

Next, a procedure for measuring the rolling resistance of the vehicle 12 by the rolling resistance measuring device 10 will be described. As a preparation for measurement, the lifting control unit of the control unit 28 adjusts the distance between the front-wheel-side claws 26c and the rear-wheel-side claws 26c of the vehicle restraining unit 14 to the distance between the jack-up points of the target vehicle 12 and the opening / closing actuator 26a. Is driven to extend and the vehicle 12 is made to stand by in a holding preparation state. At the same time, the position of the mounting table 34a of the dynamo 34, the distance between the wheels of the drive drum 30, and the like are adjusted to the distance between the wheels 12a of the vehicle 12. In this state, the vehicle 12 is moved so that the wheel 12a of the vehicle 12 contacts the top portion of the drive drum 30 exposed from the floor surface 16. Subsequently, the opening / closing actuator 26a of the vehicle restraining portion 14 which is waiting in the grip preparation state is compressed and driven, and each claw 26c is sunk into the bottom surface of the vehicle 12. continue,
The load adjusting actuator 26b of the vehicle restraining portion 14 is compressed and driven to lift the vehicle 12, and the pressure gauge block 24 is lifted.
The weight of the vehicle is measured by the load measuring sensor, and the difference from the specification weight is unloaded by the load adjusting actuator 26b to make the radial load condition acting on the drive drum 30 constant. Subsequently, the dynamo 34 is driven as a motor, the driving drum 30 is driven to rotate, the rotation speed of the wheels 12a is increased to a predetermined value (for example, 80 km / h), and the same as when the vehicle 12 is running. And prepare for measurement.

The wheel 12a is in a constant speed state (for example, 80 km
/ H), the lifting control unit of the control unit 28 can confirm that the load adjusting actuator 2
The radial load is gradually released by compressing and driving 6b. At this time, if the radial load is set to “0”, a slip occurs between the drive drum 30 and the wheels 12a,
Because the constant speed rotation of the wheel 12a cannot be maintained,
The value of the minimum radial load at which no slip occurs is calculated in advance from the slip ratio and the number of rotations of both, and the unloading of the radial load is limited to the minimum value. In this state, the control unit 28 collects the detection results of the respective reaction force detection sensors 36 and measures and calculates the rolling resistance by a known method.

As described above, according to the rolling resistance measuring apparatus 10 of the present embodiment, an unnecessary radial load acting on the reaction force detecting sensor 36 can be eliminated when measuring the rolling resistance. It can be measured accurately and easily. In the acceleration state of the wheel 12a, an appropriate radial load is applied, so that the wheel 12a can be rapidly accelerated and the preparation for measurement can be smoothly performed.

In the above description, the measurement is performed by controlling the front and rear axles to have the same radial load unloading state by the front wheel side restraining arm 26 and the rear wheel side restraining arm 26. The front wheel side restraint arm 26 and the rear wheel side restraint arm 26 may be individually controlled to arbitrarily adjust the unloading amounts of the front and rear axles. By performing such control, the vehicle is mounted (mounted), for example, when a person gets on only the driver's seat and the passenger seat, when a person gets on the rear seat, or when luggage is put on the trunk, etc. Rolling resistance when the radial load acting on the front and rear axles changes can be easily measured. By comparing the measurement results, it is possible to determine how the change in the radial load of the vehicle affects the rolling resistance. It can be easily recognized.

FIGS. 4A and 4B show another configuration of the rolling resistance measuring device. The basic configuration of the rolling measuring device 38 shown in FIG. 4 is the same as that of the rolling measuring device 10 shown in FIG.
The difference is that the radial load is controlled for each wheel of the vehicle 12 and the value of the rolling resistance is measured for each wheel. As shown in FIGS. 4A and 4B, the vehicle restraining portion 14
The lower horizontal part of the restraining arm 26, movable pawl 26c ₁ ~26c ₄ are formed up and down independently by the four load adjustment actuators 26b. The chassis dynamo unit 18 also has four independently controllable dynamos 34-.
Drive drums 30-1 to 30-4, respectively.
0-4 are being driven. Except for performing the unloading control of the radial load for each wheel, the preparation for the measurement and the measuring method are the same as those described above.

As described above, by controlling the radial load for each wheel 12a, the rolling resistance for each wheel can be measured with high accuracy. Further, by controlling the unloading amount of each radial load, for example, it is possible to variously change the variation of the measurement conditions of the rolling resistance such as applying a load of 50 kg to the driver's seat and applying a load of 80 kg to the left side of the rear seat. By comparing the measurement results, it is possible to easily recognize how the change in the balance in the vehicle riding (mounted) state affects the change in the rolling resistance. Of course, it is also possible to perform the same measurement as the rolling resistance measuring device 10 with the configuration of the rolling resistance measuring device 38.

In the above-described embodiment, an example has been described in which the vehicle 12 moves and grips the vehicle restraining unit 14 where the vehicle restraining unit 14 is waiting in a vehicle gripping preparation state. Alternatively, the moving block 22 may be moved along the overhead rail 20 and transferred to a position immediately above the chassis dynamo unit 18 to prepare for measurement.

When changing the wheel rotation speed at the time of measurement, the lifting control unit releases the unloading of the radial load,
The driving force transmission efficiency from the driving drum to the wheels is increased to a desired rotational speed. After that, the radial load unloading control is performed again to measure the rolling resistance at a desired speed.

[0039]

According to the present invention, the magnitude of the radial load received from the vehicle by the driving drum of the rolling resistance measuring device can be arbitrarily increased or decreased. Since the bearing loss (increase in torque) due to the radial load, which has occurred during the conventional measurement, can be minimized, the rolling resistance of the entire vehicle can be measured with high accuracy. In addition, since the reaction force detection sensor for measuring the rolling resistance is arranged on the driving drum of the measuring device, that is, the vehicle (tire) to be measured, the reaction force can be measured with high accuracy to obtain the rolling resistance. Further, when the desired radial load is applied, the rolling resistance of the vehicle in that state can be easily measured.

[Brief description of the drawings]

FIG. 1 is a configuration diagram illustrating a configuration of a rolling resistance measurement device according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram illustrating an attached state of a reaction force detection sensor of the rolling resistance measuring device according to the embodiment of the present invention.

FIG. 3 is an explanatory diagram illustrating a shape of a spoke member of the rolling resistance measuring device according to the embodiment of the present invention.

FIG. 4 is a configuration diagram illustrating another configuration of the rolling resistance measuring device according to the embodiment of the present invention.

FIG. 5 is a configuration diagram illustrating a configuration of a conventional rolling resistance measurement device.

FIG. 6 is an explanatory diagram for explaining the concept of rolling resistance measurement.

[Explanation of symbols]

10, 38 Rolling measurement device, 12 vehicle, 12a wheel, 14 vehicle restraint, 18 chassis dynamo, 26
Restrictive arm, 26a Opening / closing actuator, 26b
Load adjusting actuator, 26c claw, 28 control unit, 30 drive drum, 30a inner wheel, 30b outer wheel, 30c spoke member, 3
4 Dynamo, 36 reaction force detection sensor, 36a strain gauge, 36b piezoelectric element.

Claims (5)

[Claims] 1. A rolling resistance measuring device for measuring a rolling resistance of a vehicle by detecting a reaction force when the wheels are rotated by a driving drum which is rotatable and capable of contacting the wheels of the vehicle. And a lifting control unit configured to adjust a lifting force of the vehicle restraining unit to change a magnitude of a radial load acting on the driving drum, and to control a lifting force of the vehicle restraining unit. A rolling resistance measuring device for a vehicle, which detects a reaction force in the state and measures the rolling resistance of the vehicle. 2. The rolling resistance measuring device according to claim 1, wherein the lifting control unit controls the lifting force independently for each axle of the vehicle. 3. The rolling resistance measuring device for a vehicle according to claim 1, wherein the lifting control unit controls the lifting force independently for each wheel of the vehicle. 4. The apparatus according to claim 1, wherein the lifting control unit applies a predetermined radial load to the rotating drum when the rotating drum accelerates and rotates the wheel. A rolling resistance measuring device for a vehicle, which performs control for reducing a radial load during constant speed rotation. 5. The apparatus according to claim 1, wherein the driving drum includes: an inner wheel formed of a heavy member; an outer wheel formed of a lighter member than the inner wheel; A plurality of spoke members formed of a member having a lower rigidity than the outer wheel and connecting the inner wheel and the outer wheel; and each spoke member has a reaction force detection sensor. .