Abstract: A tire pressure sensing system includes a tire patch having first and second faces. A plate fixed to the second face is oriented perpendicular to a tire patch longitudinal axis. A sensor mount is positioned on the first face and oppositely facing with respect to the plate. The sensor mount includes opposed first and second bias clips and is oriented perpendicular to the tire patch longitudinal axis. At least one plate fastener extends through the tire patch fixes the plate to the second face and the sensor mount to the first face. A tire pressure sensor is releasably retained by first and second sensor fasteners and the first and second bias clips to the sensor mount. The tire pressure sensor is oriented perpendicular to the longitudinal axis. The tire patch is permanently connected to a tire inner tread wall having the longitudinal axis coaxially aligned with a tire radial centerline.

Abstract: The present invention relates to devices that include a mechanochromatic material (10) which changes color according to a pressure exerted on the device. As a result, the mechanochromatic material (10) functions as an indicator of pressure exerted on the device. A user can view the mechanochromatic material (10) to determine whether the pressure exerted on the device exceeds a threshold pressure, whereat a color change will occur in the mechanochromatic material (10).

Abstract: A tire uniformity machine includes an apparatus for receiving and rotating a tire. The apparatus includes opposed chuck assemblies for receiving, inflating and rotating the tire and a load wheel applied to the rotating tire to obtain tire test results. At least one characterizing device is associated with components of the apparatus to characterize forces of at least one of the components and the characterized forces are used in adjusting the tire test results.

Abstract: Provided is a method for testing a tire. The method may comprise performing a first stopping distance test on a tire of a first specification at a first inflation pressure and gathering data about the first stopping distance test. The method may further comprise performing a second stopping distance test on a tire of the first specification at a second inflation pressure and gathering data about the second stopping distance test. The method may further comprise performing a first traction test on a tire of the first specification at either the first inflation pressure or the second inflation pressure and gathering data about the first traction test.

Abstract: An automatic process for the identification and working of defects (12) on used tires (6) is disclosed, comprising the steps of assembling the used tire (6) on rotative support and centring means (7), starting the rotation of the tire (6), automatic scanning of the working surface (30) of the tire (6) to identify the morphology of defects (12) by means of automatic identification means (8, 41) of defects (12), comparison between the morphology of the defect (12) identified and a virtual library of defects (12?) of reference for the selection of the working and of the tool (9) to be used, charging the tool (9) chosen on an anthropomorphic robot (31), and executing the selected working on the defect (12) to form a crater (13) that is suitable for being coated, said steps being managed by a computerized control unit (11) comprising said virtual library of defects (12?).

Abstract: A determination is made as to whether a frame to be transmitted according to a first protocol is susceptible to being incorrectly interpreted by a receiver in a vehicle as being transmitted according to a second protocol. When the frame is determined to be susceptible to an incorrect interpretation, an internal value of the frame is adjusted, and the adjustment is effective to prevent an incorrect interpretation of the frame being transmitted from the tire pressure monitor to the receiver. The adjusted frame can then be transmitted.

Abstract: A method for determining or improving running characteristics of a vehicle wheel (tyre/rim assembly), comprising supporting the wheel axis of the vehicle wheel with at least a single degree of freedom of vibration perpendicular to the wheel axis. In the interior of the tyre at least one amount of a compensating substance which initiates in its flowing state a compensating effect on the rotating vehicle wheel can be disposed, and the vehicle wheel can be rotated while the compensating substance is brought into the flowing state such that the compensating substance is distributed inside the tyre during the rotation of the vehicle wheel to improve the running characteristics of the vehicle wheel, wherein the running speed of the rotating vehicle wheel is kept in a range different to the natural frequency of the rotating vehicle wheel and its suspension or supporting means.

Abstract: A tire-pressure mount apparatus having a compartment in communication with a wheel and tire assembly. The compartment has a removable closure with a tire-pressure sensor and a valve stem mounted thereon so as to permit simultaneous removal of the tire-pressure sensor and valve stem when the closure is removed from the compartment, thus providing access thereto without requiring disassembly of the wheel and tire assembly.

Abstract: In indirect tire pressure monitoring of tires of a vehicle, the following steps and means to carry out the same, respectively, are contemplated:—providing a tire classification database indicating at least one classified tire type;—determining a vehicle tire type for the vehicle on the basis of vehicle data in including information on at least one tire currently used with the vehicle,—determining whether the vehicle tire type can be associated to one of the at least one classified tire type; and—, in the case an association is determined, monitoring tire pressure according to the associated classified tire type.

Abstract: A tire state detection device capable of detecting a tire state with high accuracy. This tire state detection device (100) is a device for detecting the tire state of a pneumatic tire (200) affixed to a wheel and comprises a vibration input unit (110) for inputting predetermined vibration to the tire (200), a frequency information acquisition unit (120) for acquiring frequency information relating to the tire (200) when the predetermined vibration is inputted, and a tire state estimation unit (130) for extracting the resonance frequency and anti-resonance frequency of the tire (200) from the acquired frequency information and calculating, from the extracted resonance frequency and anti-resonance frequency of the tire (200), an outer moment of inertia and a spring constant when the tire (200) is modeled using the outer moment of inertia, an inner moment of inertia, and the spring constant of elastic force acting therebetween.

Abstract: An apparatus and method for high voltage discharge testing of a tire is disclosed. In particular embodiments, a high voltage probe is maintained against the surface of a tire. The high voltage probe is energized and relative motion is provided between the surface of the tire and the high voltage probe. At the presence of an anomaly that penetrates the insulating material of the tire surface, an electrical discharge will occur between the conductive spring electrode and a reference electrode. The reference electrode is positioned adjacent the bead portion of the tire such that the electrical discharge will travel from the high voltage probe through the anomaly in the surface of the tire to one or more carcass plies in the tire. The carcass plies will carry the electrical discharge to the bead portion of the tire, where the electrical discharge will pass to the reference electrode.

Abstract: The present invention provides a tire testing system, including: a first rail and a second rail; a carriage assembly coupled to the first rail and the second rail such that five degrees of freedom of motion of the carriage assembly are thereby constrained; a first bogie assembly coupling the carriage assembly to the first rail such that at least lateral, pitch, and yaw motions of the carriage assembly are thereby constrained; and a second bogie assembly coupling the carriage assembly to the second rail such that at least vertical and roll motions of the carriage assembly are thereby constrained; wherein the carriage assembly translates in a direction that is tangential to the first rail. The tire testing system also includes a tire articulation system coupled to the carriage assembly, wherein the tire articulation system includes a dedicated actuator for each degree of freedom of motion of a test tire coupled thereto.

Abstract: A tire air pressure monitoring device for monitoring the air pressure of a tire on a vehicle having two or more tires, including an air pressure sensing device that senses air pressure information of the tire and is adapted to be mounted at a prescribed position on the tire so as to rotate with the tire, a transmitting device that transmits the sensed air pressure information, a rotary position sensing device that senses the rotary position of the air pressure sensing device as the tire rotates, a period of rotation calculating device that calculates the period of rotation of the tire, a period of rotation disruption sensing device that senses disruption in the period of rotation based on a change in the period, and a transmission control device that outputs commands to transmit the air pressure information to the transmitting device based on a disruption in the period of rotation.

Abstract: A rim mounting device configured in such a manner that, even if a permanent magnet breaks due to impact produced during mounting thereof by magnetic attraction, the rim mounting device can be handled easily after the breakage of the permanent magnet. The rim mounting device is provided to a tire testing device having a spindle for rotating a tire and is adapted that a rim is mounted to the tip of the spindle. The rim mounting device is provided with: a rim mounting section provided to the tip of the spindle, having a rim mounting surface capable of making contact with the rim, and having mounting recesses formed in the rim mounting surface so as to be arranged side by side; permanent magnets inserted in the mounting recesses, respectively, and generating magnetic force for attracting the rim to the rim mounting surface; and scatter suppressing members.

Abstract: An apparatus to maintain optimal air pressure in a tire of a vehicle may use centrifugal force to compress air which may be delivered to the tire when the tire has low air pressure. The necessary centrifugal force to compress air may be achieved through the rotation of the tire itself. A weight may be disposed, in a chamber, near the center of rotation of a tire. The weight may be held in place with a spring or similar device. As the tire rotates, the weight may be forced outward, compressing air present in the cylinder. If the air pressure within the tire is low, the weight will compress air from inside the cylinder into the tire. The apparatus may act autonomously to add air to a low pressure tire, as opposed to simply notifying the driver that tire pressure is low.

Abstract: A tire defect tester and a method of operation are disclosed. In one aspect, the tire defect tester includes a first electrode arranged to direct energy toward a tire, and a second electrode arranged on an opposite side of the tire from the first electrode to receive energy passing through the tire from the first electrode. The tire defect tester further includes an energy sensor electrically connected to the second electrode and a fault indicator circuit responsive to the energy sensor and configured to indicate the presence of a flaw upon energy above a threshold level being sensed at the second electrode.

Abstract: A system for measuring physical parameters of a tire, according to one embodiment of the present invention comprises a sensor layer and a circuit layer. The sensor layer is communicatively coupled to the circuit layer. The sensor layer is configured as a first thin film and embedded in the tire. The sensor layer provides a signal related to a physical parameter of the tire. The circuit layer is configured as a second thin film and embedded in the tire. The circuit layer processes the signal provided by the sensor layer.

Abstract: The invention relates to a method for estimating the dynamic load borne by a tire of a vehicle running along over a given period, whereby the pressure is measured during the period, at each pressure measurement point, the pressure, known as the reference pressure, of the same tire subjected to a load that is constant and known per time interval is determined, and the variation in load is calculated from the difference between the measured pressure and the pressure, known as the reference pressure, and from a model of the tire devised beforehand and that relates a variation in load to a variation in pressure. The invention also proposes a method for estimating the load borne by a tire.

Abstract: An apparatus ascertains a contact area length of a vehicle tire. The apparatus has a transmission unit which has a resonator and which is set up to transmit a sensor signal at a defined frequency. A change in the frequency of the sensor signal on the basis of mechanical excitation of the resonator is indicative of a contact area length for the vehicle tire. Furthermore, the apparatus has a contact area length ascertainment unit which is set up to receive the sensor signal and to take the change in the frequency of the sensor signal as a basis for ascertaining the contact area length of the vehicle tire.

Abstract: A method of designing a tire, wherein a tire designer identifies a target residual aligning torque range for a tire design and creates a computer model of the tire, including a buttress angle. Further, the method includes calculating the residual aligning torque of the modeled tire and comparing the calculated residual aligning torque value to the target residual aligning torque to determine whether the calculated residual aligning torque value is within the target residual aligning torque range. The method produces a final tire design having a target residual aligning torque.

Abstract: A vehicle entry/tire pressure management system includes an ECU, tire sensors mounted in, on or adjacent respective tires of the vehicle, a portable transmission/reception unit configured to be carried by an operator of the vehicle, and an antenna mounted on the vehicle and in communication with the ECU. Each tire sensor is configured to transmit an RF signal. The portable transmission/reception unit can transmit RF signals for controlling operations of the vehicle including unlocking doors of the vehicle. The antenna is configured to transmit an LF tire sensor wake up field to wake up the tire sensors. The tire sensor wake up field includes a unique header format. The tire sensors only fully wake up upon receiving the unique header format.

Abstract: Disclosed is a method for predicting tire performance in which a tire model, which comprises a tread pattern capable of imparting deformation by means of ground contact and/or transfer, and a snow model, in which a snow-covered road surface that comes into contact with the tire model is represented, are used to predict tire performance on the snow-covered road surface on the basis of physical quantities that occur in at least either of the tire model and the snow model. The snow model is modeled as an elasto-plastic body or an elastic body, the nonlinearity of the volume compression property of snow is represented by the relationship between the density or volume strain of the snow and the pressure of the snow, and the shear property of the snow is represented by the relationship between the yield stress of the snow and the pressure of the snow.

Abstract: A method for improving a position sensing system which measures a rotating object is presented. In one embodiment, the method outputs the position of the rotating object while the object is rotating, and the method follows an external command on the sensor output line when the object is not rotating to output information other than the position information.

Abstract: Provided is an apparatus for testing an associated tire. The apparatus may comprise a substantially transparent test platform. The test platform may comprise a low friction test surface. The low friction test surface may comprise a layer of lubricant. The layer may be less than 3 millimeters thick The apparatus may further comprise an optic or acoustic data acquisition system or appliance. The optic or acoustic data acquisition system or appliance may comprise either a camera positioned to view the test surface through the substantially transparent test platform, or ultrasonic equipment positioned to acquire data regarding the test surface through the substantially transparent test platform.

Abstract: A system and related method for improving tire uniformity includes identifying at least one candidate process effect and a corresponding process harmonic number for each process effect. A given uniformity parameter, such as radial or lateral run-out, balance, mass variation, radial lateral or tangential force variation, is measured for each tire in a test set, such that the measurements contain tire harmonics as well as a process harmonics corresponding to each candidate process effect. Rectangular coordinate coefficients are electronically constructed for each said process harmonic, after which point the rectangular coordinates corresponding to each process harmonic are solved for (e.g., by using regression-based analysis). The magnitude of each said process harmonic is estimated, and a final magnitude estimate for each process harmonic can be determined by summarizing (e.g., by taking the average or median value) the respectively estimated magnitudes for each process harmonic across all test tires.

Abstract: Systems and methods facilitate the monitoring of tire pressure, the detection/determination of wheel speed, or a combination thereof. A system is provided comprising a hub cap, a target coupled to the hub cap, and at least two displacement sensors configured to measure a displacement between each displacement sensor and the target. The target has a variable thickness, and the target comprises a hollow vessel in fluid communication with a tire.

Abstract: A method of analyzing a vehicle wheel comprising a tire of a predetermined configuration and a thixotropic balancing substance, comprising rotating the vehicle wheel with a predetermined number of revolutions for a period of time, wherein a tread surface of the tire is pressed in a first contact area against a rotatable drum with a predetermined force, and a first acceleration in the first contact area is measured with a measuring device; rotating another vehicle wheel comprising another tire of the predetermined configuration with the predetermined number of revolutions for another period of time, the other vehicle wheel being conventionally balanced and having another residual unbalance, wherein another tread surface of the other tire is pressed in a second contact area against the rotatable drum with the predetermined force, and a second acceleration in the second contact area is measured with the measuring device and if the first acceleration is less than or equal to the second acceleration, determining t

Abstract: A system for locating and tracking an object is provided. The system includes a measuring device configured to determine a property of a paving-related material, a locating device configured to determine a location of the measuring device, a tracking system configured to store tracking information associated with the measuring device and one or more properties determined by the measuring device, and a communications system configured to transfer, to a remote device, the location of the measuring device and the tracking information associated with the measuring device.

Abstract: A tire test system for tire tests under the most realistic conditions possible, however, including the possibility of widely-varied, simple and precisely reproducible parameters includes a track (6) contactable by at least one tire, as well as a positive guide (5) following this track, for example, in the form of at least one rail. In addition, a test trolley (2) is provided that is guided by a positive guide (5) and is autonomously driven and/or brakable independently of the tire(s), on which trolley at least one tire (1) is mountable, and which has equipment for driving and/or braking autonomously and independently of the test trolley (2).

Abstract: A tire monitor assembly includes a rubber ply having a first side affixable to an interior surface of a tire. A pedestal extends from a second side of the rubber ply, wherein the pedestal has a top surface and at least one sidewall. The pedestal has a groove disposed in the at least one sidewall that extends along a perimeter of the pedestal, wherein the pedestal has a cavity disposed in the top surface, extending towards the rubber ply. The assembly further includes a tire monitoring device and a fastener connected to the tire monitoring device and further connected to the pedestal such that the fastener is disposed in at least one of the cavity and the groove.

Abstract: A method of estimating the transverse grip of a pair of tires intended to equip a two-wheeled vehicle by comparative analysis against another pair of tires. The tires are mounted on the vehicle in pairs, the vehicle is run in a circle of set radius until it attains the maximum speed with grip, and the mean speed and/or the mean cornering angle of the vehicle under steady state conditions and/or the mean lap time is/are determined.

Abstract: Systems and methods, including: one of a simulated road surface and an actual road surface; a test tire physically contacting the one of the simulated road surface and the actual road surface; and a plurality of gears linking the test tire and the one of the simulated road surface and the actual road surface, such that the velocities of the test tire and the one of the simulated road surface and the actual road surface are linked and an associated slip ratio between the test tire and the one of the simulated road surface and the actual road surface is controlled. The simulated road surface includes one of a drum, a belt, a drive wheel, and a rail. The plurality of gears are varied in terms of gear ratio using a controller such that slip ratio is dynamically controlled and varied.

Abstract: A system for characterizing a vehicle tire is provided. The system includes a testing assembly configured to support the vehicle tire. The assembly includes a force-moment transducer configured to gather force information from the vehicle tire in response to a stimulus on the vehicle tire. The system further includes an accelerometer coupled to the vehicle tire and configured to gather vibration information from the vehicle tire in response to the stimulus on the vehicle tire. The system further includes a post-processing system configured to receive the vibration information from the accelerometer and the force information from the force-moment transducer. The post-processing system is further configured to extract resonant frequencies from the vibration information and the force information.

Abstract: A bearing assembly for a vehicle wheel with a sensor in which load acting on the bearing assembly and/or a tread surface is accurately detected is provided. The bearing assembly includes rolling elements between outer and inner members, a load detecting device in one of the outer and inner members provided as a stationary member, for detecting load acting on the bearing assembly, a rotation detecting device for detecting the rotation of the other member provided as a rotating member, an averaging circuit for calculating rotational speed of the rotating member from output of the rotation detecting device, determining from the calculated rotational speed a time period required for the rolling elements to revolve a pitch of arrangement thereof and calculating average value of output of the load detecting device during the period, and an estimating circuit for estimating the load from the average value.

Abstract: At least one of ground contact pressure, shear stress and amount of skidding is measured at a measurement point on a tread surface of a tire. A sensor is arranged on a road surface and the measurement point is made to contact the sensor while the tire rotates. An initial position of the tire is set, where the measurement point is at a previously-set reference position and the tire is at a running start position on the road surface. The tire is made to run from the initial position to obtain a rotation angle difference ? between a tire rotation angle until the rotation axis of the tire passes over the arrangement position of the sensor and a tire rotation angle until the measurement point contacts the road surface. The tire is set at the initial position and rotated by ? without changing the running start position of the tire.

Abstract: A tire pressure measurement system (TPMS) includes a capacitor and an integrated circuit configured to receive a supply voltage. The integrated circuit includes a voltage regulator and a measurement unit. The voltage regulator is configured to be turned on and off for predetermined periods of time such that the capacitor is charged and discharged, respectively. The voltage regulator and the capacitor are connected to the measurement unit in order to selectively provide electric charge at a voltage between predetermined upper and lower limits.

Abstract: An inflation and pressure measurement system having over pressure protection for an attached pressure gauge. A plunger is placed within an internal cavity of a valve body where the plunger can move axially into a first and a second position. In the first position there is gaseous communication between an inflation valve and an operating port. While in the first position, a gauge port may release gas through a wiper seal. In the second position there is gaseous communication between the operating port and the gauge port. The plunger may be biased in the second position. The first and second positions may be located by a locating groove in the plunger and a locating structure passing through the valve body and contacting the locating groove. While the inflatable device can be inflated using high pressures, the pressure gauge is protected from over pressure damage. Some embodiments can inflate and monitor the pressure of multiple inflatable devices from a single position.

Abstract: Disclosed herein is a device for detecting a tire position. The device for detecting a tire position includes a plurality of transmitters provided on each of a plurality of vehicle wheels having a tire and detecting and transmitting a rotation direction and a rotation period of each vehicle wheel; and a receiver mounted on a vehicle body and identifying the left and right of the corresponding vehicle wheel according to the rotation direction of each vehicle wheel and identifying the front and rear of the corresponding vehicle wheel according to the rotation period of each vehicle wheel. By the above configuration, the present invention can identify the tire position without performing the ID information and the ID information update and thus, improve a freedom of change of the tire position and can digitize and process signals from a acceleration sensor to be strong against noise and reduce load.

Abstract: A digital tire pressure gauge has a housing having a first and a second end. A port at the first end of the housing is adapted to engage with and open a needle valve of a tire valve stem. The gauge also includes a pressure sensor and a processor in electronic communication with the pressure sensor. A bleed valve is disposed in the housing and a bleed lever is in contact engagement with the bleed valve. When the port is coupled to the tire valve stem, in a first operational mode, the bleed valve is closed and an air pressure measurement is obtained. In a second operational mode, pressing the bleed lever causes the bleed valve to open and to allow air to be bled out from the tire via the pressure gauge.

Abstract: A tyre changer which comprises a mounting device (18) for receiving at least a wheel rim of a wheel/tyre assembly, wherein the mounting device (18) has an axis (S), a roller (26) which is able to contact a peripheral surface of the wheel/tyre assembly (14) and to apply a predetermined force to the peripheral surface of the wheel/tyre assembly (14), a control device (32) for controlling the predetermined force applied by the during a rotation of the wheel/tyre assembly about the axis (S) of the mounting device and a sensor device (30) for measuring force variations acting between the peripheral surface of the wheel/tyre assembly and the roller (26), wherein supports (20, 22) of the roller (26) and of the mounting device (18) are designed for a relative movement of the roller (26) and of the mounting device (18) towards each other along a straight line to apply the predetermined force to the peripheral surface of the wheel/tyre assembly (14).

Abstract: An adjustable width chuck assembly for a tire testing machine including upper and lower relatively movable rims by which a tire is clamped and held during a testing cycle. A pilot or nose cone forming part of one of the rims is gas pressure biased towards engagement with complementally formed structure on the other rim. The gas pressure bias is provided by a gas spring which can be replaced with gas springs of differing pressures in order to adjust the biasing force or, alternately, the gas spring can be removed from the chuck assembly and re-pressurized to a different level in order to change its biasing force. The use of a gas spring for providing the necessary biasing force expands the range of motion for the nose cone, thus allowing a given chuck assembly to accommodate tires having a wide range of bead widths.

Abstract: The degree of wear of a tire is estimated with constant accuracy. An acceleration sensor (11) is installed on the inner surface in the inner liner region of a tire to detect the acceleration of the tread in the radial direction of the tire. The peak level on the leading edge side or the trailing edge side of the tread appearing in the differentiated waveform of the detected acceleration is calculated and used as an index V of deformation speed of the tread. The degree of wear of the tire is estimated on the basis of the calculated index V of deformation speed and an M-V map (16B) showing a predetermined relationship between the degree M of tire wear and the index V of deformation speed.

Abstract: A rotary drum used in a tire testing machine has a road surface base material made of an aluminum alloy and provided with a road surface onto which a tire is pushed. The road surface is coated with a thermally-sprayed steel film having higher hardness than the road surface base material, and polished. With such a configuration, a favorable test result can be obtained.

Abstract: The present invention provides a tire state variables management system where an external module can reliably receive data from a specific sensor module from which data is to be acquired when an external module transmits to the sensor module a command signal for requesting data transmission. Each sensor module 3 possesses a self-identifying code for distinguishing itself from other sensor modules; the command signal transmitted by the external module 2 includes the self-identifying code possessed by the sensor module 3 from which data is to be acquired; and the sensor module 3 is adapted to transmit the data only when the self-identifying code included in the command signal from the external module 2 coincides with the self-identifying code possessed by itself.

Abstract: A sensor device adapted to be associated with a vehicle wheel includes a package enclosing at least one sensor and an electronic data processing apparatus and at least one antenna arranged on the package for at least one among the wireless transmission of data generated by the electronic apparatus and the wireless reception of data to be provided to the electronic apparatus. The at least one antenna is shaped to adhere to surfaces of the package.

Abstract: A tire testing apparatus that includes a test drum and at least one tire station. The test drum has an outer radial surface and a plurality of sectioned plates having outer radial test surfaces, wherein the plurality of sectioned plates mount on the outer radial surface of the test drum. The tire testing apparatus further includes at least one tire station having a selected tire with a tread, wherein the tread of the selected tire presses against the outer radial test surface of the plurality of sectional plates, and wherein the at least one tire station applies a force against the tread of the selected tire. Further, a tire testing method includes providing a selected tire having a circumferential tread and moving the selected tire against a rotating test drum having a plurality of sectional plates having a test surface.

Abstract: The detection apparatus includes means for detecting rotation speed information of the respective wheels of a vehicle; means for estimating, a frequency characteristic of the wheel rotation speed information; and means for determining, based on the estimated frequency characteristic, a tire having a decreased air pressure. The frequency characteristic estimate means includes, to a time-series signal including the wheel rotation speed information: means for time-series estimating a third order or more linear model parameter; means for generating pseudo input data; means for estimating, based on the estimated linear model parameter and the pseudo input data, output data to a linear model; means for identifying, based on the pseudo input data and the estimated output, a linear model parameter for which the order is reduced to a second order; and means for estimating, based on the identified parameter for which the order is reduced to the second order, a resonance frequency of a tire torsional direction.

Abstract: A method is disclosed for determining a grade of a roadway bordered by a marker including a bottom that contacts the roadway, with a machine traveling on the roadway. A scanning device mounted on the machine is used to locate a first point indicative of the bottom of the marker at a first geographical location along the roadway. The scanning device is also used to locate a second point indicative of the bottom of the marker at a second geographical location along the roadway. The locations of the first and second points are compared to determine the grade of the roadway. Also disclosed is a method for determining a bank of a roadway bordered on a first side by a first marker including a bottom that contacts the roadway and bordered on a second side by a second marker including a bottom that contacts the roadway, with a machine traveling on the roadway.

Abstract: A method for evaluating the transversal grip of a type of tires on a snow-covered ground, of providing this type of tires to a vehicle, driving this vehicle at the transversal grip limit on a snow-covered track, and producing instantaneous measures of the vehicle transversal acceleration while it travels on the track. Track (P) includes a plurality of turns (V1, V2) making it possible to establish a transversal acceleration steady state, the transversal acceleration instantaneous measures being subjected to a low-pass filtering, and the transversal grip of a tire is judged as being even better the higher the transversal acceleration values obtained with this tire are.

Abstract: A tire testing machine according to the present invention, which can measure both uniformity and dynamic balance of a tire T, comprises a spindle for driving the tire T to rotate about a vertical axis, a spindle housing which supports the spindle rotatably, and a rotating drum rotatable about an axis parallel to an axis of the spindle and movable toward and away from the tire T. The spindle housing is fixed to a base through a piezoelectric sensor so that it can bear a pressing force provided from the rotating drum. The piezoelectric sensor is disposed within a plane including the axis of the spindle and perpendicular to the pressing force. With this structure, dynamic balance of the tire can be measured accurately and easily.