BRPI1001095A2 - improvement in apparatus for measuring the geometry elements of a vehicle suspension - Google Patents

Abstract

IMPROVEMENT IN APPARATUS FOR MEASURING THE GEOMETRIC ELEMENTS OF A VEHICLE SUSPENSION. Comprising mechanical and electronic means so that a set of preferably 3 electronic gyros (11), one for the X axis (12a), one for the Y axis (12b) and the other for the Z axis (12c), can be used in Measurement of the different angles found in the geometry of a vehicle suspension, in which the mechanical means, in addition to the electronic parts, are initially defined by a calibration base (1) which, on the one hand, is electronically interconnected with a computer. (2) and, on the other hand, includes coupling / uncoupling and electronic interconnecting means with four measuring heads (3), one left front head (a), one right front head (b), one left rear head ( c) and a right rear head (d); each calibration head (3) has its electronic circuit with its microcontroller (4) which, in addition to the corresponding power supply (5), also has interconnections (6) and (7 or 8), the first with the computer (2), while the other two are communication heads (3abcd), which optionally may be wired or wireless; said calibration base also includes head coupling sensors (9) and lab charging circuitry (10) of said heads; each measuring head (1) has the corresponding microcontroller (13), with which a set of 3 electronic gyroscopes are interconnected, one for the X axis (12a), one for the Y axis (12b) and the other for the axis. Z (12c) arranged on printed circuit boards, the front of which also includes an inclinometer (14), optional three-axis accelerometer (15), optional electronic compass (iSa) position sensor (16), battery (17), a display (18), keys (19) for user interface, on this board will be the microcontroller (13) and the connections for wired or wireless communication (7-8), while the other two cards for the other axes will be mounted on a relief built to ensure orthogonality.

Description

IMPROVEMENT IN APPLIANCE FOR MEDICATION OF

GEOMETRY ELEMENTS OF A VEHICLE SUSPENSION. Field of the Invention.

More particularly the present invention relates to technical and functional improvements introduced in apparatus for measuring the geometry elements of a vehicle suspension, making it an ideal equipment for workshops and other establishments working with steering alignment in general.

There are numerous literatures on the subject, some of which are adopted in the descriptive in question, taking into consideration some teachings of Brazilian associations and publications, mainly from ABRAPNEUS Brazilian Association of Tire Dealers and SINDIREPA SP Vehicle and Accessories Repair Industry Union of the State of São Paulo. Automotive Literature - Suspension Geometry. GT Editora, 2009. p.7-16.

ELEMENTS OF THE GEOMETRY OF A VEHICLE SUSPENSION Allnhaznentio Steering

Alignment is specified by the vehicle manufacturer to provide higher rolling efficiency, better drivability and optimization of the degree of esterification. Any change in alignment specifications caused by impact, chatter, lateral compression and suspension component wear may compromise the vehicle's good behavior. Or cause uneven and premature wear of the tire tread. Front wheel alignment based on centerline

The convergence of each front wheel is measured and adjusted using the vehicle centerline as a reference. This method has been used for many years and can provide satisfactory alignment services as long as the rear wheels of the vehicle are positioned perfectly parallel to the centerline.

In the event that the rear wheels (rigid axle or independent suspension) create a directional line forming an angle to the centerline, the steering geometry will come out of its center point and the steering wheel will be bent to one side when the vehicle "rotate" straight.

Front wheel alignment based on directional line

Aligning the front wheels based on the directional line created by the rear wheels represents a considerable advance over the previous method.

In this method rear convergence is measured (not adjusted). This measurement determines the directional line of the rear wheels that is used as a reference for adjusting the front wheels. As a result, in most cases the steering wheel will be centered when the vehicle travels in a straight line.

Full four-wheel alignment

Full alignment is the most complete service, rear individual convergence is measured and adjusted to manufacturer specifications. This adjustment matches the rear wheel directional line with the center directional geometric line. In this case the four wheels will be parallel to each other and the centered steering wheel, we will then have the total parallelism of the vehicle.

Convergence

Convergence, as shown in Figure 1, is the adjustment of the driven wheels so that they are closer at the front end than at the rear.

Divergence

Divergence, as illustrated in Figure 2, is the opposite condition to convergence. In this case, the wheels are more open at the front end than at the rear. If the specified values for wheel convergence are changed, the tire tread exhibits uneven "saw" shape wear, which will accelerate the tire evenly.

The amplitude of convergence or divergence may be expressed as follows:

• Angular measurement (in degrees) related to the vehicle's central geometric line; and

• Linear measurement (in millimeters) by reference to wheel rim.

Figures 3, 4 and 5 show, respectively, convergence, divergence and parallelism between the wheels (angle 0).

Function

The objective is to keep the wheels parallel with the track when the vehicle is moving, thus avoiding lateral tire friction with the ground, minimizing tire wear.

The wear generated by a convergence mismatch or divergence of 3mm equals a side drag of 2 meters for each kilometer traveled. Variations in suspension height may affect convergence or divergence measurements.

Curve Divergence

To make a turn, the inner wheel (relative to the rear) must steer more than the outer wheel to produce the necessary divergence to make this turn safely. After making the curve, this divergence situation must cease, returning to the specified parallelism. If the specified turning angle for an inner wheel is out of range, all vehicle tires will wear excessively on the corners as a result of the drag they are subjected to.

Differences greater than IM degrees side by side in the divergence angle in curves indicate a twist or defect in the vehicle's steering arms.

During a corner, the inner wheel describes a smaller curvature than the outer wheel, so the inner wheel should tilt slightly more than the outer wheel to avoid excessive tire friction with the ground.

Caster

As shown in Figure 6, caster is the forward (negative) or backward (positive) tilt angle of the kingpin or shaft support arm at the top relative to a vertical plane. The caster is responsible for the directional stability of the vehicle. Little or no caster will cause the wheel to wobble, resulting in marked wear on localized points of a tire tread.

The uneven caster causes the wheel to pull to one side, causing uneven tire tread wear. Excessive caster will cause premature full wear of the tire tread.

In figure 7 we have:

• Positive - when the inclination of the pivot axis is forward;

• Negative - when the inclination of the turning axis is backwards; and

· Zero - when the pivot axis is vertical.

Function

Provide directional stability.

The caster, when positive, projecting the swing axle forward, establishes the forward loading point of the wheel contact point with the ground. As a result, the wheels tend to be aligned straight ahead, imposing a straight trajectory on the vehicle. Although the caster is a critical angle for vehicle control, it does not influence tire wear.

The effects of an off-spec caster are as follows:

When insufficient

• Reduces high-speed directional stability; and

• Reduces the directional effort required at low speed.

When excessive

• Increases directional stability at high speed;

• Increases the directional effort required at low speed; and

• May cause side vibrations at high speed.

Different side by side

• May cause vehicle pull tendencies to one side and may cause problems with violent braking; and

• The maximum allowable difference side by side is ½ degree.

Camber

The camber as exemplified in Figure 8 is determined by tilting the top of the wheel into or out of the vehicle relative to a vertical plane. The camber can be positive or negative. Excessive camber causes more wear on the tire shoulder. If the camber is positive, the wear will be on the outer shoulder; If negative, wear will be on the inner shoulder of the tire.

Function

The function of the camber is to distribute the weight of the vehicle on the tire tread evenly, avoiding uneven tire wear. Excessive tire shoulder wear is generally attributed to incorrect camber adjustments.

Camber Negative (Fig. 9) Causes premature wear on the inner shoulder of the tire.

Designs the point of application of vehicle weight to the end of the wheel axle, generating a leverage effect that causes vertical instability and fatigue on both the axle and other suspension components.

Positive Camber (Fig.10)

It causes premature wear on the outer shoulder of the tires.

Designs the point of application of the vehicle weight to the inside of the wheel axle, decreasing the leverage effect and thereby increasing the vertical stability of the vehicle.

Camber Desigual (Fig. 11)

When not specified by the manufacturer, a maximum difference of ^ degrees camber side by side shall be tolerated. The vehicle tends to "pull to the side of the wheel that has the most positive camber setting.

KPI / SAI

The KPI / SAI, as shown in Figure 12, is the angle formed by the line crossing the pivot axis and the natural vertical, viewed from the front wheel.

The KPI / SAI is an angle that is not measured directly, but with a pre-set front wheel turn. More precision is obtained if the rotation is symmetrical with respect to the rear axle directional line.

Function The KPI / SAI contributes to steering stability by imposing a tendency on wheels to maintain a straight track and reducing the effects of obstacles on the steering wheel.

The KPI / SAI angle allows you to use angles of

less positive caster to facilitate vehicle handling without changing directional stability.

Included Angle

As shown in figure 13, Included angle is the sum of the angles KPI / SAI and camber. It is formed by the rotating axis and the geometric axis of the wheel. The maximum permissible difference in inclined angle of one wheel relative to another is 1.5 degrees.

When you change the camber angle, the included angle also changes.

Set back

The Set Back (SB), exemplified in Figure 14, corresponds to the coaxial difference of the axes, where (Ll) is the central geometric line. Represents the "delay" of one of the front wheels, ie the distance that one wheel is "behind" the other.

The set back angle, as shown in Figure 15, is formed between the center geometric line (L1) and the perpendicular to the front axle line (L2) (measured in degrees).

Positive (9SB) set back is considered when the left wheel is in front of the right, and negative when the right wheel is in front of the left.

Set Back Effects

Set back angles greater than +/- ¾ degrees may cause the vehicle to pull to the rear wheel side as well as general instability during braking.

Turning radius

The turning radius, as exemplified in Figure 16, is the distance between the point of contact of the tire with the ground and the steering axle projection.

Total parallelism

Total parallelism is exemplified in Figures 17 and 18, where Ll is the center geometric line, θ is the rear axle directional angle, and L2 is the rear axle directional line. Full parallelism means that the four wheels are aligned with each other, which in turn is parallel to the vehicle's center line and centered steering wheel. This situation is considered ideal for driving a vehicle.

State of the art.

Nowadays the state of the art has some technologies equally developed for measuring the geometry elements of a vehicle suspension, such technologies, although with many variations, offer means and processes that certainly compete to make accurate measurements. Existing technologies are taught in many documents, such as those listed below:

PI0604089-6 - 9/21/2006.

SET OF ALIGN ANGLE DETERMINING SENSORS, ANGLE MEASUREMENT SYSTEM AND VEHICLE WHEEL ALIGNMENT PROCESS.

PI0602128-0 - 02/01/2006. LASER PORTABLE EQUIPMENT FOR AUTOMOTIVE VEHICLE GEOMETRY AND METHODS

C10300742-1 - 11/10/2003.

IMPROVEMENTS INTRODUCED IN ALIGNMENT EQUIPMENT.

PI0300742-1 - 03/10/2003.

IMPROVEMENT IN ALIGNMENT EQUIPMENT. PI0202870-0 - 25/07/2002.

WHEEL ALIGNMENT AND CONTROL SYSTEM AND WHEEL ALIGNMENT AND CONTROL PROCESS.

MU8002519-6 - 11/11/2000.

ARRANGEMENT IN WHEEL ALIGNMENT EQUIPMENT.

PI9901148-4 - 3/22/1999.

VEHICLE WHEEL ALIGNMENT ANGLE MEASURING PROCESS AND EQUIPMENT.

PI9814339-5 - 21/12/1998.

DEVICE FOR DETERMINING WHEEL AND / OR AXLE GEOMETRY GEOMETRY.

PI9814364-6 - 12/21/1998.

DEVICE FOR DETERMINING WHEEL AND / OR SHEET GEOMETRY OF AUTOMOTIVE VEHICLES.

PI9714230-1 - 12/19/1997.

WHEEL ALIGNMENT METHOD AND DEVICE.

MU7703094-0 - 10/09/1997.

LASER PROJECTOR ARRANGEMENT.

PI9711500-2 - 09/11/1997.

APPARATUS FOR USE IN CAL IBRATION OF AN OTO-ELECTRICAL ALIGNMENT SYSTEM AND CALIBRATION METHOD OF AN OTO-ELECTRICAL ALIGNMENT SYSTEM. 9503169-3 - 8/17/1995.

DEVICE AND INITIALIZATION PROCESS OF A STEERING WHEEL ANGLE DRIVE DEVICE FOR AUTOMOTIVE VEHICLES.

PI8906803-3 - 12/22/1989.

AUTOMOTIVE VEHICLE DRIVING GEOMETRY EQUIPMENT.

PI8300412-2 - 01/21/1983.

WHEEL ALIGNMENT TESTING APPARATUS FOR AUTOMOTIVE VEHICLES. PI8202687-4 - 10/05/1982.

CONVERGENCE MEASUREMENT PROCESS, ALIGNMENT MEASUREMENT PROCESS, CONVERGENCE MEASUREMENT APPARATUS, PAINTING WHEEL ALIGNMENT APPARATUS, POINTING DISPLAY.

PI8202663-7 - 05/07/1982.

STEERING PROJECTOR AND STEERING PROJECTOR. PI7806318-3 - 9/26/1977.

APPARATUS AND PROCEDURE FOR PROVIDING DEVIATION COMPENSATION.

PI7806121-0 - 9/19/1977.

APPARATUS AND ANGLE MEASURING PROCESS. PI780614 9-0 - 9/19/1977.

APPARATUS FOR DETERMINING THE POSITION OF THE FRONT WHEELS OF A VEHICLE AND IMPROVEMENT IN WHEEL ALIGNER.

PI7801264-3 - 3/2/1977.

APPARATUS FOR MEASURING ANGLE OF CONVERGENCE OF FRONT WHEELS OF A MOTOR VEHICLE. KR20090120218 (A) - 2009-11-24. WHEEL ALIGNMENT MEASURING EQUIPMENT KR100926070 (Bl) - 2009-11-11.

WHEEL ALIGNMENT MEASURING APPARATUS OF CAR FOR MEASURING TOE, CAMBER AND CASTER USING ONE POSITION SENSING DEVICE AND LIGHT SIGNAL TRANSMISSION METHOD OF TWO OPPSITE SIDE SENSOR HEADER OF WHEEL ALIGNMENT MEASURING APPARATUS. EP2147278 (Al) - 2010-01-27.

METHOD AND DEVICE FOR OPTICALLY MEASURING AN UNDERCARRIAGE.

ES2331908 (T3) - 2010-01-20

A process for reading fractions of an interval between contiguous photo-sensitive elements in a linear optical sensor

WO2009148389 (Al) - 2009-12-10

POSITIONING OF LIGHT-REFLECTING OBJECT USING SWEEPING

LINE-SHAPED LIGHT BEAMS

KR20090074002 (A) - 2009-07-03

TOE SENSOR ZERO SETTING METHOD OF WHEEL ALIGNMENT SENSOR EP2126510 (Al) - 2009-12-02

METHOD AND APPARATUS FOR THE CONTACTLESS DETERMINATION OF THE SIDE MISALIGNMENT RELATIVE TO A STRAIGHT DIRECTION

US2009279077 (Al) - 2009-11-12 METHODS AND SYSTEMS FOR WHEEL PROFILE MEASUREMENT W02009130103 (A2) - 2009-10-29 CHASSIS MEASUREMENT METHOD AND DEVICE WO2009118214 (Al) - 2009-10-01

CHASSIS-MEASURING SYSTEM AND METHOD FOR DETERMINING THE POSITION OF PARAMETERS OF PROBES OF A CHASSIS-MEASURING SYSTEM

WO2009118211 (Al) - 2009-10-01

PROBE FOR A CHASSIS-MEASURING SYSTEM, CHASSIS-MEASURING SYSTEM AND METHOD FOR DETERMINING THE POSITION OF PROBES OF A CHASSIS-MEASURING SYSTEM EP2048473 (Al) - 2009-04-15

Method and device for measuring angles of wheel and axles W02009056392 (Al) - 2009-05-07

DEVICE AND METHOD FOR CHECKING AN ATTITUDE OF A VEHICLE US2008271328 (Al) - 2008-11-06

Method and Apparatus For Vehicle Service System Optical Target Assembly US2008297777 (Al) - 2008-12-04

METHOD OF AND APPARATUS FOR DETERMINING GEOMETRICAL DIMENSIONS OF A VEHICLE WHEEL US2008273194 (Al) - 2008-11-0

NON CONTACT WHEEL ALIGNMENT SENSOR AND METHOD US200818 6383 (Al) - 2008-08-07

Method and Apparatus For Guiding Placement of Vehiele Service Fixtures DE102008006329 (Al) - 2009-07-30

Verfahren und Vorrichtung zum Überprüfen der Referenzierung von Messköpfen eines

Fahrwerksvermessungssystems EP2109754 (Al) - 2009-10-21

DEVICE FOR THE MEASUREMENT OF UNDERCARRIAGE GEOMETRY WO2008072276 (Al) - 2008-06-19 WHEEL ALIGNMENT DEVICE ADAPTED TO RUNOUT ERROR US2009144993 (A1) - 2009-06-11

OPTICAL SYSTEM AND METHOD OF CENTERING A TREE WITHIN A TREE SPADE US2008086900 (A1) - 2008-04-17

Vehicle wheel alignment system and methodology WO2008150278 (A1) - 2008-12-11

LIGHTWEIGHT WHEEL CLAMP FOR VEHICLE WHEEL ALIGNMENT SYSTEM KR20080037568 (A) - 2008-04-30

WHEEL ALIGNMENT MEASURING APPARATUS EPl930688 (A1) - 2008-06-11

Method for optical chassis measurement WO2008046715 (A1) - 2008-04-24

METHOD FOR DETERMINING THE AXIS OF ROTATION OF A VEHICLE WHEEL WO2008046706 (A1) - 2008-04-24

METHOD FOR MEASURING THE WHEEL OR AXLE GEOMETRY OF A VEHICLE WO2008034209 (A1) - 2008-03-27

SET OF SENSORS DETERMINING ALIGNMENT ANGLES KR20090086933 (A) - 2009-08-14

VEHICLE WHEEL ALIGNMENT SYSTEM AND METHODOLOGY US2009059213 (A1) - 2009-03-05

APPARATUS AND METHOD FOR WHEEL ALIGNMENT WO2008028832 (A1) - 2008-03-13

METHOD FOR DETERMINING DISTANCES FOR MEASURING THE CHASSIS OF A MOTOR VEHICLE AND MEASURING DEVICE, CHASSIS MEASURING DEVICE AND TESTING UNIT WO2008028831 (A1) - 2008-03-13 METHOD FOR LOCATING A GEOMETRIC DETAIL FOR THE DETERMINATION OF THE SPATIAL RESPECT TO A MEASURING DEVICE AND METHOD AND DEVICE FOR DETERMINING THE SPATIAL POSITION OF A WHEEL RIM WITH RESPECT TO A MEASURING DEVICE

US2009216484 (Al) - 2009-08-27

METHOD FOR THE RELATIVE POSITIONING OF AN OBJECT TO BE MEASURED AND OF A MOTOR VEHICLE TO A MEASURING DEVICE, AND MEASURING DEVICE AND A DEVICE FOR MEASURING A CHASSIS

W02008 02882 6 (Al) - 2008-03-13

METHOD FOR MEASURING THE CHASSIS OF A MOTOR VEHICLE, DEVICE FOR MEASURING A CHASSIS AND MOTOR VEHICLE TESTING UNIT

EP2047211 (Al) - 2009-04-15

METHOD FOR THE DETERMINATION OF THE AXLE GEOME TRY OF A VEHICLE

EP1887317 (Al) - 2008-02-13

Method and device for non-contact measurement of the alignment of motor vehicle wheels US2009031782 (Al) - 2009-02-05

Calibration and operation of wheel alignment systems W020090174 93 (Al) - 2009-02-05

WHEEL ALIGNMENT HEAD AND SYSTEM WITH ADVANCED POWER MANAGEMENT

W020090174 92 (Al) - 2009-02-05

FAULT TOLERANT WHEEL ALIGNMENT HEAD AND SYSTEM

W02008015063 (Al) - 2008-02-07

METHOD FOR DETERMINING THE ROTATIONAL AXIS AND THE ROTATING CENTER OF A VEHICLE WHEEL WO2008012173 (A1) - 2008-01-31

OPTICAL MEASUREMENT DEVICE WITH TWO CAMERA UNITS

SE0701245 (A) - 2008-11-23

Hjulinstailning

WO2008143614 (A1) - 2008-11-27

METHOD AND APPARATUS FOR WHEEL ALIGNMENT

DE202007018657 (U1) - 2009-02-26

Fahrwerksvermessungseinrichtung

US7424387 (B1) - 2008-09-09

Method for use with an optical aligner system for positioning a fixture relative to a vehicle

KR100744746 (B1) - 2007-07-25

CENTER POSITION CONTROL APPARATUS FOR TIRE FORMING MACHINE

ES2321562 (T3) - 2009-06-08

Method and device for wheel run-out compensation in axis measurement

EP1798515 (A2) - 2007-06-20

Measuring or reference unit and chassis measurement therewith

W02007077063 (A1) - 2007-07-12

METHOD AND APPARATUS FOR CONTACTLESSLY MEASURING THE AXLE GEOMETRY

W02007080014 (A1) - 2007-07-19

METHOD FOR OPTICALLY MEASURING A CHASSIS

W02007080012 (A1) - 2007-07-19

METHOD FOR OPTICALLY MEASURING A CHASSIS

W02007080011 (A2) - 2007-07-19

METHOD FOR OPTICALLY MEASURING A CHASSIS

US2007081147 (A1) - 2007-04-12 METHOD FOR DYNAMIC MEASURING THE POSITION AND ORIENTATION OF A WHEEL US200712 4 94 9 (Al) - 2007-06-07

Method and Apparatus for Wheel Alignment System Target Projection and Illumination W020070534 62 (Al) - 2007-05-10

RETRO-REFLECTIVE TARGET WAFER FOR A VISUAL POSITION DETERMINATION SYSTEM US2007101595 (Al) - 2007-05-10

Retro-reflective target wafer for a position determination system JP2008102063 (A) - 2008-05-01

VEHICLE WHEEL CENTER POSITION MEASURING DEVICE BY IMAGE PROCESSING DE202006016018 (Ul) - 2006-12-21

Device for measuring vehicle steering system beaver offset has first / second signaling devices that emit optical signals

WO2006124642 (Al) - 2006-11-23 WHEEL ALIGNER MEASUREMENT MODULE ATTACHMENT SYSTEM US2006274303 (Al) - 2006-12-07

Wheel aligner measurement module attachment system EP1845338 (Al) - 2007-10-17

Method of optically scanning the tread surface of a pneumatic tire of a vehicle wheel US2008319706 (Al) - 2008-12-25

Method for the Determination of the Wheel Geometry and / or Axle Geometry of Motor Vehicles EP1845337 (Al) - 2007-10-17

Apparatus for contactless 3D wheel alignment, system and method therefor

1717547 (Al) - 2006-11-02

Method and device for determining the alignment of the wheels of a vehicle

JP2 00 627 6007 (A) - 2006-10-12

WHEEL ALIGNMENT METHOD AND WHEEL FOR MEASUREMENT US2006168827 (Al) - 2006-08-03

Method and device for measuring the steering geometry of vehicles

WO2 00 607 4 02 6 (Al) - 2006-07-13

NON-CONTACT VEHICLE MEASUREMENT METHOD AND SYSTEM JP2007171106 (A) - 2007-07-05

METHOD AND APPARATUS FOR ASSEMBLING ROTARY SLIT BOARD OF ROTARY ENCODER

WO2006073680 (Al) - 2006-07-13

ALIGNMENT SYSTEM WITH LOCKING TURNTABLES AND SKID PLATES GB2428808 (A) - 2007-02-07

An inspection device for vehicle wheel alignment. DE202 005 011165 (U1) - 2005-10-13

Vehicle wheel tracking adjustment test unit has horizontal test rod fixable to steering wheel with rotating mounted Iamp to illuminate scale to wheel rim supports

DE102005032735 (B3) - 2007-02-22 Tire testing device using interferometric measurement, has positioning device arranged in additional chamber allowing tread to be scanned from outside by measuring head

EPl602891 (Al) - 2005-12-07 Support for measuring instruments EPl600731 (Α2) - 2005-11-30

Apparatus and method for measuring the chassis of an engine vehicle with means for automatic adaptation depending on wheel type DE102005022565 (A1) - 2006-11-23

Automatisches Belichtungssystem für ein berührungslos messendes Automobilservicegerãt US2007283582 (A1) - 2007-12-13

Measuring Method and Measuring Unit for Determining the Spatial Position of a Wheel Rim as Well as a Wheel Alignment Measuring System US2005268475 (A1) - 2005-12-08

Method and device for controlling the geometry of the chassis of a chain or belt driven vehicle KR20060090338 (A) - 2006-08-10

ZERO SETTING METHOD AND DEVICE OF WHEEL ALIGNMENT SENSOR DE102005003993 (A1) - 2006-08-31

Trail and camber angle adjusting device for motor vehicle axle, has generator generating laser beam and screen collecting beam, where target position corresponding to preset falling or wheel alignment of axle is defined in screen US2005126021 (A1) - 2005-06-16

Gradient calculating camera board EP1677071 (A1) - 2006-07-05

Multiple axle alignment method and device for trucks DE202004018749 (U1) - 2005-08-04

Tracking measurement system for all-terrain vehicles and quad bikes projects laser line onto measurement strip (s), enabling measurement values to be read off directly and tracking to be adjusted after each pre-adjustment (toe-in or toe-out)

ES2303138 (T3) - 2008-08-01

STEERING WHEEL MEASURING SCALES

US2005188753 (Al) - 2005-09-01

Method of adjusting straight ahead

US2005178015 (Al) - 2005-08-18

Method and device for measuring wheel alignment of car JP2006118922 (A) - 2006-05-11

APPARATUS AND METHOD FOR MEASURING WHEEL ALIGNMENT

TW256922 (B) - 2006-06-21

System for adjusting kidney

US2005068522 (Al) - 2005-03-31

Wheel alignment apparatus and method utilizing three-dimensional imaging

W02005033628 (A2) - 2005-04-14

INVISIBLE TARGET ILLUMINATORS FOR 3D CAMERA-BASED ALIGNMENT SYSTEMS

CN1587 902 (A) - 2005-03-02

Measuring method for plane equation coefficient and wheel positioning device

US2005016003 (Al) - 2005-01-27

Apparatus and method for maintaining wheel alignment sensor runout compensation

KR20060015368 (A) - 2006-02-17

SYSTEM FOR AUTO WHEEL-ALIGNMENT AND METHOD THEREFOR US2006028638 (Al) - 2006-02-09

Method for measuring optically reflective vehicle wheel surfaces WO2005012831 (Al) - 2005-02-10

two-wheel alignment adjustment method WO20041115 69 (Al) - 2004-12-23

WHEEL ALIGNMENT WITH SURFACE-ORIENTED RUNOUT DETERMINATION US2005027473 (Al) - 2005-02-03

Wheel alignment with surface-oriented runout determination US200424 6470 (Al) - 2004-12-09

Image sensing wheel alignment system JP2005326944 (A) - 2005-11-24

DEVICE AND METHOD FOR GENERATING MAP IMAGE BY LASER MEASUREMENT WO2004102114 (Al) - 2004-11-25

TECHNIQUE CAMERA FOR ADAPTIVE CRUISE CONTROL (ACC) ADJUSTMENT SENSOR US2005096807 (Al) - 2005-05-05

Camera technique for adaptive cruise control (ACC) sensor adjustment EPl477766 (Al) - 2004-11-17

Device for measuring differences in track between front wheels and rear wheels of vehicles EP1505367 (A2) - 2005-02-09

Method for evaluating axle geometry and sensor for implementation of said method CA2485543 (Al) - 2005-07-12

WHEEL ALIGNMENT GAUGE US20050054 63 (Al) - 2005-01-13

Self-calibrating position determination system and user interface GB2410565 (A) - 2005-08-03

A measuring unit for a wheel alignment apparatus W02004068072 (A1) - 2004-08-12

CALIBRATION CERTIFICATION FOR WHEEL ALIGNMENT EQUIPMENT

US2004244463 (A1) - 2004-12-09

Calibration certification for wheel alignment equipment

US2004139620 (A1) - 2004-07-22

Method of and apparatus for inspection of vehicle wheel alignment

CA2455066 (A1) - 2004-07-09

METHOD OF AND APPARATUS FOR THE INSPECTION OF VEHICLE WHEEL ALIGNMENT

US2005138823 (A1) - 2005-06-30

Wheel alignment system for single track vehicles

KR20040036674 (A) - 2004-04-30

APPARATUS FOR MEASURING WHEEL ALIGNMENT OF VEHICLE

US2005132587 (A1) - 2005-06-23

Methods for measuring alignment in customized vehicles

US2004172170 (A1) - 2004-09-02

Portable wheel alignment device

W02004051180 (A1) - 2004-06-17

METHOD AND SYSTEM FOR MEASURING CASTER TRAIL

DE20317876 (U1) - 2004-03-04

Montagehilfe zur Instandsetzung von Lenkungs- und Fahrwerksteilen an Kraftfahrzeugen

US2004055169 (A1) - 2004-03-25

Wheel alignment measuring method and apparatus

US2005078304 (A1) - 2005-04-14

Common reference target machine vision wheel alignment system US6823598 (B1) - 2004-11-30

Laser support attachment for vehicle alignment system US200416517 4 (A1) - 2004-08-26

Adjusting device with an optical regulating device having a reflector WO2004025218 (A2) - 2004-03-25

DIAGNOSTIC METHOD AND SYSTEM FOR A MULTIPLE-LINK STEERING SYSTEM DE20320947 (U1) - 2005-09-08

Belt or chain alignment method for use with a chain or belt driven machine, e.g. motorcycle or bicycle, whereby laser beam is used to position the chain on the secondary cog relative to the chain wheel KR20050023956 (A) - 2005-03-10

APPARATUS FOR MEASURING VEHICLE WHEEL ALIGNMENT FOR SIMPLY MEASURING AMOUNT OF TOE AND AMOUNT OF SET BACK WO2004023066 (A1) - 2004-03-18

RETAINING DEVICE FOR A WHEEL-ALIGNMENT ANALYZER WO2004029547 (A1) - 2004-04-08

DIAGNOSING MALFUNCTIONING WHEEL ALIGNMENT SYSTEM US2006156562 (A1) - 2006-07-20

Device for determining the wheel and / or axle geometry of motor vehicles DE10333762 (A1) - 2005-02-17

Vehicle test bed, especially for commercial vehicles, has means for testing headlamp alignment, chassis alignment, tracking and a distance-regulated cruise control system CN1570587 (A) - 2005-01-26

Measuring method and device for intellectualized four-wheel orientator DE10332817 (B3) - 2005-02-10

Verfahren und Fahrzeugprüfstand zur dynamischen Fahrtsimulation JP2004 004108 (A) - 2004-01-08

TARGET SYSTEM FOR USE IN POSITIONING SYSTEM US20050054 61 (Al) - 2005-01-13

Truck alignment system WO2004 01187 9 (Al) - 2004-02-05

A SYSTEM FOR CONTROLLING THE SHAPE AND ALIGNMENT OF WHEELS AND METHOD FOR CONTROLLING THE SHAPE AND ALIGNMENT OF WHEELS EP1361412 (A2) - 2003-11-12

Quick-fit assembly for measuring and centering jigs used for vehicle wheel trim WO0308 987 6 (Al) - 2003-10-30

VEHICLE WHEEL ALIGNMENT BY ROTATING VISION SENSOR US2004 03 95 4 4 (Al) - 2004-02-26

Vehicle wheel alignment by rotating vision sensor KR2004 008 8 816 (A) - 2004-10-20

WIRELESS ADDED WHEEL ALIGNMENT MEASURING APPARATUS MAINLY CONCERNED WITH REDUCING SPACES FOR INSTALLING US2003187610 (Al) - 2003-10-02

Color vision vehicle wheel alignment system US2003131485 (Al) - 2003-07-17

Method and device for automatically adjusting the axle geometry of suspended vehicle in a production Iine US2003225536 (Al) - 2003-12-04

Self-calibrating, multi-camera vision measuring system WO03074963 (Α2) - 2003-09-12

A METHOD AND APPARATUS FOR DETERMINING THE RIDE HEIGHT OF A VEHICLE

GB2385419 (A) - 2003-08-20

Chassis alignment system

US2003147068 (A1) - 2003-08-07

Device for measuring the characteristic attitude parameters of a vehicle

JP2004212365 (A) - 2004-07-29

SYSTEM FOR MEASURING TOW VALUE OF TIRE

JP2004212363 (A) - 2004-07-29

SYSTEM FOR MEASURING TOW VALUE OF TIRE

US20031422 94 (A1) - 2003-07-31

Method and system for measuring trail caster DE10256123 (A1) - 2004-06-17

Track state determination method for determining values representative of railway track condition, especially the rail profile using a light intersection method, whereby a light inspection beam is incident close to the wheel

DE0256122 (A1) - 2004-06-17

Determination of operating states relating to wheel-rail parings of a train and track, e.g. for determining wear of the rail or wheel surface, whereby two optical projection-imaging systems are used to improve diagnosis.

WO0304647 6 (A2) - 2003-06-05

METHOD AND SYSTEM FOR DETERMINING SYMMETRY AND ACKERMANN GEOMETRY STATUS OF THE STEERING SYSTEM OF A VEHICLE

US2003051356 (A1) - 2003-03-20

Target system for use with position determination system US2003025901 (A1) - 2003-02-06

Integrated circuit image sensor for wheel alignment systems US6691062 (B1) - 2004-02-10

Method and apparatus for advising the play on bearings or joints of components coupled to one another EP1281932 (A2) - 2003-02-05

Method and arrangement for measuring a bicycle frame WO03002937 (A1) - 2003-01-09

SELF-CALIBRATION P0SITI0N DETERMINATION SYSTEM AND USER INTERFACE US2003023395 (A1) - 2003-01-30

Self-calibrating position determination system and user interface US2003233758 (A1) - 2003-12-25

Vehicle wheel toe-in alignment apparatus and method WO02103286 (A1) - 2002-12-27

SELF-CALIBRATING POSITION DETERMINATION SYSTEM US2002189115 (A1) - 2002-12-19

Self-calibrating position determination system US67108 66 (B1) - 2004-03-23

Device for determining wheel and / or axle geometry of motor vehicles US20030654 66 (A1) - 2003-04-03

Self-calibrating, multi-camera vision measuring system JP2004012195 (A) - 2004-01-15

METHOD AND DEVICE FOR MEASURING WHEEL ALIGNMENT OF AUTOMOBILE US6748796 (B1) - 2004-06-15 Procedure for determining the dynamic behavior of a vehicle on a test bench US2002162231 (Al) - 2002-11-07

A cordless alignment system having conveniently interchangeable batteries

US2002167 658 (Al) - 2002-11-14

Process for identifying a specific light signal used in a linear optical sensor of goniometer from among other potentially disturbing light signals EP1262742 (A2) - 2002-12-04

A process for calibrating the sensor KR20030069720 (A) - 2003-08-27

APPARATUS AND METHOD FOR ADJUSTING SENSITIVITY OF OPTICAL SENSOR TO MEASURE WHEEL ALIGNMENT DE20202500 (Ul) - 2002-06-27

Vorrichtung zur Anbringung einer Aehsmesseinriehtung an Kfz-Felge

EP1231451 (A1) - 2002-08-14

Gripping device to a pneumatie-tyred wheel for measuring and recording vehicle convergence US6559936 (Bl) - 2003-05-06

Measuring angles of wheels using transition points of refleeted laser lines EP1227299 (Al) - 2002-07-31

Apparatus for measuring the symmetry of a vehicle body ES2221877 (T3) - 2005-01-16

Method and device for detecting the position of a vehicle wheel in a reference system linked to the vehicle

US2003071989 (Al) - 2003-04-17 Apparatus and method for target identification in a vehicle wheel alignment system

FR2830932 (A1) - 2003-04-18

Checking of motor vehicle wheel geometry using an H shaped measurement configuration whereby measurement devices are placed in between vehicle wheels to reduce the cost of measurement apparatus

W002055982 (A1) - 2002-07-18

SYSTEM FOR DETERMINING THE DYNAMIC ORIENTATION OF A VEHICLE WHEEL PLANE

US2002040533 (A1) - 2002-04-11

Method and device for automatically adjusting the axle geometry of a suspended vehicle in a production'Iine

US2003030791 (A1) - 2003-02-13

Portable wheel alignment system

EP1190875 (A2) - 2002-03-27

Suspension system for a vehicle

AU65 61301 (A) - 2002-03-07

180 Method and apparatus for measuring the running gears on a motor vehicle

US2002080343 (A1) - 2002-06-27

Wheel alignment apparatus

EP 16669715 (A1) - 2006-06-14

Chassis measurement device

W00231437 (A1) - 2002-04-18

DEVICE FOR DETERMINING THE WHEEL GEOMETRY AND / OR AXLE GEOMETRY

EP1184 641 (A1) - 2002-03-06

Method and apparatus for measuring the alignment of a vehicle frame WO0214784 (Al) - 2002-02-21

SELF-CALIBRATING 3D MACHINE MEASURING SYSTEM USEFUL IN MOTOR VEHICLE WHEEL ALIGNMENT US2002027651 (Al) - 2002-03-07

Self-calibrating 3D machine measuring system useful in motor vehicle wheel alignment W00212821 (A2) - 2002-02-14

TWO PIECE ALIGNMENT HEAD AU7 3008 01 (A) - 2002-01-08

3d machine vision measuring system with vehicle position adjustment mechanism for positioning vehicle W0020114 9 (A2) - 2002-01-03

MEASURING WHEEL PARALLELISM BASE WITH A POSITION DETERMINATION SYSTEM US2 002 00107 6 (Al) - 2002-01-03

Method and apparatus for measuring vehicle wheel scrub radius US2002020071 (Al) - 2002-02-21

Method and system for driving wheel alignment US2002092183 (Al) - 2002-07-18

Glint-resistant position determination system WO0203027 (Al) - 2002-01-10

GEOMETRICAL WHEEL DATA, GE OME TRICAL AXLE DATA AND BODYWORK DISPLACEMENT DATA COMPRISING WHEEL MARKERS CONFIGURED AT THE PRODUCTION STAGE US6522400 (Bl) - 2003-02-18

Portable front wheel alignment apparatus and method US2002193910 (Al) - 2002-12-19

Method and apparatus for wireless information transfer in vehicle service systems CA2345928 (A1) - 2001-11-09

CHASSIS MEASURING APPARATUS AND METHOD OF MEASURING A CHASSIS WO0181860 (A1) - 2001-11-01

MEASUREMENT OF WHEEL AND AXLE ALIGNMENT OF MOTOR VEHICLES US2002099483 (A1) - 2002-07-25

Measuring wheel base parallelism with a position determination system WO0177617 (A1) - 2001-10-18

MEASURING VEHICLE WHEEL ALIGNMENT WITH VIDEO CAMERAS AND REPEATED APPROXIMATION CALCULATIONS US6404486 (B1) - 2002-06-11

Device for determining the geometry of a wheel and / or axle in motor vehicles US2001022655 (A1) - 2001-09-20

Vehicle alignment sensor system CN1734231 (A) - 2006-02-15

Self-calibrating, multi-camera vision measuring system JP2002257540 (A) - 2002-09-11

TOE VALUE MEASURING DEVICE, TOE VALUE MEASURING METHOD, TOE VALUE MEASURING PROGRAM AND TOE VALUE ADJUSTING METHOD OF AXLE ASSEMBLY US2001009070 (A1) - 2001-07-26

Wheel alignment apparatus US2002088128 (A1) - 2002-07-11

PORTABLE WHEEL ALIGNMENT SYSTEM FOR MOTORCYCLES WO0146909 (A1) - 2001-06-28

METHOD AND APPARATUS OF AUTOMATICALLY IDENTIFYING FAULTS IN A MACHINE VISION MEASURING SYSTEM US64 90800 (B1) - 2002-12-10

Procedure for measuring the wheel angle on steerable vehicles

JP2001124537 (A) - 2001-05-11

ROTATIONAL ANGLE SENSOR FOR ROTATING MEMBER W00123834 (Al) - 2001-04-05

METHOD AND APPARATUS FOR MEASURING VEHICLE WHEEL ROLL RADIUS

US6397164 (Bl) - 2002-05-28

Device for determining the wheel and / or axle geometry of motor vehicles

US7236240 (Bl) - 2007-06-26

Time-resolved photogrammetric measurement of wheel position values

DE10035118 (Al) - 2002-01-31

Procedure and device for the optical scanning of a vehicle wheel

EP1069402 (A2) - 2001-01-17 Tire position detecting device and wheel alignment adjusting device US6657711 (Bl) - 2003-12-02

Vehicle wheel alignment measuring device US6862544 (Bl) - 2005-03-01 Vehicle wheel alignment data by rotating vision sensor FI4796 (Ul) - 2001-01-17 Kõysipyõrán linjauslaite W00070304 (Al) - 2000-11-23 ACTIVE TARGET WHEEL ALIGNER FR2808082 (Al) - 2001-10-26 Method and equipment for acquisition of geometric data concerning the parallelism of the front wheels of the vehicle, comprising bay equipped with projectors of parallel light rays and matrix cameras

W00063639 (A1) - 2000-10-26

STEERING WHEEL CENTERING DEVICE

US6456372 (B1) - 2002-09-24

Steering aligning apparatus and method

HU0200395 (A2) - 2002-06-29

METHOD AND DEVICE FOR AUTOMATICALLY ADJUSTING THE AXLE GEOMETRY OF A SUSPENDED VEHICLE IN A PRODUCTION LINE

US6327785 (B1) - 2001-12-11

Four sensor system for wheel alignment

US6400451 (B1) - 2002-06-04

Non-contact wheel alignment measuring method and system US 64 98 959 (B1) - 2002-12-24

Apparatus and method for controlling a mechanism for positioning video cameras for use in measuring vehicle wheel alignment

US632754 8 (B1) - 2001-12-04

Method of adjusting wheel alignment angles

US6424411 (B1) - 2002-07-23

Optical installation and process for determining relative positions of at least two objects in space

EP1003013 (A1) - 2000-05-24

Determination of the position of the optical axis of a camera

EP1808670 (A2) - 2007-07-18

Optical Determination of Relative Positions of Objects in Space US6252973 (B1) - 2001-06-26

Apparatus and method for determining vehicle wheel alignment measurements from three dimensional wheel positions and orientations FR2799542 (A1) - 2001-04-13

Measuring equipment for testing the geometry of wheeled vehicles, comprising light source, semitransparent plate and charge coupled optical sensor mounted in container with horned light apertures FR2798190 (A1) - 2001-03-09

Device for control and adjustment of the geometry of a vehicles wheels EE9900223 (A) - 2000-04-17

Measuring the unroundness and diameter of railway wheels CA2279565 (A1) - 2000-02-07

AUTOMATED SUSPENSION CORRECTION FOR TWIN I-BEAM SUSPENSIONS US6594600 (B1) - 2003-07-15

Method for calibrating the initial position and orientation of one or several mobile cameras CN2387507 (Y) - 2000-07-12

Optical four-wheel position indicator EP0971205 (A2) - 2000-01-12

Apparatus and method with improved field of view for determining vehicle wheel alignment measurements from three dimensional wheel positions and orientations KR20010003888 (A) - 2001-01-15

METHOD FOR ALIGNING VEHICLE WHEEL US6233837 (B1) - 2001-05-22

Axle alignment using a reflected signal EP0969275 (Α2) - 2000-01-05

Device for mesuring the wheel axles of vehicles US614 8528 (A) - 2000-11-21

Method and apparatus for determining the alignment of motor vehicle wheels

US622 687 9 (Bl) - 2001-05-08

Method of and means for establishing vehicle datum DEl9917359 (Al) - 2000-10-19

Apparatus for laterally recognizing obstacles to driving direction of a vehicle DE19914300 (Al) - 2000-10-05

Alignment measuring device with oblique target EP0945333 (A2) - 1999-09-29

Method and device for measuring the frame of a two wheeled vehicle

KR20000036220 (A) - 2000-06-26

CALIBRATING CAMERAS USED IN ALIGNMENT OF WHEELS US6219134 (Bl) - 2001-04-17

Rolling runout compensation for wheel alignment ES2279597 (Q3) - 2007-08-16

Method and device for measuring the characteristic attitude of angles of a vehicle US6163968 (A) - 2000-12-26

Steering Iash and suspension play testing system JP2000205815 (A) - 2000-07-28

DEVICE AND METHOD FOR, WHEEL THREE-DIMENSIONAL DISPLACEMENT DETECTION AND ALIGNMENT MEASURING INSTRUMENT

KR20000022430 (A) - 2000-04-25 EASY TOE ADJUSTMENT DE29822272 (Ul) - 1999-05-27

Motorradspurlehre

US6412183 (Bl) - 2002-07-02

Wheel alignment measuring instrument

US6134792 (A) - 2000-10-24

Method and apparatus for determining wheel alignment optical target orientation parameters

EP0970361 (Al) - 2000-01-12

APPARATUS AND METHOD FOR DETERMINING AXIAL STABILITY

W099234 51 (A2) - 1999-05-14

COMPUTERIZED AUTOMOTIVE SERVICE SYSTEM

GB2343006 (A) - 2000-04-26

Vehicle wheel alignment checking device

EP1335182 (A2) - 2003-08-13

Vehicle wheel alignment system

EP0994329 (Al) - 2000-04-19

Calibration of a device used for alignment of vehicle wheels

GB2331590 (A) - 1999-05-26

Laser-based device for checking geometry

W09915854 (Al) - 1999-04-01

MACHINE VISION METHODS USING FEEDBACK TO DETERMINE CALIBRATION LOCATIONS OF MULTIPLE CAMERAS THAT IMAGE A COMMON OBJECT

JP11152060 (A) - 1999-06-08

ATTITUDE REGULATING METHOD AND DEVICE OF MOTOR VEHICLE

US6282469 (Bl) - 2001-08-28

Computerized automotive service equipment using serial link multipoint data transmission protocols WO9903018 (A1) - 1999-01-21

APPARATUS AND METHOD FOR ADJUSTING WHEEL ALIGNMENT CAMERA HEIGHT US6298284 (B1) - 2001-10-02

Apparatus and method with improved field of view for determining vehicle wheel alignment measurements from three dimensional wheel positions and orientations US6473978 (B1) - 2002-11-05

Wheel alignment assembly and method US5886350 (A) - 1999-03-23

Multi-axis wheel transducer with angular position detector WO9855827 (A1) - 1998-12-10

COMPENSATION FOR UNDESIRED ANGLE DEVIATIONS ARISING DURING VEHICLE WHEEL ALIGNMENT OPERATIONS JP11051626 (A) - 1999-02-26

METHOD AND INSTRUMENT FOR MEASURING ANGLE OF WHEEL JP11314562 (A) - 1999-11-16

WHEEL ALIGNMENT MEASURING DEVICE AND ROTOR INCLINATION MEASURING DEVICE US6414304 (B1) - 2002-07-02

Method and apparatus for determining the position of a wheel mounted on a vehicle US5886782 (A) - 1999-03-23

Vehicle rear end alignment device FR275575 9 (A1) - 1998-05-15

Wide angle wheel alignment system WO9828594 (A1) - 1998-07-02

DEVICE AND METHOD FOR MEASURING THE ORIENTATION OF A SURFACE W09828595 (Al) - 1998-07-02

METHOD AND DEVICE FOR WHEEL ALIGNMENT JP11165650 (A) - 1999-06-22

POSITION ADJUSTING DEVICE AND POSITION ADJUSTING METHOD DEl97 54 010 (Al) - 1999-06-17

Apparatus for determining an angle between two objects WO9825106 (Al) - 1998-06-11

WHEEL ALIGNMENT SYSTEM US5 94 37 83 (A) - 1999-08-31

Method and apparatus for determining the alignment of motor vehicle wheels US6082011 (A) - 2000-07-04

Laser plane vehicle alignment system US596924 6 (A) - 1999-10-19

Apparatus and method for determining axial stability US5 97 8 07 7 (A) - 1999-11-02

Non-contact method and apparatus for determining camber and caster of a vehicle wheel DEl97 4 82 3 9 (Al) - 1998-05-20

Automobile Wheel Alignment Measurement Machine GB2329256 (A) - 1999-03-17

Viewing system for optical wheel alignment gauge DE19728509 (Al) - 1999-01-07

Method of measuring railway vehicle wheel profiles US6209209 (Bl) - 2001-04-03

Rolling run-out measurement apparatus and method JP11014332 (A) - 1999-01-22

DISPLACEMENT DETECTING DEVICE, THREE-DIMENSIONAL DISPLACEMENT DETECTING DEVICE, WHEEL ALIGNMENT MEASURING DEVICE, DISPLACEMENT DETECTING METHOD AND THREE-DIMENSIONAL METHOD WO9744635 (A1) - 1997-11-27

APPARATUS AND METHOD FOR DETERMINING VEHICLE WHEEL ALIGNMENT MEASUREMENTS FROM THREE-DIMENSIONAL WHEEL POSITIONS AND ORIENTATIONS US5870315 (A) - 1999-02-09

Apparatus and method for determining vehicle wheel alignment measurements from three dimensional wheel positions and orientations US5886781 (A) - 1999-03-23

Device for the geometric inspection of vehicles CNl172944 (A) - 1998-02-11

Method and device for detecting vehicle wheel base difference PL318831 (A1) - 1998-08-31

METHOD OF AND APPARATUS FOR MEASURING TOE IN OR TOE OUT WELL AS CAMBER ANGLES OF AUTOMOBILE WHEELS JP10197230 (A) - 1998-07-31

METHOD AND DEVICE FOR MEASURING WHEEL ALIGNMENT US5815257 (A) - 1998-09-29

Portable optical wheel alignment apparatus and method for race cars US5731870 (A) - 1998-03-24

Intelligent sensor method and apparatus for optical wheel alignment machine PL317166 (A1) - 1997-05-12

METHOD OF MEASURING 0VERHEAD TRAVELING CRANE WHEEL ALIGNMENT AND SET OF EQUIPMENT THEREFOR JP10007045 (A) - 1998-01-13

METHOD FOR INDICATING ARRANGED CONDITION OF WHEEL ΕΡ0769676 (Α2) - 1997-04-23

Custom vehicle wheel aligner WO9714016 (A1) - 1997-04-17

METHOD AND APPARATUS FOR DETERMINING THE ALIGNMENT OF MOTOR VEHICLE WHEELS PL105400 (U1) - 1997-04-01

MEASURING UNIT FOR CHECKING AND MEASURING GEOMETRY OF WHEEL ALIGNMENT PL105399 (U1) - 1997-04-01

FIXING CLAMP FOR ATTACHING MEASURING UNITS TO WHEEL RIMS AU6803796 (A) - 1997-01-16

Wheel alignment system AU703528 (B2) - 1999-03-25

Wheel alignment system US5648846 (A) - 1997-07-15

Apparatus and method for the geometric measurement of a vehicle EP0766064 (A2) - 1997-04-02

Vehicle wheel alignment testing US5909379 (A) - 1999-06-01

Custom vehicle wheel aligner US5948024 (A) - 1999-09-07

Vehicle alignment condition measurement and display SE9603459 (A) - 1998-03-24

Satt och anordning for f aststâllande av ett fordons framvagnsvinklar speciellt s cat cats-, kpi- och styrutslagsvinklarna US5809658 (A) - 1998-09-22

Method and apparatus for calibrating cameras used in the alignment of motor vehicle wheels US5724129 (A) - 1998-03-03

Method for determining vehicle wheel alignments

US5852241 (A) - 1998-12-22

System for measuring wheel angles and chassis units positions of a vehicle

JP1008 0192 (A) - 1998-03-24

PULSE ENGINE CONTROL EQUIPMENT, WHEEL ALIGNMENT MEASURING EQUIPMENT, PULSE ENGINE CONTROL METHOD AND WHEEL ALIGNMENT MEASURING

JP10073422 (A) - 1998-03-17

CASTLE ANGLE MEASURING DEVICE, WHEEL ALIGNMENT MEASURING, CASTER ANGLE MEASUREMENT, AND WHEEL ALIGNMENT MEASUREMENT

W09709583 (A2) - 1997-03-13

APPARATUS AND METH0D FOR WHEEL ALIGNMENT, SUSPENSION DIAGNOSIS AND CHASSIS MEASUREMENT OF VEHICLES

US5812256 (A) - 1998-09-22 Vision system for wheel alignment

KR200143972 (Yl) - 1999-06-15

DEVICE OF PREVENTING WHEEL ALIGNMENT SENSOR FROM FALLING

JP10047940 (A) - 1998-02-20

MEASURING PLATE, AND DEVICE AND METHOD FOR MEASURING WHEEL ALIGNMENT

US6075589 (A) - 2000-06-13 Device for the geometric measurement and inspection of wheeled vehicles

US5817 951 (A) - 1998-10-06

Multi-axis wheel transducer with angular position detector

EP0819910 (A1) - 1998-01-21 The method and system for measuring the wheels of a vehicle US61819 93 (B1) - 2001-01-30

Four sensor system for wheel alignment DE19623982 (C1) - 1997-09-04

Apparatus to check vehicle front wheel toe = in angles JP10002726 (A) - 1998-01-06

MEASURING PLATE AND DEVICE AND METHOD FOR MEASURING WHEEL ALIGNMENT JP9329433 (A) - 1997-12-22

NON-CONTACT ALIGNMENT MEASURING DEVICE FOR VEHICLE WHEEL US5675515 (A) - 1997-10-07

Apparatus and method for determining vehicle wheel alignment measurements from three dimensional wheel positions and orientations PL104593 (U1) - 1996-10-14

EXTERNAL LIGHT BEAM DEFLEXION ASSEMBLY FOR MEASURING INSTRUMENTS PL104592 (U1) - 1996-10-14

INTERNAL LIGHT BEAM DEFLEXION ASSEMBLY FOR MEASURING INSTRUMENTS US5781286 (A) - 1998-07-14

Method and apparatus for measurement of axle and wheel positions of motor vehicles JP9280843 (A) - 1997-10-31

NON-CONTACING TYPE ALIGNMENT MEASURING DEVICE OF VEHICLE'S WHEEL JP8285573 (A) - 1996-11-01

EQUIPMENT AND METHOD FOR WHEEL ALIGNMENT JP9250914 (A) - 1997-09-22 MEASURING DEVICE FOR WHEEL ALIGNMENT CA2171352 (A1) - 1996-09-11

METHOD AND APPARATUS FOR MEASURING THE DYNAMIC CAMBER OF VEHICLE TIRES WO9621840 (A1) - 1996-07-18

DETERMINING VEHICLE WHEEL ALIGNMENT POSITIONS AND ORIENTATIONS JP9159426 (A) - 1997-06-20

WHEEL ALIGNMENT MEASURING APPARATUS FOR VEHICLE JP9133510 (A) - 1997-05-20

WHEEL ALIGNMENT MEASURING METHOD US5786751 (A) - 1998-07-28

System for monitoring alignment of wheels using a photoelectric sensor FR2739923 (A1) - 1997-04-18

Car wheel geometry testing bench US5724743 (A) - 1998-03-10

Method and apparatus for determining the alignment of motor vehicle wheels PL57509 (Y1) - 1999-11-30

MEASURING HEAD WITH MOUNTING ASSEMBLY MEASURING HEAD WITH MOUNTING ASSEMBLY PL103528 (U1) - 1997-04-14

APPARATUS FOR CHECKING WHEEL ALIGNMENT IN MOTOR VEHICLES CZ4789 (U1) - 1996-07-17

Measuring system of optical-mechanical apparatus FR2721109 (A1) - 1995-12-15

Multi-axis wheel transducer appts. esp. for measuring loads and torque acting on vehicle wheels US5600893 (A) - 1997-02-11 Process and system for measuring alignment of automotive vehicle suspension

FR2735861 (Al) - 1996-12-27

Vehicle wheel trains geometry measuring device US5598358 (A) - 1997-01-28

Apparatus and method for calibrating vehicle wheel alignment instruments

US5748301 (A) - 1998-05-05

Device and process for the geometric inspection of wheeled vehicles

US5532824 (A) - 1996-07-02 Optical motion sensor

US5489983 (A) - 1996-02-06

Sensor for vehicle alignment system and apparatus using same

ITMI950173 (Al) - 1995-08-01 Vehicle wheel alignment appts.

US56754 08 (A) - 1997-10-07

Device and method for measuring wheel angles US5625953 (A) - 1997-05-06

Clamping device for vehicle wheel alignment equipment

WO9515479 (A1) - 1995-06-08

VEHICLE ALIGNMENT SYSTEM

US5583797 (A) - 1996-12-10

Method and apparatus for wheel alignment audit

US5 63 6016 (A) - 1997-06-03

Apparatus and method for the geometric inspection of vehicles with steered wheels

DE 9417 467 (Ul) - 1994-12-15 Drehimpulsgeber DE4438837 (Al) - 1996-04-25

Rotation sensor with shaft carrying incremental disc

JP8105731 (A) - 1996-04-23

WHEEL-ALIGNMENT MEASURING APPARATUS

EP0647829 (Al) - 1995-04-12

Process and device for the geometric control of a vehicle.

FR27112 65 (Al) - 1995-04-21

System for controlling service devices for motor vehicles

DE4 4,3312 6 (Al) - 1995-03-23

Self-calibrating wheel aligning device and method therefor

PL56374 (Yl) - 1998-08-31 MEASURING ASSEMBLY OF AN OPTO-MECHANICAL INSTRUMENT

US5540108 (A) - 1996-07-30

Multi-axis wheel transducer with angular position detector

DE 4 4 27483 (Cl) - 1995-11-30

Measurement of alignment of wheels and axles on motor vehicle

DE 4 419584 (Al) - 1995-12-07

Dynamic contactless angle determination for rotating bodies, e.g. tracking-toe angle of motor vehicle wheel US555338 9 (A) - 1996-09-10

Appartus and method for adjusting vehicle to alignment alignment

DE4 41219 6 (Al) - 1995-10-19

Measuring instrument axle attachment adapter for motor vehicle wheel US5532816 (A) - 1996-07-02

Laser tracking wheel alignment measurement apparatus and method

CZ9400472 (A3) - 1995-02-15

OPTIC — ELECTRONIC INSTRUMENT FOR CHECKING AND MEASURING OF AUTOMOBILE WHEEL GEOMETRY AND TEST METHOD EMPLOYING SAID INSTRUMENT

EP0611948 (A1) 1994-08-24

System for measuring the wheel base of an automobile frame and the transverse and longitudinal offsets of its steered wheels.

EP0611947 (A2) - 1994-08-24

System for measuring the characteristic attitude angles of the wheels of an automobile frame, and relative measurement means.

KR0129271 (B1) - 1998-04-08

MEASURING METHOD AND APPARATUS FOR WHEEL TOE DE4343624 (A1) - 1994-08-04

Verfahren zur Datenübermittlung in

Ausrichtungsvorrichtungen und Ausgleichsvorrichtungen zur Realisierung des Verfahrens GB2285872 (A) - 1995-07-26

Wheel alignment apparatus US5453839 (A) - 1995-09-26

Optoelectronic measuring scale FR27114 23 (Al) - 1995-04-28

Method and device for eheeking the geometry of a vehiele ES2094 4 4 7 (T3) - 1997-01-16

It should ealibrate measuring-units to determine to-, camber- and flack of vehiele wheels in a driving-rack.

590593067 (A1) - 1994-04-20

Procedure and device for the determination of the orientation and position of objects with laserbeams.

FR2711238 (A1) - 1995-04-21

Angular measurement device, in particular for checking the geometry of vehicles

US5586062 (A) - 1996-12-17

Vehicle wheel alignment utilizing wheel offset and body center line

US54 43537 (A) - 1995-08-22

Method of balancing and aligning wheels on trucks

US5535522 (A) - 1996-07-16

Method and apparatus for determining the alignment of motor vehicle wheels

FR2695994 (A1) - 1994-03-25

Wheel alignment system for measuring alignment angles of wheels

DE4320311 (C1) - 1995-01-05

Method and device for wheel alignment and chassis alignment of motor cycles

US5388057 (A) - 1995-02-07

Apparatus and method for determining shim changes to adjust caraber and caster of vehicle wheel

US54 4 69 67 (A) - 1995-09-05

Mounting apparatus US5335420 (A) - 1994-08-09

Wheel alignment system US55284 96 (A) - 1996-06-18

Vehicle alignment system and method incorporating digital photograph database of vehicles

PL54994 (Y1) - 1997-03-28

MEASURING ASSEMBLY OF AN APPARATUS FOR WHEEL ALIGNMENT CHECKS

PL298583 (A1) - 1993-09-20

METHOD OF CALIBRATING AUTOMOBILE REAR WHEELS GEOMETRY

MEASURING ASSEMBLY AND DEVICE THEREFOR AU3674193 (A) - 1993-10-14

Sensing of wheel parameters US5425523 (A) - 1995-06-20

Apparatus for establishing predetermined positions of one element relative to another

JP6016151 (A) - 1994-01-25

DEVICE AND METHOD FOR ADJUSTING WHEEL ALIGNMENT BASED ON VEHICLE RIDE HEIGHT

US5313711 (A) - 1994-05-24

Wheel alignment system WO9314369 (A1) - 1993-07-22

PIVOTING TRAY DEVICE AND WORKSHOP EQUIPMENT PROVIDED WITH SUCH DEVICE

DE4243104 (A1) - 1993-06-24

Wheel alignment system for measuring alignment angles of wheels

AU2 98 4 4 92 (A) - 1993-06-24

AUTOMOTIVE SERVICE EQUIPMENT EXPERT SYSTEM US5327 655 (A) - 1994-07-12

Method and apparatus for vehicle alignment JP5193517 (A) - 1993-08-03

METHOD FOR COMPENSATION OF SKETCH AND CASTER TO READING OF CASTER AND CAMBER JP5193516 (A) - 1993-08-03

METHOD AND APPARATUS FOR CROSSTALK COMPENSATION IN WHEEL ALIGNMENT SYSTEM EP0581990 (Al) - 1994-02-09

Wheel alignment measuring apparatus. DE69220789 (T2) - 1997-11-27

Radstellungsmessvorrichtung US52 4,377 66 (A) - 1993-09-14

WHEEL ALIGNMENT MEASUREMENT SYSTEM GB2258315 (A) - 1993-02-03

WHEEL ALIGNMENT MEASUREMENT SYSTEM JP6011420 (A) - 1994-01-21

WHEEL ALIGNMENT MEASURING METHOD FOR AUTOMOBILE DE4217702 (Al) - 1993-11-25

Vehicle contactless wheel center, camber and tracking measurement - using mobile CCD cameras and lighting to produce symmetrical image or images. WO9219932 (Al) - 1992-11-12

A SYSTEM FOR MEASURING THE SETTINGS OF VEHICLE WHEELS DE4212426 (Cl) - 1993-07-01

Measurement of tracking and camber of vehicle wheel axles - recording markers on rotating wheels using synchronized video cameras, image evaluation of marker positions

JP5288535 (A) - 1993-11-02

No title available US517 97 84 (A) - 1993-01-19

Wheel alignment device US5274433 (A) - 1993-12-28

Laser-based wheel alignment system US52 912 64 (A) - 1994-03-01

Method and apparatus for the optical measurement of an angle between positions of components relative to each other

US5177558 (A) - 1993-01-05 Wheel alignment apparatus US5174032 (A) - 1992-12-29 Universal wheel gauge US5295073 (A) - 1994-03-15 Device for checking the position of various points of a vehicle

US5105547 (A) - 1992-04-21

METHOD OF AND APPARATUS FOR MEASURING THE WHEEL ALIGNMENT OF AUTOMOTIVE VEHICLES FR2665256 (Al) - 1992-01-31

DEVICE AND PROCEED POUR MESURER UN ANGLE. JP4232410 (A) - 1992-08-20

METHOD AND APPARATUS FOR MEASURING ANGLE REALTION OF AUTOMOBILE WHEEL JP7103738 (A) - 1995-04-18

DEVICE FOR MEASURING ANGULAR RELATIONSHIP OF AUTOMOBILE WHEEL

Wheel alignment method RU2011162 (C1) - 1994-04-15 US516517 9 (A) - 1992-11-24

METHOD AND DEVICE FOR TESTING DEFORMATION OF AUTOMOBILE

BACK AXLE BEAM

FR265828 6 (Al) - 1991-08-16

LICHTABTASTSYSTEM FUER EINE MESSUNG EINER RICHTUNG UND PHYSIKALISCHER MERKMALE EINES WERKSTUECKS DE4039881 (Al) - 1992-06-17

Method and device for optical measurement of an angle and positions of structures, particularly wheel positions in automobiles. JP4177116 (A) - 1992-06-24

APPARATUS FOR MEASURING WHEEL ALIGNMENT W09100982 (A2) - 1991-01-24 LASER-BASED WHEEL ALIGNMENT SYSTEM DE4 019694 (Al) - 1992-01-09 Light sensor conductor for automatic wheel alignment monitoring - has light conductors in bands connected via photodiodes to evaluate computer US5056231 (A) - 1991-10-15

Apparatus for locking wheel unit in automotive wheel alignment system

JP3128803 (U) - 1991-12-25 No title available JP3017502 (A) - 1991-01-25

POSITIONAL INSPECTION DEVICE FOR MEASURING POINT IN CAR JP3243805 (A) - 1991-10-30

WHEEL ALIGNMENT MEASURING INSTRUMENT FOR AUTOMOBILE JP2247512 (A) - 1990-10-03 WHEEL ALIGNMENT DATA MEASURING DEVICE JP3237307 (A) - 1991-10-23 WHEEL ALIGHMENT MEASURING INSTRUMENT FOR AUTOMOBILE SU1704159 (Al) - 1992-01-07

DEVICE FOR AUTOMATIC CENTERING OF OPTICAL COMPACT DISK US504 6032 (A) - 1991-09-03 Calibration bar SU1762120 (Al) - 1992-09-15 STAND FOR WHEEL SETTING ANGLE TESTING AND CONTROLING FOR TRANSPORTING CARRIAGE AU2818689 (A) - 1989-06 -14 PORTABLE AXLE AND FRAME ALIGNMENT TOOL JP3122511 (A) - 1991-05-24

ANGLE DETECTOR FOR WHEEL ALIGNMENT APPARATUS US5014227 (A) - 1991-05-07

Caster and steering axis inclination measurement technique N0892920 (A) - 1989-09-06

BAERBART AKSEL- OG RAMMEJUSTERINGSREDSKAP. US4942667 (A) - 1990-07-24 Portable axle and frame alignment tool JP3115123 (U) - 1991-11-27 No title available

GB2230344 (A) - 1990-10-17

Wheel alignment measuring equipment SU1663387 (A2) - 1991-07-15

DEVICE FOR DETERMINING AXIS OF SYMMETRY OF PIECE JP2121482 (U) - 1990-10-02 No title available SU1728655 (Al) - 1992-04-23

METHOD FOR CHECKING WHEEL CAMBER AND TOE-EP0317839 (Al) - 1989-05-31 Electronically aided compensation apparatus and method. JP187408 (A) - 1989-07-26

DEVICE AND METHOD OF MEASURING WHEEL ALIGNMENT CHARACTERISTIC US4897926 (A) - 1990-02-06 Vehicle wheel turning angle gauge US4 9014 4 2 (A) - 1990-02-20 Vehicle wheel toe-in testing device US4 918821 (A) - 1990 -04-24 Method of determining wheel alignment US4 8 99218 (A) - 1990-02-06

Vehicle wheel alignment apparatus and method AU1314 2 8 8 (A) - 1989-10-05

METHOD AND ARRANGEMENT FOR THE MEASUREMENT OF WHEEL ALIGNMENT ANGLES IN THE FRONT AXLE AND SUSPENSION ASSEMBLY OF A VEHICLE ENGINE JP63247606 (A) - 1988-10-14

WHEEL ALIGNMENT DEVICE FOR CAR AND METHOD THEREOF US4 8 4 4 609 (A) - 1989-07-04

Apparatus and method for aligning elements of a drive train of a vehicle, especially a heavy-duty, Ioad-carrying vehicle SU1542195 (Al) - 1996-03-20 DEVICE TESTING LENS CENTERING US4854702 (A) - 1989-08-08 Vehicle wheel alignment apparatus and method of use JP1131408 (A) - 1989-05-24

METHOD AND DEVICE FOR MEASURING WHEEL ALIGNMENT FR2 60 6503 (Al) - 1988-05-13 Wheel alignment apparatus for vehicles US4863267 (A) - 1989-09-05

Fiber optic toe / track measurement system GB22104 67 (A) - 1989-06-07 Alignment gauge KR94 00007 67 (Bl) - 1994-01-29 METHOD AND APPARATUS FOR MEASURING VEHICLE WHEEL ALIGNMENT

US4 8 98 464 (A) - 1990-02-06

Method and apparatus for determining the position of an object

GB2207519 (A) - 1989-02-01 Wheel alignment apparatus JP6317 07 04 (U) - 1988-11-07 No title available US4759133 (A) - 1988-07-26 Method and apparatus for automotive wheel alignment US4 7 617 4 9 (A) - 1988-08-02

Vehicle wheel alignment apparatus and method AU67 50987 (A) - 1987-07-23 WHEEL ALIGNMENT APPARATUS US4803785 (A) - 1989-02-14 Wheel alignment apparatus US4 827 623 (A) - 1989-05-09

Apparatus for determining the alignment of vehicle wheels

IT1973 63 (B) - 1988-11-30

Angle-measuring device and apparatus for measuring axial geometry parameters HU45774 (A2) - 1988-08-29

OPTICAL MEASURING APPARATUS FOR GEOMETRIC MEASUREMENT AS WELL AS CONTROL OF TWO CIRCULARLY Y YME T RI CAL BODIES, PREFERABLY A PAIR OF RAILWAY WHEELS, SITUATED SYMMETRICALLY WITH RESPECT TO A MEDIUM PLANE JP63035 1990-08208-8-9-139-8-9-13 (Al) - 1989-01-23 METHOD OF MEASURING ADJUSTMENT ANGLES OF ENGINE VEHICLE WHEELS

JP63011807 (A) - 1988-01-19

WHEEL ALIGNMENT MEASUREMENT FOR AUTOMOBILE DE3619931 (Cl) - 1987-10-29

Device for optical alignment measurement between two variously rotatable shafts JP62175607 (A) - 1987-08-01

METHOD AND APPARATUS FOR MEASURING WHEEL ALIGNMENT FR2566897 (Al) - 1986-01-03

ARRANGEMENT FOR MEASURING WHEEL ALIGNMENT AND STEERING GEOMETRY IN AN AUTOMOBILE US4718759 (A) - 1988-01-12

Apparatus for alignment and balance of wheels of a motor vehicle

US4594789 (A) - 1986-06-17 Wheel alignment system SU1427175 (Al) - 1988-09-30

METHOD OF CHECKING RELATIVE POSITION OF AXES OF CYLINDRICAL LENS SURFACES US4 57 4 4 90 (A) - 1986-03-11

Wheel alignment system with bali joint wear monitor and method

SU1280303 (Al) - 1986-12-30 DEVICE FOR OPTICAL ALIGNMENT OF COMPONENTS US4 5 4 512 8 (A) - 1985-10-08

Apparatus for checking alignment of tandem flangeless monorail wheels US4 615618 (A) - 1986-10-07 Apparatus for determining relationship of vehicle thrust line, and body center

US4573275 (A) - 1986-03-04

Arrangement for the mounting of measuring devices for axle measurement equipments EP0120329 (A2) - 1984-10-03 Beam scanning system. DK52884 (A) - 1985-08-08

Apparatus for measuring the wheel angles of a car US4 4 982 4 4 (A) - 1985-02-12

Target including sliding scale US4500201 (A) - 1985-02-19 Individual toe measuring system MX1552 4 4 (A) - 1988-02-09 Determining toe of rear and front vehicle wheels W08401213 (Al) - 1984-03-29

DETERMINING TOE OF REAR AND FRONT VEHICLE WHEELS AT33307 (T) - 1988-04-15

SPURMESSUNG DER HINTEREN UND VORDEREN RADSAETZE EINES AUTOMOBILS.

US4 534115 (A) - 1985-08-13 Vehicle wheel location device JP59103208 (U) - 1984-07-11 No title available USRE33144 (E) - 1990-01-09

Vehicle wheel alignment apparatus US4424700 (A) - 1984-01-10

Calibration fault detector and automatic calibrator State of the art considerations.

Of all the technologies created for such types of vehicle measurements, those based on optical systems stand out, in which angles are measured through infrared light sources that focus on a goniometer, which concentrates the light beam on a CCD sensor. . Tilt sensors (pendulum or liquid) are also used to measure some angles such as caster and wheel tilt. Figure 19 is a simple illustration of this system. These heads are fixed by means of a clamping jaw on each of the vehicle's wheels. The specific angles of each wheel are measured using the inclinometer. Already the angles between the wheels are measured through the optical system with goniometer and CCD sensor.

It happens that these systems are precise but quite delicate and require considerable investments, which makes them limiting, because this level of investment restricts the number of users with modest capital to provide such services. The fact that they are delicate requires periodic calibrations that are performed by skilled technicians. The user can hardly verify if the instrument is calibrated or not. Often he only realizes that there is a calibration problem when the vehicle has problems (symptoms as described above) after the service is performed.

Objectives of the Invention.

The main object of the invention is to provide a new concept for reading angles, logically replacing the measuring instruments by infrared light sources. To this end, four reading heads, equally equipped with electronic resources, have been created. that each of them may preferably have three electronic gyros for XYZ angle detection. Each read head includes features to be fixed to the center of the vehicle wheel, so using 4 objects with 3 gyros each (3 coordinates) we can get the angles between the 4 objects in 3 coordinates.

Another object of the invention is to provide a calibration base that acts as a permanent template for automatic calibration of said measuring heads after use, that is, at an initial moment the reading heads are in the template where all angles will be equal to zero. In a second moment, the said heads are fixed to the wheels of the vehicle and, as a result, all angles will be calculated on each axle and on each head.

Another object of the invention is the embodiment of a substantially reduced cost equipment, hence the investment is smaller and suitable for those skilled in the art.

Another object of the invention is the realization of equipment that does not require periodic calibrations performed by a specialized technician, since, considering that the reading heads always return to the template after each measurement, we can say that the system is self-calibrating, which further reduces Plus your cost.

It is also an object of the invention to realize functional equipment which, from the users' point of view, the system does not require major changes in use compared to traditional systems, ie those who already use traditional systems will not need to learn new things to use The new product.

Advantageously in the present invention the heads will be smaller and lighter than traditional systems and therefore less susceptible to breakage caused by falls.

Description of the drawings.

For a better understanding of the present invention, a detailed description of the invention is given below, with reference to the accompanying drawings:

FIGURES 1 to 19 are illustrations showing the different measurements on suspension of a four-wheeled vehicle;

FIGURES 20-24 show schematic illustrations for understanding an electronic gyroscope;

FIGURE 25 illustrates a perspective view highlighting the calibration base and measuring heads in accordance with the present invention;

FIGURES 26-28 are a block diagram of the assembly;

FIGURE 29 is a schematic perspective view of the measuring head; and the

FIGURE 30 reproduces a perspective showing a usual grip used to secure the measuring head to the corresponding vehicle wheel.

Detailed description of the invention. In accordance with these illustrations and their details, the present invention, apparatus for measuring the geometrical elements of a vehicle suspension, is characterized by the use of electronic gyros for measuring angles, as gyros are known to be instruments. whose operation is based on: conservation of angular momentum in direction and direction; inertial moment; and precession movement.

Figure 20 is a schematic illustration to exemplify the operation of an electronic gyroscope (11), as there are currently chips that are electronic gyros and function based on the Coriolis Principle. Basically these circuits generate an output voltage that is directly proportional to the angular velocity of their main axis (Z).

Thus, as exemplified in Figure 21, considering an angle θ initially equal to zero (fixed reference), it is possible to calculate the value of angle θ by integrating ω in time, ie Θ = J Qdt.

Thus, we can have a circuit to calculate this integral in real time, where we can get the value of θ at a given time tm, where tm is the time that defines the new position of the chip in which the angle Θ is to be obtained.

As shown in Figure 22, it is also possible to fix two or three of these electronic chips or gyros (11) on a single object, with axes in 3 Cartesian coordinates, therefore, it is possible to measure the angular displacement of the object in 2 or 3 axes. different and perpendicular axes to each other.

Considering also the figure 23, using a template capable of aligning two or more objects with these (3 axes), where we can determine that the initial angles are all equal and equal to zero, and then we move and fix these Objects in another position (tm) have their respective angles of displacement relative to the template, as exemplified in Figure 23, where only two objects with a gyroscope are illustrated. In this case the angle between OBl and 0B2 will be Θ1 + Θ2.

As shown in figure 24, using 4 objects, each with 3 gyros (3 coordinates). In this condition, it is possible to obtain the angles between the 4 objects in 3 coordinates at the measurement position (t = tm), consequently, this methodology applies to the measurement of the geometry elements of a vehicle suspension.

Thus, taking into consideration Figure 25, briefly, at an initial moment (t = 0) the objects are in the template where all angles will be equal to zero. In a second moment (t = tm) the objects are fixed to the wheels of the vehicle, as in figure 24. Then all angles will be calculated by the integral between 0 and tm on each axle and on each object.

Adopting the aforementioned technology, the present invention is characterized in that it comprises, as illustrated in Figures 25 and 26, a calibration base (1) which, on the one hand, is electronically interconnected with a standard computer (2). ) and, on the other hand, includes coupling / uncoupling means and electronic interconnection with four measuring heads (3), one left front head DE (a), one right front head DD (b), one left rear head TE ( c) and a right rear head TD (d), such elements being interconnected according to the diagram of figure 26.

The calibration base (1) is the system concentrator. It makes the initial reference, feeding or re-loading of the heads (3), controls the processes that are taking place in the system, coordinates the interfaces with the heads and with the computer. To this end, it has its own electronic circuit whose architecture comprises, as shown in the block diagram of Figure 27, a microcontroller (4) which, in addition to the corresponding power supply (5), also has interconnections (6) and (7). or 8), the first with the computer (2), while the other two are for communication with the heads (3abcd), which can optionally be wired or wireless. Wired serial type RS232, USB, RS485, CAN or other system compatible. Wireless bluetooth, zigbee, miwi, wifi or other compatible with the system.

Said calibration base also includes head coupling sensors (9) (Iabcd) and loader circuit (10) of said heads.

As shown in figures 28 and 29, the four heads will have similar structures and functionality, each must have a microcontroller to measure, send data to the base and manage a basic user interface for measurement. The main features are:

-Sensors for measuring angles;

-Calculations and filters related to measurements;

-Batteries;

-User interface display;

-Buttons for performing the functions;

-Communication with the base (wireless or cable);

-Keys controls for position recognition on the base and wheel holder; and

-Error warning sounds;

Referring also to Figure 28, each measuring head (1) has the corresponding microcontroller (13), with which a set of 3 electronic gyroscopes are interconnected, one for the X axis (12a), one for the Y axis (12b). ) and the other for the Z axis (12c), arranged on printed circuit boards, where the front also includes inclinometer (14), optional three-axis accelerometer (15), optional electronic compass (15a), position sensor ( 16), battery (17), a display (18), keys (19) for user interface, on this board will be the microcontroller (13) and the connections for wired or wireless communication (7-8), while Two other plates with gyro sensors for the other axes will be mounted on a relief built to ensure orthogonality.

Referring to figures 29 and 30, each head (3) has all its electronics mounted in an airtight housing (20) with an upper clamping handle (21), guide hole (22) in alignment with the base (1) as It also includes a bearing-type rear bearing to engage the base (1) and the usual claw (23) of the corresponding head to the vehicle wheel. The handle (21) at the top prevents the head from turning once fixed. Another constructive detail is the possibility of different holes and fittings with sensors for the base and the grip, so the system can automatically recognize if the head is on the calibration base, the measuring grip or in transport.

The calibration base (1) is a true zero jig, preferably made in the form of an amount of pipes and plates, with means for fixing to the floor and with plumb leveling accuracy. This template will have pins / shafts at its top for fixing the measuring heads through the rear hole. These holes must have a very precise parallelism in the 3 coordinates, because this condition will be the reference of the heads zero (3).

In addition to these basic elements, as illustrated in Figure 30, there are also the usual clamps (23) for securing the measuring heads (3) to the vehicle wheels and another electronic device (interface) whose purpose is to interface between the heads and a computer.

The fact that the heads have displays, buttons and a microcontroller allows angle readings to be made through the display of each head as well.

Functional aspects of the device Step 1: The calibration heads (3abcd) are placed in the calibration base (1). At this point, electronics identifies that the heads are in the jig and therefore zeroes all angles. Identification can be done automatically through a sensor or manually through the buttons.

Step 2: Place the claws (23) on the wheels of the vehicle.

Step 3: Remove the heads (3) from the calibration base (1) and insert them into the respective claws (23) attached to the vehicle wheels. After the head is removed from the template, the electronics starts calculating the angles of the 3 axes and transmits / displays the calculated angle information over time.

Step 4: Through the display information, the operator should level the head and lock the bearing shaft through the handle (21). In this situation, the device already shows the valid angle measurements.

Step 5: Once the measurements have been completed, you can go back to step 1 to perform a new operation.

As can be seen from the foregoing and illustrated, the present APPLIANCE IMPROVEMENT FOR MEASURING GEOMETRIC ELEMENTS OF A VEHICLE SUSPENSION has a simplified construction and therefore results in an instrument with a substantially reduced manufacturing cost.

Another advantageous aspect is that, considering that the heads always return to the jig after each measurement, we can say that the system is self-calibrating, eliminating the periodic calibrations performed by a specialist technician.

Another advantage of the set is that, from a users' point of view, the system does not require significant changes in use compared to traditional systems, meaning those who already use traditional systems will not need to learn new things to use the new system. product, and the heads are smaller and lighter than traditional systems, and therefore less susceptible to fall damage and more comfortable to handle.

It will be understood that certain characteristics and combinations of the calibration base (1), computer (2) and measuring heads (3) may vary considerably while maintaining the same functional concept for the assembly, therefore, it is noted that the construction now described in detail by way of example is clearly subject to constructive variations, but always within the scope of the inventive concept of using gyros or combining gyros

accelerometers and compass (mechanical, electronic or optical) for measuring vehicle suspension angles (buses, cars, motorcycles, airplanes, etc.). Can use the principle in measuring only one or all angles to be measured. Thus, and as many modifications may be made to the detailed configuration herein in accordance with the descriptive requirements of the law, it is understood that the present details should be construed as illustrative and not limiting.

Claims (7)

1.) Improvement of apparatus for measuring the geometrical elements of a vehicle suspension, characterized in that it comprises mechanical and electronic means so that a set preferably of 3 electronic gyros (11), one for the X axis (12a), one for the axis Y (12b) and the other for the Z axis (12c) which may or may not be combined with accelerometers and / or electronic compass, may be used to measure the different angles found in the geometry of a vehicle suspension, where the mechanical means, In addition to shipping the electronic parts, they are initially defined by a calibration base (1) which, on the one hand, is electronically interconnected with a standard computer (2) and, on the other hand, includes means for coupling / uncoupling and interconnection. electronics with four measuring heads (3), one left front head (a), one right front head (b), one left rear head (c) and one right rear head (d); each calibration head (3) has its respective electronic circuit with its microcontroller (4) which, in addition to the corresponding power supply (5), also has interconnections (6) and (7 or -8), the first with the computer (2), while the other two are for communication with the heads (3abcd), which may optionally be wired or wireless; said calibration base also includes head coupling sensors (9) (Iabcd) and head charging circuit (10); each measuring head (1) has the corresponding microcontroller (13), with which a set of 3 electronic gyros are interconnected, one for the X axis (12a), one for the Y axis (12b) and the other for the axis. Z (12c), arranged on printed circuit boards, the front of which also includes inclinometer (14), optional three-axis accelerometer (15), optional electronic compass (15a) position sensor (16), battery (17), a display (18), keys (19) for user interface, on this board will be the microcontroller (13) and the connections for wired or wireless communication (7-8), while the other two cards for the other axes will be mounted on a relief built to ensure orthogonality. 2. Apparatus improvement for measuring the geometrical elements of a vehicle suspension according to Claim 1, characterized in that each head (3) has all its electronics mounted in an airtight housing (20) with a clamping handle. (21), guide hole (22) in alignment with base (1), but also includes a rear bearing-type bearing fitting for engagement with base (1) and the usual clamping jaw (23) of the corresponding head at the wheel of the vehicle; said handle (21) with clamping means to prevent the head from turning once fixed. 3.) APPARATUS IMPROVEMENT FOR MEASURING GEOMETRY ELEMENTS OF A VEHICLE SUSPENSION according to claim 1, characterized in that it includes fittings and sensors in the base and the claw, all for automatic recognition if the head is in the calibration base (1). ), in the measuring jaw (23) or in transport. 4.) APPARATUS IMPROVEMENT FOR MEASURING THE GEOMETRY ELEMENTS OF A VEHICLE SUSPENSION according to claim 1, characterized in that the calibration base (1) is a zero template, preferably made in the form of an amount of tubes. and plates, with means for fixing to the floor and with precision plumb leveling, having holes in their upper part for fixing the measuring heads via the rear axle; said holes are accurate at the 3 coordinates, because this condition will be the heads zero reference (3). 5.) APPARATUS IMPROVEMENT FOR MEASURING THE GEOMETRY ELEMENTS OF A VEHICLE SUSPENSION according to claim 1, characterized in that it comprises a set of 4 usual clamps (23) for fixing the measuring heads (3) on the vehicle wheels and another electronic device or interface between the heads (3) and the computer (2). 6.) APPARATUS TO IMPROVE THE GEOMETRY ELEMENTS OF A VEHICLE SUSPENSION according to claim 1, characterized in that the communication between the calibration base (1) and the measuring heads (3) is wired from the serial type RS232, USB, RS485, CAN or other system compatible. 7.) APPARATUS TO IMPROVE THE GEOMETRY ELEMENTS OF A VEHICLE SUSPENSION according to claim 1, characterized in that the communication between the calibration base (1) and the measuring heads (3) is bluetooth wireless , zigbee, miwi, wifi, or other system compatible.