Dynamic axle alignment system onboard a vehicle

Abstract

The present invention relates to a dynamic axle alignment system onboard a vehicle for determining the perpendicular position of axle (58), as compared to vehicle centerline (70), which may be measurably monitored by establishing a first point (38) located onboard the vehicle's body or frame (62) and a second point (58a) located on or in proximity to axle (58). These two points serve as control points. A quantitative measurable relationship exists between the control points when compared with axle (58) alignment to the vehicle's centerline (70). In other words, the measurable relationship of the control points is quantitatively altered when axle (58) changes position as compared to the vehicle's centerline (70). Thus the present invention is utilized for monitoring the alignment of axle (58) as compared to the vehicle's centerline (70) by monitoring the measurable relationship of point (38) and point (58a).

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to vehicle axle alignment and, more particularly, to a dynamic axle alignment system onboard a vehicle for determining one or more axle alignment conditions, determining one or more axle alignment instructions, and/or controlling one or more axle alignment actuator devices, while the vehicle is either stationary or in motion. Proper axle alignment depends on the axle being perpendicular to a vehicle's centerline, which positions the wheels and tires parallel to the centerline with respect to a vehicle's direction of travel. The relationship between the axle and the vehicle's centerline is extremely critical for reducing driver fatigue, tire wear, tire temperature, tire failure, rolling resistance, component vibration and wear, operating cost, and for improving highway safety, fuel economy, and related vehicle efficiency and performance.

2. Description of Prior Art

Currently, the only provisions disclosed in prior art for onboard monitoring of a vehicle's axle alignment with respect to a vehicle's centerline is described in my U.S. Pat. No. 7,415,771, filed Nov. 16, 2005, entitled Apparatus Onboard a Vehicle for Instructing Axle Alignment. Currently, the only provisions disclosed in prior art for onboard monitoring and adjusting of an axle's alignment with respect to a geometric centerline is described in my U.S. patent application Ser. No. 11/809,529, filed Jun. 2, 2007, entitled Apparatus for Tractor Trailer Onboard Dynamic Alignment which is now approved.

In reference to my previous patents, improvements to my onboard axle alignment system have been made. These improvements include, but not limited to, using GPS for determining an axle's alignment condition, providing an actuator device attached relative to a telescoping trailing arm, and determining a vehicle's weight load and center of gravity.

OBJECTIVES OF THE INVENTION

An objective of the present invention is to provide means for determining a measurable relationship between two or more control points or benchmarks located onboard a vehicle while the vehicle is either stationary or in motion. The measurable relationship between the two control points may be used for testing dynamics of axle and suspension related designs, determining axle alignment conditions, instructing axle alignment or realignment, and/or controlling one or more axle alignment actuator devices mounted on or in proximity to one or more of the vehicle's axles. The term “onboard the vehicle” is defined as being on or in proximity to a vehicle's upper body, under body, outer body, inner body, frame, frame member, suspension member, or axle.

Another objective of the present invention is to establish a first control point on or in proximity to a vehicle's suspended member such as the vehicle's body or frame and a second control point established on or in proximity to the vehicle's non-suspended member such as an axle.

Yet another objective of the present invention is to establish a first control point on a vehicle's non-suspended member such as the vehicle's axle and a second control point on a second non-suspended member such as a second axle.

Yet another objective of the present invention is to provide means to quantitatively measure a relationship between a first control point and a second control point located onboard a vehicle.

Yet another objective of the present invention is to provide means to determine a distance between a first control point and a second control point located onboard a vehicle.

Yet another objective of the present invention is to provide means to determine a vector angle relative to two points located onboard a vehicle.

Yet another objective of the present invention is to provide means to quantitatively measure a relationship between multiple control points located onboard a vehicle.

Yet another objective of the present invention is to provide means to quantitatively compare a relationship between two control points to an axle being perpendicular to a travel, vehicle's body or frame centerline, vehicle's geometric centerline, or a vehicle's direction of travel.

Yet another objective of the present invention is to provide means to collect, store, print, display, compare, or transmit data that relates to a measurable relationship between two or more control points located onboard a vehicle.

Yet another objective of the present invention is to provide means to collect, store, print, display, compare, or transmit data that relates to a perpendicular position of an axle compared to a vehicle's body or frame centerline, vehicle's geometric centerline, or vehicle's direction of travel.

Yet another objective of the present invention is to provide means to collect, store, print, display, compare, or transmit data that relates to an alignment or misalignment of an axle as compared to a vehicle's body or frame centerline, vehicle's geometric centerline, or vehicle's direction of travel.

Yet another objective of the present invention is to provide an algorithm for determining a vehicle's axle alignment condition, instruction for axle alignment or realignment, an instruction for controlling one or more axle alignment actuators, an instruction for controlling air supply to one or more airbags of a vehicle's suspension, instruction for controlling air supply to one or more of the vehicle's tires.

Yet another object of the present invention is to utilize an air supply unit onboard a vehicle for supplying air to one or more airbags or tires by using a computer and algorithm for controlling the air supply which inflates and/or deflates the airbags or tire with respect to an axle's alignment condition.

Yet another objective of the present invention is to provide means to collect, store, print, display, compare, or transmit data that relates to an alignment or misalignment of an axle as compared to a vehicle's body or frame centerline, vehicle's geometric centerline, or vehicle's direction of travel, while the vehicle is either stationary or in motion.

Yet another objective of the present invention is to provide means to identify a misaligned axle.

Yet another objective of the present invention is to provide means to identify a misaligned axle and to provide means to detect the direction of misalignment.

Yet another objective of the present invention is to provide means to identify a misaligned axle and to provide means to quantitatively measure the misalignment.

Yet another objective of the present invention is to provide means to instruct the alignment of an axle.

Yet another objective of the present invention is to provide means to instruct the realignment of a misaligned axle.

Yet another objective of the present invention is to provide means to identify a particular vehicle, a particular axle, a particular side of the axle, a particular direction in which to align the axle, and to determine when the axle's alignment is correct.

Yet another objective of the present invention is to provide means to identify a misaligned axle and to provide means to reposition the axle perpendicular to the vehicle's body or frame centerline, vehicle's geometric centerline, or vehicle's direction of travel, while the vehicle is stationary or in motion.

Yet another objective of the present invention is to provide means to identify an axle's path of motion while the vehicle is being driven or in motion.

Yet another objective of the present invention is to provide means to identify an axle's path of motion while the vehicle is being driven or in motion and to collect, store, print, display, compare, or transmit data that relates to the axle's path of motion.

Yet another objective of the present invention is to provide means to identify and/or determine a weight load of a vehicle.

Yet another objective of the present invention is to provide means for sensing the vehicle's empty weight, distribution of loaded weight, load shift, and/or center of gravity (CG) with respect to an axle's alignment.

Yet another objective of the present invention is to provide a display for displaying load information to dock loaders and/or the vehicle driver.

BRIEF SUMMARY OF THE INVENTION

The present invention relates to a dynamic axle alignment system onboard a vehicle for monitoring and/or adjusting an axle's alignment while the vehicle is either stationary or in motion. Every vehicle has two centerlines, either of which may be selected as a reference for axle alignment. The first centerline is a body centerline, defined as a longitudinal axis along the center plane of the vehicle's frame. The second centerline is a geometric centerline, defined as a longitudinal axis through the midpoint of the rear axle and intersecting the midpoint of the front axle. Ideally, both centerlines should coincide; however, one must be selected as a reference for axle alignment. The choice of centerline is determined when the axle is first properly aligned. Proper alignment of an axle exist when the axle is perpendicular to the reference centerline, wheels and tires are parallel to the centerline, and the axle's thrust or drag line vector coincide with the centerline. The present invention will monitor the axle with respect to the selected centerline reference when it is installed onboard the vehicle relative to a selected axle.

The perpendicular position of the axle, as compared to the vehicle's centerline, may be measurably monitored by selectively establishing a first point located onboard the vehicle, which may be considered a fixed master control point and selectively establishing a second point located on or in proximity to the vehicle's axle. These two points serve as control points or benchmarks. A quantitative measurable relationship exists between the control points when compared to the axle's alignment to the vehicle's centerline reference with respect to the vehicle's direction of travel. In other words, the measurable relationship of the control points is quantitatively altered when the axle changes position as compared to the vehicle's centerline or direction of vehicle travel. Thus the present invention is utilized for monitoring the alignment of an axle as compared to the vehicle's centerline or direction of travel by monitoring the measurable relationship of the two control points. The measurable relationship of the two control points may include additional points or lines which may help define the way the two control points interact with each other. A change in the measured relationship between the two control points may be translated into a meaningful, quantitative determination of one or more axle alignment or misalignment conditions, one or more axle alignment or realignment instructions, data for controlling one or more axle alignment actuators, data for controlling an air supply to one or more of the vehicle's tires or suspension airbags with respect to axle misalignment caused by an unleveled vehicle.

Axle alignment conditions determined by the present invention may include, but not limited to, proper axle alignment, axle misalignment, axle's drag angle, drag line vector, axle's thrust angle, thrust line vector, tandem scrub angle, axle motion, axle alignment with respect to spring wrap condition, axle alignment with respect to a weight load, axle alignment with respect to a leaning vehicle cause by an uneven weight load, axle alignment with respect to a leaning vehicle due to low pressure of an airbag suspension, axle alignment with respect to a leaning vehicle caused by low tire pressure. Furthermore, digital values may be determined which represent dynamic or static axle conditions, and/or distinguishing between an axle alignment condition and a wheel alignment condition.

Axle alignment conditions which place the axle's thrust or drag angle to the left of the vehicle's centerline is referred to as negative and to the right as positive. These conditions define various relationships between the axle's alignment and the vehicle's centerline with respect to the vehicle's direction of travel.

Axle alignment instructions, notices, or alerts given by the present invention may include but not limited to a particular vehicle, a particular axle to align, a particular side of the axle to align, a particular direction to align the axle, when to stop alignment of the axle, an indication that the axle is properly aligned, irregular axle motion, a particular side of an axle causing irregular axle motion, threshold value exceeded, inspection due, low air pressure relative to a particular tire, low air pressure relative to a particular airbag suspension, etc.

Axle alignment actuators, which may be controlled by the present invention, may include but not limited to rotary, linear, or oscillatory actuators such as linear actuators, hydraulic cylinders, pneumatic actuators, and electric motors. All of which may be mounted on or in proximity to the vehicle's frame, axle, or suspension member. In addition to the actuator, a safety means such as a lever, locking pin, gear, and/or sensors may be included for preventing unwanted movement of the actuator, axle, or suspension member. The axle alignment actuators may be mounted onboard the vehicle relative to at least one selected from the group of an axle, trailing arm, telescoping trailing arm, control arm, spring, frame or frame member, knuckle or spindle. In some applications actuators may possibly operate under continuous variable rates and require a cooling means such as air, liquid, or gases.

Axles monitored and/or adjusted by the present invention may include, but not limited to, steerable or non-steerable axles such as live, straight, dead or lazy, lift, drag, tag, pusher, split, tandem, drive, trailer, or portal axles.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 a shows one example of the present invention in one embodiment such as a GPS receiver and one or more GPS antennas mounted onboard the vehicle and in communication with a Global Positioning System (GPS) or satellite network for monitoring a vehicle's axle alignment;

FIG. 1 b shows a computer receiving axle alignment and related data sent from the present invention;

FIG. 1 c is an example of a distance determined between the two points seen in FIG. 1a;

FIG. 2 a shows a plan view of GPS satellites in communication with GPS antennas located at two points onboard the vehicle;

FIG. 2 b is an example of a distance determined between the two points seen in FIG. 2a;

FIG. 3 shows utilizing GPS in conjunction with an axle alignment actuator attached to the vehicle's suspension member such as a trailing arm;

FIG. 4 a shows a plan view of various configurations of positioning the present invention onboard of a vehicle;

FIG. 4 b is an example of a distance determined between two points selected from one of the configurations shown in FIG. 4a;

FIG. 5 a is a side elevation view of a vehicle's suspension showing one embodiment of the present invention utilizing a baseline device in communication with sensors, an onboard computer, and an axle alignment actuator mounted inside a telescoping trailing arm;

FIG. 5 b shows a handheld receiver in communication with the present invention shown in FIG. 5a;

FIG. 6 a shows an elevation view of a vehicle suspension positioned at a normal ride height and a distance shown between the trailing arm pivot connection and the axle;

FIG. 6 b shows an elevation view of a vehicle suspension being compressed by a weight load and an altered distance shown between the trailing arm pivot connection and the axle;

FIG. 7 a shows how sensors may be arranged for determining a measurable relationship between a first point located onboard the vehicle and a second point located relative to the axle with respect to a properly aligned axle;

FIG. 7 b shows a close up view of the sensor seen in FIG. 7a and the arrangement of the sensors for determining an axle's alignment condition;

FIG. 7 c shows an example of a flowchart representation of a solution algorithm using structured type programming for determining axle alignment conditions;

FIG. 8 a shows how an arrangement of sensors may be utilized for determining a misaligned axle and how an axle alignment instruction may be generated;

FIG. 8 b shows a close up view of the sensor seen in FIG. 8a and the arrangement of the sensors for determining axle alignment instruction and controlling an axle alignment actuator;

FIG. 8 c shows an example of a flowchart representation of a solution algorithm using structured type programming for determining axle alignment instruction and for controlling an axle alignment actuator;

FIG. 9 a shows the present invention determining a misaligned axle due to a leaning vehicle caused by an uneven load distribution;

FIG. 9 b shows a close up view of the sensor seen in FIG. 9a and the arrangement of the sensors for determining axle misalignment and controlling air inflation to a vehicle's suspension airbag;

FIG. 9 c shows an example of a flowchart representation of a solution algorithm using structured type programming for supplying air to a vehicle's suspension airbag when axle misalignment is detected due to a leaning vehicle;

FIG. 10 shows a plan view of one embodiment of the present invention including a directional sensor for detecting lateral displacement of the axle as compared to the vehicle centerline and an actuator for aligning the axle if displacement is detected;

FIG. 11 a is a side elevation view of a vehicle's suspension and the present invention utilizing electromagnetic wave or sonar wave devices for determining a distance between two fixed points on the vehicle;

FIG. 11 b shows a side view of a telescoping trailing arm housing an actuator;

FIG. 12 is a side elevation view of a vehicle's suspension illustrating one embodiment of the present invention utilizing a laser and directional sensors in communication with an axle alignment actuator mounted relative to the vehicle's trailing arm and frame;

FIG. 13 is a side elevation view of a vehicle's suspension illustrating one embodiment of the present invention utilizing a wave emitting source, computer, and an axle alignment actuator mounted relative to the trailing arm and frame;

FIG. 14 is a side elevation view of a vehicle's suspension illustrating one embodiment of the present invention utilizing a camera, target, computer, and an axle alignment actuator mounted relative to the trailing arm and frame;

FIG. 15 shows a perspective view of a vehicle's axle, trailing arm, and frame, that illustrates one embodiment of the present invention utilizing an encoded or potentiometer coupled with mechanical linkage;

FIG. 16 shows an exploded view of my prior art axle monitoring apparatus which includes an axle, a rod extending from the axle to directional sensors or a sensing plane, and a housing for enclosing the sensor and rod;

FIG. 17 shows a perspective view of my prior art axle alignment apparatus assembled and mounted relative to a vehicle's axle and frame with a linear actuator for rotating the axle's adjustment mechanism;

FIG. 18 is a flowchart that shows an example of method steps for setup of the present invention;

FIG. 19 shows a level sensor which may be used in conjunction with the present invention for distinguishing between axle misalignment due to a low tire or an uneven weight load.

DRAWING

Reference Numerals

• 20—Mounting plate;
• 20 a—Mounting base for a baseline establishing device such as a rod or mechanical linkage;
• 22—Plate cover;
• 24—Opening;
• 26—U type bolts;
• 28—Baseline: a line or line segment such as a time of flight light wave from a camera or laser, ultrasonic wave, electromagnetic wave such as radio, or a measuring rod;
• 28 a—Laser having measuring properties;
• 28 b—Camera having measuring properties;
• 28 c—Target or detector for a laser or camera;
• 28 d—Wave emitting source such as a light wave, electromagnetic wave, or ultrasonic wave, etc, which may alternatively include a built-in detector;
• 30—Baseline producing device such as a time of flight sensor of a camera or laser, sonar, radio, electromagnetic radiation emitter, or measuring rod;
• 30 a—A mechanical arm, rod, or linkage;
• 32—Hinge;
• 34—Position sensor;
• 36—Sensor support bracket;
• 38—First control point or benchmark located onboard the vehicle;
• 40—Sensors, segmented sensing plane, or directional sensors;
• 40 a—Electrical measuring device such as an encoder or potentiometer;
• 42—Wiring connection;
• 44—Reset switch;
• 46—Indicator guide;
• 48—Guide slot;
• 50—Longitudinal groove for mechanical link;
• 52—Sensor cover;
• 54—Flex boot;
• 56—Housing tube;
• 58—Axle;
• 58 a—Control point or benchmark located on or in proximity to an axle or suspension member;
• 60—Axle deviation;
• 60 a-Angle of deviation;
• 62—Frame rail;
• 64—Sensor central axis or centerline;
• 66—Electromagnetic wave emitter and antenna;
• 66 a-Electromagnetic wave receiver and antenna;
• 68—Handheld receiver;
• 68 a—GPS receiver onboard the vehicle;
• 70—Vehicle's centerline;
• 72—Direction of travel;
• 74—Alignment threshold;
• 76—Axle motion values;
• 78—GPS antenna;
• 80—Frame member or extension;
• 82—Computer or logic;
• 82 a—Onboard display;
• 84—Actuator;
• 84 a—Mounting bracket;
• 86—Bolt or other fastening means;
• 88—Rotary axle adjustment mechanism;
• 88 a—Oscillatory or rocker arm axle adjustment mechanism;
• 88 b—Manual axle adjustment mechanism;
• 90—Linear slotted hole;
• 92—Dowel pin, bolt, or other suitable securing means;
• 94—Trailing arm;
• 94 a-Telescoping arm;
• 98—Remote computer;
• 140-148—Method steps for setup of the present invention;
• 160—Air supply unit placed onboard the vehicle;
• 162—Airbag suspension;
• 164—Level sensor;
• 166—tire;
• CG—Center of gravity.

FLOWCHART

Reference Numerals

• 100—Start;
• 102—Read OP: Read Operations for front and rear axle position sensor's left and right sides;
• 104—Loop connector;
• 106—OP=0?: Are Operations equal to zero?;
• 108—Axle alignment correct;
• 108 a—Axle misalignment;
• 110—Left side drive axle LSDA>0: position sensor 40 lower left quadrant is greater than zero;
• 110 a—Alignment condition: negative thrust angle caused by the left side of rear drive axle being rearward;
• 112—Left side drive axle LSDA<0: position sensor 40 upper right quadrant is less than zero;
• 112 a—Alignment condition: positive thrust angle caused by the left side of rear drive axle being forward;
• 114—Right side drive axle RSDA>0: position sensor 40 lower right quadrant is greater than zero;
• 114 a—Alignment condition: positive thrust angle caused by the right side of rear drive axle being rearward;
• 116—Right side drive axle RSDA<0: position sensor 40 upper left quadrant is less than zero;
• 116 a—Alignment condition: negative thrust angle caused by the right side of rear drive axle being forward;
• 118—Left side rear tandem LSRT>0: position sensor 40 lower left quadrant is greater than zero;
• 118 a—Alignment instruction: adjust left side of the rear tandem axle forward;
• 120—Left side rear tandem LSRT<0: position sensor 40 upper right quadrant is less than zero;
• 120 a—Alignment instruction: adjust left side of the rear tandem axle rearward;
• 122—Right side rear tandem RSRT>0: position sensor 40 lower right quadrant is greater than zero;
• 122 a—Alignment instruction: adjust right side of the rear tandem axle forward;
• 124—Right side rear tandem RSRT<0: position sensor 40 upper left quadrant is less than zero;
• 124 a—Alignment instruction: adjust right side of the rear tandem axle rearward;
• 126—Left side of rear tandem axle LSRT>0: position sensor 40 lower left quadrant is greater than zero;
• 126 a—Airbag inflation instruction: supply air to the right side airbag suspension;
• 128—Left side of rear tandem axle LSRT<0: position sensor 40 upper right quadrant is less than zero;
• 128 a—Airbag inflation instruction: supply air to the left side airbag suspension;
• 130—Right side of rear tandem axle RSRT>0: position sensor 40 lower right quadrant is greater than zero;
• 130 a—Airbag inflation instruction: supply air to the left side airbag suspension;
• 132—Right side of rear tandem axle RSRT<0: position sensor 40 upper left quadrant is less than zero;
• 132 a—Airbag inflation instruction: supply air to the right side airbag suspension;
• 134—Connector for results;
• 136—Receive results;
• 138—Stop.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The present invention includes various configurations for mounting various devices for determining a measurable relationship relative to one or more points located onboard a vehicle. The spatial relationship or relative positioning of the points may be utilized as representation of a relationship between an axle and the vehicle's centerline. The measurable relationship may be translated into data for determining one or more axle alignment conditions, one or more axle alignment instructions, one or more instructions for controlling one or more axle alignment actuators, and/or instructions for controlling air supply to a tire or airbag of a vehicle's suspension.

FIGS. 1 a, 1b, and 1c show an example of the present invention in one embodiment utilizing a satellite or Global Positioning System (GPS) for monitoring a vehicle's axle alignment. This may be accomplished by following: 1) mounting a first GPS satellite receiver's antenna 78 at a first fixed control point 38 (see FIG. 18 box 140) selectively established onboard the vehicle, for example on the vehicle's roof; 2) mounting a second GPS satellite receiver's antenna 78 at a second fixed control point 58a (see FIG. 18 box 142) established relative to the vehicle's axle at the outer hub or wheel cap. Orbit position and other related data sent from the GPS satellites are received at each GPS antenna's electrical phase center, a point where the satellite signal is collected (not shown). Each GPS antenna 78 may be linked to a main GPS receiver 68a located onboard the vehicle, such as but not limited to the vehicle's interior compartment. Receiver 68a may be used for calculating a distance between the first GPS antenna's phase center and satellite, and the second GPS antenna's phase center and satellite. The receiver 68a or other suitable calculating means such as an onboard computer 82 may then combine these distances in a calculation for determining a distance (see FIG. 1c) between the first GPS antenna 78 at first point 38 and the second GPS antenna 78 at second point 58a (see FIG. 18 box 144). The measured relationship between the GPS antenna 78 at the first point 38 and the GPS antenna 78 at the second point 58a may be transmitted to a data processing means such as computer 82 for qualitative comparison of measured values to a predetermined reference frame or one or more predetermined values. This data may be used for gathering information relative to axle and suspension dynamics which may be beneficial to research and development of axle and suspension design. The predetermined values may further be used to determine one or more axle alignment conditions (see FIG. 7c and FIG. 18 box 146), one or more axle alignment instructions (see FIG. 8c and FIG. 18 box 148), and/or control the engagement and disengagement of one or more axle alignment actuators (see FIG. 8c and FIG. 18 box 148), which may be mounted relative to one or more of the vehicle's axles or suspension members. The alignment conditions and related data may be displayed in view of a driver by onboard display 82a or sent to a remote site or computer 98 (see FIG. 1b). Each GPS receiver antenna 78 must be utilized onboard the particular vehicle being monitored.

FIG. 2 a shows a plan view of another example of using GPS for monitoring a vehicle's axle alignment. The first GPS receiver's antenna 78 is shown at first fixed control point 38 (see FIG. 18 box 140) selectively established onboard the vehicle. A second GPS receiver's antenna 78 is shown at a second fixed control point 58a (see FIG. 18 box 142) established relative to the axle's outer hub or wheel cap. Axle 58 is perpendicular to the vehicle's centerline 70, and vehicle centerline 70 is relative to the vehicle's direction of travel 72. Any change in the spatial relationship or relative position of axle 58 and centerline 70 quantitatively alters the measurable relationship between the first GPS receiver's antenna 78 at the first point 38 and the second GPS receiver's antenna 78 at the second point 58a. Therefore, the present invention may utilize GPS receiver 68a for calculating a distance between the first GPS antenna 78 and satellite, and the second GPS antenna 78 and satellite. Receiver 68a or other suitable calculating means such as an onboard computer 82 may combine these distances in a calculation for determining a distance (see FIG. 2b) between the first GPS antenna 78 at first point 38 and the second GPS antenna 78 at second point 58a (see FIG. 18 box 144). The measured relationship between the GPS antenna 78 at the first point 38 and the GPS antenna 78 at the second point 58a may be transmitted to a data processing means such as computer 82 for qualitative comparison of measured values to a predetermined reference frame or one or more predetermined values. This data may be used for gathering information relative to axle and suspension dynamics which may be beneficial to vehicle axle and suspension design. The predetermined values may further be used to determine one or more axle alignment conditions (see FIG. 7c and FIG. 18 box 146), one or more axle alignment instructions (see FIG. 8c), and/or control the engagement and disengagement of one or more axle alignment actuators (see FIG. 8c and FIG. 18 box 148), which may be mounted relative to one or more of the vehicle's axles or suspension members. The alignment conditions and related data may be displayed in view of a driver by onboard display 82a or sent to a remote site or computer 98 (see FIG. 1b). Alternatively, the data may be used for controlling an air supply unit 160 (see FIG. 15), which may supply air to a low airbag 162 of the vehicle's suspension (see FIG. 15) or a low tire (see FIG. 19), if the low air pressure is determined to have an affect on the alignment of axle 58.

FIG. 3 shows a semi trailer vehicle having a GPS receiver's antenna 78 mounted at a first fixed control point 38 located on the vehicle's roof. A second GPS receiver's antenna 78 mounted at a second fixed control point 58a located relative to the vehicle's axle 58. GPS satellites are shown in communication with each GPS antenna 78. GPS receiver 68a may be used for calculating a distance measurement between satellites and each GPS receiver's antenna. The distance or measurement is trigonometrically calculated for determining a distance between first point 38 and second point 58a. This data may be sent to computer 82 for processing and comparing the measurement to a predetermined reference frame or value such as seen in FIG. 7c, 8c, or 9c. The data may further be sent to an onboard display 82a. Display 82a may be located at the rear of the trailer in view of a person (dock loader) who loads the vehicle. Display 82a may display weight of the load, distribution of the load, and/or center of gravity CG of the loaded trailer vehicle. The data may further be sent to an axle alignment actuator 84 mounted relative to trailing arm 94 for adjustment of axle 58, if axle 58 is determined to be misaligned according to the measurement between first point 38 and second point 58a. Alternatively, related data may be sent to a remote computer or receiver.

FIG. 4 a shows a plan view of a tractor trailer vehicle having multiple axles and various configurations of location points for establishing control points onboard the vehicle. The points shown may include embodiments shown in FIGS. 5a, 10, 11, and 12-16.

Listed below are configurations A-G as shown in FIG. 4a.

Example (A) is an arrangement of the invention consisting of a single axle 58 having two control points 58a located on axle 58. Control points 58a communicate with two control points 38 which are located on the trailer's frame or body 62.

Example (B) is an arrangement of the invention consisting of a single axle 58 having two control points 58a located on axle 58. Control points 58a communicate with a single control point 38 which is located on the trailer's frame or body 62.

Example (C) is an arrangement of the invention consisting of two axles 58 where each axle 58 has two control points 58a located on the axle. Control points 58a communicate with a single control point 38 which is located on the trailer's frame or body 62.

Example (D) is an arrangement of the invention consisting of two axles 58 where each axle 58 has a single control point 58a located on the axle. Control points 58a communicate with each other.

Example (E) is an arrangement of the invention consisting of a single axle 58 where axle 58 has two control points 58a located on axle 58. Control points 58a communicate with two control points 38, wherein the first control point 38 is located on the trailer's frame or body 62 aft of axle 58 and the second control point 38 is located on the trailer's frame or body 62 fore of axle 58.

Example (F) is an arrangement of the invention consisting of two axles 58 where each axle 58 has a single control point 58a located on axle 58. Control points 58a communicate with a single control point 38 which is located between the axles on the tractor vehicle's frame or body 62.

Example (G) is an arrangement of the invention consisting of a single axle 58 having a single control point 58a located on axle 58. Control point 58a communicates with a single control point 38 which is located on the vehicle's frame or body 62.

In regard to the various arrangements, a distance measured between control points located along the vehicle may be utilized for determining the vehicle's center of gravity CG. An example of center of gravity CG is shown in FIG. 4a located between examples (C) and (D).

FIG. 4 b is an example of a distance determined between two points selected from one of the configurations shown in FIG. 4a;

FIG. 5 a shows an example of one embodiment of the present invention mounted relative to a vehicle's body or frame 62, frame member 80, and axle 58. The embodiment utilizes a directional sensor 40 mounted at a first fixed control point 38 (see FIG. 18 box 140) on or in proximity to the vehicle's body or frame 62 and a second fixed control point 58a (see FIG. 18 box 142) on or in proximity to axle 58. A baseline device 30 is used for establishing baseline 28 that originates at second fixed control point 58a and ends on directional sensor 40. When the axle 58 dynamically moves relative to frame 62 axle alignment data is generated based on the relative position of baseline 28 and sensor 40. Axle alignment data may be sent to an onboard computer 82, onboard display 82a, remote computer 98 (seen in FIG. 1b) and/or to an axle alignment actuator 84. Computer 82 may store axle alignment data while the vehicle is in motion or stationary (see FIG. 18 box 144) and then use it to determine one or more axle alignment conditions (see FIG. 7c and FIG. 18 box 146), one or more axle alignment instructions (see FIG. 8c), and/or instructions to control one or more axle alignment actuators 84 (see FIG. 8c and FIG. 18 box 148) mounted relative to the vehicle's axle or suspension member, such as trailing arm 94. Axle alignment actuator 84 is attached to arm 94 and telescoping arm 94a. The data generated in the process of comparison of a relative position of baseline 28 and sensor 40 may be utilized for controlling an engagement and disengagement of actuator 84 (see FIG. 8c). Actuator 84 alters the length of trailing arm 94 and slides member 94a to adjust a positioning of axle 58.

Alternatively, the data may be used for controlling an air supply unit 160 (see FIG. 15), which may supply air to a low airbag 15 (see FIG. 15) of the vehicle's suspension or a low tire (see FIG. 19), if the low air pressure is determined to have an affect on the alignment of axle 58. Furthermore, baseline device 30 and directional sensor 40 may be arranged in a vice versa manner, where baseline device 30 is mounted relative to the vehicle's body or frame 62 and directional sensor 40 is mounted relative to axle 58.

FIG. 5 b shows one example of a wireless remote receiver 68 which may be used with the present invention. Receiver 68 may receive axle alignment data from computer 82 or sensor 40 located onboard the vehicle. Receiver 68 may display axle alignment data utilizing a LCD monitor or other suitable means such as lights or text shown on receiver 68.

FIG. 6 a shows a side elevation view of a vehicle's suspension at a normal static ride height with a normal distance between a pivotal connection (or axis) at bolt 92 of trailing arm 94 and the center of axle 58. This distance is determined along a horizontal datum plane.

FIG. 6 b illustrates an example of a weight load on a vehicle which may alter the positioning of axle 58. For example, when the vehicle is loaded the vehicle's springs or airbags are compressed from the weight load and the ride height is altered. Trailing arm 94 will follow an arch of its axis located at bolt 92 and may alter the distance between bolt 92 and axle 58 (along the horizontal datum plane). If the weight is distributed evenly from side to side the distance between bolt 92 and axle 58 change at an equal rate on both sides of axle 58. This change, being equal doesn't affect the axle's alignment. However, it is possible for the distance between bolt 92 and axle 58 to become unequal from side to side (along the horizontal datum plane). This may be experienced when only one side of axle 58 is raised or lowered opposed to the other side. This would cause axle 58 to slightly deviate 60 momentarily from its original alignment relative to the opposing side. This momentary effect is not noticed by the driver; however, if a weight load on the vehicle is distributed unevenly, the vehicle may lean to one side. A leaning vehicle may have the same affect on the alignment of axle 58 as if only one side of the axle is raised, except the deviation will become constant until the load is redistributed or removed. Such misalignment may cause the vehicle to slightly skew from its normal direction of travel. The driver would then input a constant counter steer in order to keep the vehicle moving in a straight path.

Furthermore, a weight load may be determined using the present invention by measuring a substantially horizontal distance between first point 38 and second point 58a when the vehicle is empty and measuring the distance as weight is applied. By knowing the empty weight and distance between the control points it is possible to determine a vehicle's weight load as the distance changes with respect to the axle's state of adjustment.

FIGS. 7 a-9c shows examples of how the present invention may be used with a computer. In FIGS. 7c, 8c, and 9c show an example of flowcharts of solution algorithms for basic structured programming when using a computer with the present invention. The program may be used for determining an axle's alignment condition, instructing axle alignment or realignment procedure to a technician or machine, engaging or disengaging an actuator for aligning an axle, supplying air to a tire or airbag of the vehicle's suspension, or notifying an operator about axle alignment conditions.

The complexity of the program will depend on how many axle adjustments mechanisms are present on the vehicle. For example, the program will have fewer steps if the vehicle has only one axle adjustment mechanism on only one side of the axle and more steps if the vehicle has adjustment mechanism on both sides of the axle. The program will include even more steps if the vehicle has a third adjustment for adjusting the axle transversely as it will require steps for determining the transverse adjustment.

FIG. 7 a shows one example of how the present invention may be arranged for determining a measurable relationship between a first fixed control point 38 (see FIG. 18 box 140) at sensor 40 and a second fixed control point 58a (see FIG. 18 box 142) at baseline device 30. Sensor 40 is shown located on or in proximity to the vehicle's body or frame 62 adjacent to axle 58. Baseline device 30 is shown located relative to axle 58. These two points are shown with respect to a properly aligned axle 58.

During setup of the present invention, baseline device 30 may be used for establishing a line perpendicular to axle 58 (illustrated through baseline 28) which may be aligned relative to a point along the central axis 64 of sensor 40. Baseline 28 has a first end starting at baseline device 30 and a second end ending at the sensor 40 and is parallel to vehicle's centerline 70. When aligned, the second end of baseline 28 at the sensor 40 establishes a zero point surrounded by a quadrant of sensors in order to quantitatively measure the relationship between the first and the second control point (see FIG. 18 box 144). As weight is applied to the vehicle, baseline 28 will move horizontally fore or aft relative to central axis 64 at sensor 40, depending upon the weight of the load. At this point a new zero point may be established. However, if the weight is distributed unevenly from side to side, baseline 28 will move from its zero point and away from central axis 64 and the sensors at sensor 40 would indicate data that may be used to determine that the vehicle has an uneven weight load. Measuring may be performed while the vehicle is stationary or in motion. The relationship between the first and second point may include using sensor 40 and baseline 28 for measuring a longitudinal, lateral, or angular displacement between the first and the second control point as compared to the points' original position. Any deviation about sensor 40 may be used for determining an alignment condition of axle 58 (see FIGS. 7c and 18 box 146), one or more axle alignment instructions (see FIG. 8c and FIG. 18 box 148) and/or signals for engaging and disengaging one or more axle alignment actuator devices (see FIG. 18 box 148).

The arrangement of devices seen in FIG. 7a may be positioned in a vice versa manner, where sensor 40 is mounted on the axle and baseline device 30 mounted adjacent to the axle. Alternatively, the baseline 28 is not required to be perpendicular to axle 58 as long as sensor 40 is arranged to recognize an angle of baseline 28.

In FIG. 7b, sensor 40 is shown divided into quadrants which are utilized for detecting and/or measuring a baseline such as a vector between baseline device 30 and sensor 40 or a vector angle (shown in FIG. 8b) between baseline 28 and the sensor 40. Sensor 40 may include any number of sensors, segments, or pattern grids. Furthermore, predetermined specific coding may be used to generate specific alignment data relative to a distance between baseline device 30 and sensor 40 and/or angle between baseline 28 and sensor 40. This signal or code may communicate an axle's alignment condition (see FIG. 7c) or axle motion values 76 (See FIGS. 7a and 7b).

As shown in FIG. 7a, baseline 28 intersects with a zero point located along central axis 64 of sensor 40 when the axle 58 is properly aligned. FIG. 7b shows specific coding arranged in quadrants surrounding the zero point. As axle 58 moves under dynamic conditions (see FIG. 6b), baseline 28 simultaneously moves relative to sensor 40. When an axle misalignment conditions occur baseline 28 exceeds the predetermined threshold value 74. The quadrants of sensor 40 may be used for detecting and determining the misalignment condition of axle 58. The condition may further be identified as a condition (known in the art) associated with a particular position of the axle as compared to the vehicle's centerline. The quadrants may determine the condition when baseline 28 moves longitudinally and to the left or right of the zero point or a change in distance may determine the condition when using a wave source such as light, electromagnetic, or ultrasonic.

For clarity, see FIG. 7b simultaneously with FIG. 7c for comparison of the quadrants of sensor 40 to the algorithm seen in FIG. 7c.

For example, Start 100 begins the sequence of steps for determining an axle alignment condition of a rear drive axle. Read OP 102 reads the operations. Then tests if the operations equal zero (OP=0?) 106 and is executed if the condition is “YES” Alignment Correct 108 is indicated. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

If (OP=0?) 106 condition is “NO” axle Misalignment 108a condition is determined and the testing begins by checking if the value is greater than zero (LSDA>0) 110 (meaning the left side of the drive axle moved rearward), an indication of a negative thrust angle 110a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

If the value is less than zero (LSDA<0) 112 (meaning the left side of the drive axle moved forward), an indication of a positive thrust angle 112a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138. After LSDA is checked the operation process continues to RSDA.

If the value of RSDA is greater than zero, (RSDA>0) 114 (meaning the right side of the drive axle moved rearward), a positive thrust angle 114a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

If the value is less than zero, (RSDA<0) 116 (meaning the right side of the drive axle moved forward), a negative thrust angle 116a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

After RSDA is checked, the process is repeated through Loop Connector 104, where (OP=0?) 106 is tested. The sequence will repeat the steps until the loop is closed by determining that the value of operations are equal to zero, (OP=0?) 106, Alignment Correct 108 is indicated. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

The above is an example and is not limited to only the conditions illustrated, but may include other axle alignment conditions such as, but not limited to the conditions described in this specification. The algorithm seen in FIG. 7c may also be used with GPS axle alignment monitoring described as one embodiment of the present invention.

FIG. 8 a shows an example of axle deviation and how deviation may be detected by the arrangement of sensors, segments, or pattern grids located at sensor 40. For example: sensor 40 is shown at a first control point 38 located adjacent to a second control point 58a located at axle 58. Baseline device 30 projects baseline 28 perpendicular to axle 58. If axle 58 deviates from its normal position, it causes baseline 28 to skew from a zero point at the sensor 40. One or more sensors, segments, or pattern grids at sensor 40 would detect a distance or degree of deviation 60a and generate a specific data relative to deviation of the axle 58. One or more signals may be generated by one or more sensors, segments, or pattern grids surrounding the zero point of sensor 40 that would identify specific deviation data (misalignment data) such as but not limited to the distance, direction of deviation or movement, deviation angle, angle of axle 58 relative to centerline 70, angle of deviation between the baseline 28 and the centerline 70, etc. Obtained data may be utilized to determine axle alignment threshold values 74, one or more axle alignment conditions (see FIG. 7c), one or more axle alignment instructions (see FIG. 8c), and/or to control one or more axle alignment actuator devices (see FIG. 8c).

FIG. 8 b shows one example of sensor 40 divided into quadrants utilizing specific coding for determining axle alignment instructions, which may be used for instructing manual axle alignment or controlling one or more axle alignment actuator.

For clarity, see FIG. 8b simultaneously with FIG. 8c for comparison of the quadrants of sensor 40 to the algorithm seen in FIG. 8c. For example, Start 100 begins the sequence of steps for determining an axle alignment instruction for a trailer vehicle's rear tandem axle. Read OP 102 reads the operations. Then tests if the operations equal zero (OP=0?) 106 and is executed if the condition is “YES” Alignment Correct 108 is indicated. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

If (OP=0?) 106 condition is “NO” axle Misalignment 108a condition is detected and the testing begins by checking if the value is greater than zero (LSRT>0) 118 (meaning the left side of the tandem axle moved rearward), an instruction to adjust the left side of the rear tandem axle forward 118a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

If the value is less than zero (LSRT<0) 120 (meaning the left side of the tandem axle moved forward), an instruction to adjust the left side of the rear tandem axle rearward 120a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138. After LSRT is checked the operation process continues to RSRT.

If the value of RSRT is greater than zero, (RSRT>0) 122 (meaning the right side of the tandem axle moved rearward), an instruction to adjust the right side of the rear tandem axle forward 122a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

If the value is less than zero, (RSRT<0) 124 (meaning the right side of the tandem axle moved forward), an instruction to adjust the right side of the rear tandem axle rearward 124a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

After RSRT is checked, the process is repeated through Loop Connector 104, where (OP=0?) 106 is tested. The sequence will repeat the steps until the loop is closed by determining that the value of operations are equal to zero, (OP=0?) 106, Alignment Correct 108 is indicated. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

The above is an example and is not limited to only the axle alignment instructions illustrated in FIG. 8c, but may include other instructions such as, but not limited to the alignment instructions described in this specification. The algorithm seen in FIG. 8c may also be used with GPS axle alignment monitoring described as one embodiment of the present invention.

FIG. 9 a shows how axle deviation may be detected due to an uneven weight load of a vehicle. For example, sensor 40 is positioned at a first point 38 locate adjacent to a second point at axle 58. A baseline device 30 establishes the second point 58a and projects a baseline 28 perpendicular to axle 58 and intersects a zero point at sensor 40. With a properly distributed weight load baseline 28 will be parallel to vehicle centerline 70. If during loading the weight load may compress the suspension (see FIG. 6b) and the zero point of sensor 40 may be changed of central axis 64 and a new zero point may be set (this may alternatively be done through a new distance determined between the first and second points). If the weight load is distributed unequally and creates a vehicle lean, baseline 28 will move from its zero point and away from central axis 64 and the sensors at sensor 40 would indicate data that may be used to determine axle deviation 60a, according to the uneven weight load of the vehicle. This data may be used for controlling an onboard air supply 160 (see FIG. 15) for inflation of at least one airbag 162 of the vehicle's suspension.

FIG. 9 b shows one example of sensor 40 divided into quadrants utilizing specific coding for controlling an onboard air supply to the vehicle's airbag suspension.

For clarity, see FIG. 9b simultaneously with FIG. 9c for comparison of the quadrants of sensor 40 to the algorithm seen in FIG. 9c. For example, Start 100 begins the sequence of steps for determining an instruction for supplying air to the airbag. Read OP 102 reads the operations. Then tests if the operations equal zero (OP=0?) 106 and is executed if the condition is “YES” Alignment correct before and after loading 108 is indicated. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

If (OP=0?) 106 condition is “NO” axle alignment incorrect after loading 108a condition is detected and the testing begins by checking if the value is greater than zero (LSRT>0) 126 (meaning the left side of the rear tandem axle moved rearward), an instruction to supply air to the right side airbag 126a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

If the value is less than zero (LSRT<0) 128 (meaning the left side of the rear tandem axle moved forward), an instruction to supply air to the left side airbag 128a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138. After LSRT is checked the operation process continues to RSRT.

If the value of RSRT is greater than zero, (RSRT>0) 130 (meaning the right side of the rear tandem axle moved rearward), an instruction to supply air to the left side airbag 130a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

If the value is less than zero, (RSRT<0) 132 (meaning the right side of the rear tandem axle moved forward), an instruction to supply air to the right side airbag 132a will be determined. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

After RSRT is checked, the process is repeated through Loop Connector 104, where (OP=0?) 106 is tested. The sequence will repeat the steps until the loop is closed by determining that the value of operations are equal to zero, (OP=0?) 106, Alignment Correct 108 is indicated. The testing is exited at this time through Connector 134, Receive Results 136, and Stop 138.

The above is an example and is not limited to only the instructions illustrated in FIG. 9c, but may include other instructions such as, but not limited to the instructions described in this specification. The algorithm seen in FIG. 9c may also be used with GPS axle alignment monitoring described as one embodiment of the present invention.

Alternatively, the present invention may be utilized to adjust axle 58 to compensate for uneven load by detecting the change or deviation 60a in axle 58 alignment relative to centerline 70 and then controlling an engagement and disengagement of actuator 84 (see FIG. 5a) until axle 58 is again perpendicular to the vehicle's centerline 70, thus, maintaining proper axle alignment.

Furthermore, the above algorithm may also be written to supply air to one or more tires having low air pressure when the low pressure tire affects the alignment of axle 58 (see FIG. 19).

FIG. 10 shows an example of one embodiment of the present invention where-directional sensor 40 is placed at the first fixed control point 38 (see FIG. 18 box 140) selectively established adjacent to axle 58, and a baseline device 30 is placed at the second fixed control point 58a (see FIG. 18 box 142) on or in proximity to axle 58. These two points are shown with respect to a properly aligned axle 58. During setup of the present invention, baseline device 30 may be used to establish baseline 28 perpendicular to axle 58 which, when aligned to sensor 40, is parallel to vehicle's centerline 70 and indicates that axle 58 is perpendicular to vehicle's centerline 70. Baseline 28 and sensor 40 is used for determining a measurable relationship between first point 38 and second point 58a (see FIG. 18 box 144). When baseline 28 moves from its original position it generates a signal that indicates lateral displacement (axle misalignment condition) of axle 58 (see FIG. 18 box 146). This signal may be sent to onboard computer 82, onboard display 82a, or remote computer. Furthermore, the signal may be sent from computer 82 or sensor 40 to actuator 84. Actuator 84 is shown mounted by bolts or pins 92 to frame 62 and axle 58 in a transverse direction and may be utilized for adjusting the lateral position of axle 58 (see FIG. 18 box 148). The adjustment is determined according to the relationship between sensor 40 and baseline 28.

Alternatively, sensor 40 and baseline device 30 may be mounted in a vice versa manner where sensor 40 is mounted relative to axle 58 and baseline device 30 is mounted relative to the vehicle's body or frame 62.

FIG. 11 a shows an example of one embodiment of the present invention where an electromagnetic wave device 66 is mounted at the first fixed control point 38 (see FIG. 18 box 140) at vehicle's frame or body 62 and an electromagnetic wave receiver 66a is mounted at the second fixed control point 58a (see FIG. 18 box 142) on or in proximity to axle 58. An electromagnetic wave 28 is used to measure the distance between the two fixed control points (see FIG. 18 box 144). Obtained data could be sent to computer 82 for collecting, storing, calculating, displaying, printing, or comparing distances between emitter 66 and receiver 66a. Distances may be compared to a predetermined reference frame or values to determine one or more axle alignment conditions (see FIG. 7c and FIG. 18 box 146), one or more axle alignment instructions (see FIG. 7c), and/or controlling one or more actuators 84 (see FIG. 18 box 148) mounted relative to axle 58 or a suspension member. Axle alignment condition and/or instruction may be sent to an onboard display 82a, remote computer or remote receiver 68 (seen in FIG. 5b). Alternatively, emitter 66 and receiver 66a may be mounted in a vice versa manner where emitter 66 is mounted relative to axle 58 and receiver 66a is mounted relative to the vehicle's body or frame 62.

Alternatively, the data may be used for controlling an air supply unit 160 (see FIG. 15), which may supply air to a low airbag 162 (see FIG. 15) of the vehicle's suspension or a low tire (see FIG. 19), if the low air pressure is determined to have an affect on the alignment of axle 58.

FIG. 11 b shows a telescoping trailing arm consisting of two parts: inner arm 94 and outer arm 94a. An actuator 84 is located at the trailing arm and has one end attached to inner arm 94 and the other end attached to outer arm 94a.

FIG. 12 shows an example of one embodiment of the present invention where a directional sensor 40 is mounted at the first fixed control point 38 (see FIG. 18 box 140) at vehicle's frame 62 and a laser 28a is mounted at a second fixed control point 58a (see FIG. 18 box 142) at axle 58. Laser 28a is used for measuring the distance between the two fixed control points. Obtained data could be sent to a computer 82 for collecting, storing, calculating or comparing distance between directional sensor 40 and a laser 28a (see FIG. 18 box 144). Obtained data may be sent to computer 82 for collecting, storing, calculating or comparing distance between sensor 40 and laser 28a for determining alignment condition of axle 58 (see FIG. 18 box 146). Actuator 84 is shown mounted substantially vertical to frame member 80 and oscillatory or rocker arm mechanism 88. Mechanism 88 is connected to trailing arm 94 and may be used for adjusting axle 58 (see FIG. 18. box 148). Alternatively, laser 28a and sensor 40 may be mounted in a vice versa manner where sensor 40 is mounted relative to axle 58 and laser 28a is mounted relative to the vehicle's body or frame 62. Furthermore, the data may be used for controlling an air supply unit 160 (see FIG. 15), which may supply air to a low airbag 162 (see FIG. 15) of the vehicle's suspension or a low tire (see FIG. 19), if the low air pressure is determined to have an affect on the alignment of axle 58.

FIG. 13 shows an example of one embodiment of the present invention utilizing a time of flight sensor such as a wave emitting device 28d having a built-in emitter and detector and mounted at a first fixed control point 38 (see FIG. 18 box 140) on or in proximity to the vehicle's body or frame 62. Wave emitting device 28d is used for emitting a baseline 28 in a form of wave or beam to a target located at a second fixed control point 58a (see FIG. 18 box 142) on or in proximity to axle 58 for determining a measurable relationship between the first and the second control point (see FIG. 18 box 144). Obtained data may be sent to computer 82 for collecting, storing, calculating or comparing distance between wave emitting device 28d and second point 58a at axle 58 (see FIG. 18 box 146). Actuator 84 is shown mounted substantially vertical to frame member 80 and rotary mechanism 88. Rotary mechanism 88 is connected to trailing arm 94 and may be used for adjusting axle 58 (see FIG. 18. box 148). Alternatively, wave emitting device 28d may be mounted relative to axle 58 for measuring a distance to a point on body or frame 62. Furthermore, the data may be used for controlling an air supply unit 160 (see FIG. 15), which may supply air to a low airbag 162 (see FIG. 15) of the vehicle's suspension or a low tire (see FIG. 19), if the low air pressure is determined to have an affect on the alignment of axle 58.

FIG. 14 shows an example of one embodiment of the present invention utilizing a time of flight sensor such as a camera 28b located at a first fixed control point 38 (see FIG. 18 box 140) on or in proximity to the vehicle's body or frame 62 and a target 28c located at a second control point 58a (see FIG. 18 box 142) on or in proximity to axle 58. A baseline 28 is used to determine a measurable relationship between the first and second control points (see FIG. 18 box 144). Obtained data may be sent to a computer 82 for collecting, storing, calculating or comparing distance between camera 28b and target 28c. Data may be used for determining axle alignment conditions (see FIG. 7c and FIG. 18 box 146), axle alignment instructions (see FIG. 8c), and/or controlling actuator 84 (see FIG. 8c). Actuator 84 is shown mounted to frame member 80 in a substantially horizontal position. Mounting bracket 84a or other suitable means may be used for securing actuator 84 relative to frame member 80 and bolts 92 may secure actuator 84 to trailing arm 94. Alternatively, camera 28b and target 28c may be mounted in a vice versa manner where camera 28b is mounted relative to axle 58 and target 28c is mounted relative to the vehicle's body or frame 62. Furthermore, the data may be used for controlling an air supply unit 160 (see FIG. 15), which may supply air to a low airbag 162 (see FIG. 15) of the vehicle's suspension or a low tire (see FIG. 19), if the low air pressure is determined to have an affect on the alignment of axle 58.

FIG. 15 shows one embodiment of the present invention utilizing an encoder or potentiometer 40a located at a first fixed control point 38 (see FIG. 18 box 140) selectively established on or in proximity to body or frame 62 and a mounting base 20a located at a second fixed control point 58a (see FIG. 18 box 142) on or in proximity to axle 58, trailing arm 94, or other suspension member. Mounting base 20a is used for mounting a mechanical arm or rod 30a, or relative to axle 58. Arm or rod 30a extends substantially horizontal and connects to encoder or potentiometer 40a A measurable relationship between the first control point 38 and the second control point 58a may be determined by movement of arm or rod 30a relative to encoder or potentiometer 40a (see FIG. 18 box 144). Obtained data may be sent to computer 82 for collecting, storing, calculating or comparing distance between encoder or potentiometer 40a and mounting base 20a. The data may be compared to a predetermined reference frame or values for determining one or more axle alignment conditions (see FIG. 18 box 146), one or more axle alignment instructions (see FIG. 7c), and/or controlling one or more actuators 84 (see FIG. 18 box 148) mounted relative to axle 58, or a suspension member such as trailing arm 94 for positioning of axle 58. A manual axle adjustment mechanism 88b may be used for manual adjustment of axle 58 (see FIG. 18 box 148) based on axle alignment instruction. Furthermore, the data may be used for controlling an air supply unit 160 (see FIG. 15), which may supply air to a low airbag 162 (see FIG. 15) of the vehicle's suspension or a low tire (see FIG. 19), if the low air pressure is determined to have an affect on the alignment of axle 58.

FIG. 16 shows one example of a disassemble view of my prior art axle alignment utilizing a mechanical link as an indicator, arm, or line segment 28. A mounting plate 20 is attached to axle 58 by U shaped bolts 26. A sensor support bracket 36 is attached to the inside section of frame rail 62. A segmented plane 40 is attached to sensor support bracket 36. Sensor support bracket 36 should be attached to only one side of frame rail 62 and not to a cross-member of the vehicle. Attaching sensor support bracket 36 (containing sensor 40) to only one side of frame 62 provides means for detecting a diamond condition as the sensor support bracket is fixed to frame 62 while axle 58 will become skew to sensor bracket 36 (and sensor 40) upon a diamond frame condition. Support bracket 36 may be attached to the vehicle using any means which may be accepted by the vehicle manufacture. Indicator 28 has a first end attached to a hinge 32 located on mounting plate 20 and the second end connected to sensor support bracket 36 coupled by an indicator guide 46. Indicator guide 46 is inserted into a longitudinal groove 50 located at the end of indicator 28 and inserted into a slot 48 positioned transverse to segmented plane 40. The connection of hinge 32 and indicator guide 46 maintains the relation between indicator 28 and segmented plane 40 by allowing indicator 28 to slide left, right, forward and rearward of central path 64 during suspension travel and axle deviation. Position sensor 34 is shown along a central path 64 of segmented plane 40. A plate cover 22 is attached to mounting plate 20 and has an opening 24 on one side. A sensor cover 52 is placed over segmented plane 40 attached to sensor support bracket 36. The sensor cover 52 has an opening 24 on one side. Opening 24 of plate cover 22 and opening 24 of sensor cover 52 faces one another and are connected by housing tube 56 with flex boot 54 at each end. Indicator 28 is located inside of housing tube 56. Indicator 28 is positioned in line with the path 64 of segmented plane 40. Housing tube 56 and flex boots 54 are used for keeping indicator 28 clean from road and weather conditions. A wiring connection 42 is used to connect the apparatus to a vehicle's power system. An auxiliary battery (not shown) may be used with an on/off or reset switch 44 for checking and correcting axle alignment when the vehicle is not in service such as stationary or when electrical power is unavailable.

FIG. 17 shows an assembled view of my prior art alignment apparatus seen in FIG. 16 which is mounted between vehicle's axle 58 and frame 62. Actuator 84 is attached to frame member 80 at one end and cam mechanism 88 at the other end. Line segment 28 of the axle measuring device is shown projected between axle 58 and sensor 40.

FIG. 18 shows one method for installing the present invention onboard a vehicle. Step one 140 establishes a first point onboard a vehicle; step two 142 establishes a second point onboard the vehicle; step three 144 provides means for measuring a relationship between the first point and the second point while the vehicle is either stationary or in motion; step four 146 provide means for determining at least one axle alignment condition based on the measured relationship; step five 148 is an optional step that could be used to provide means onboard the vehicle for adjusting an axle based on the measured relationship.

FIG. 19 shows a level sensor 164 mounted on axle 58, which may be used in conjunction with the present invention for distinguishing between axle misalignment due to a low tire 166 or axle misalignment due to an uneven weight load.

Advantages

From the descriptions above, the following advantages become evident when using the present alignment apparatus:

• • Reducing driver fatigue;
  • Reducing tire wear;
  • Reducing tire temperature;
  • Reducing tire failure;
  • Reducing rolling resistance;
  • Reducing component vibration and wear;
  • Reducing operating cost;
  • Improving highway safety;
  • Improving fuel economy;
  • Improving vehicle efficiency and performance;
  • Performing automatic axle alignment during dynamic driving conditions.

Ramifications and Scope

Accordingly, the reader will see that the present invention can be made and designed in different ways in order to achieve the desired results. Although the description above contains much specificity, these should not be construed as limiting the scope of the present invention, but as merely providing illustrations of some of the presently preferred embodiments of my apparatus.

For example, the structure of the present invention may have other shapes such as circular, oval, triangular, etc. The parts of the present invention may be made of any material such as aluminum, metal, plastic, fiberglass, etc. Also various sizes may be used for any of the parts such as the actuator, cams, etc.

The present invention may be any means to point, indicate or link the axle's alignment to the direction of the vehicle's centerline, geometric centerline, or direction of vehicle travel or link to any other component that will compare the axle's alignment to one or more predetermined points located on the vehicle and/or to a predetermined value.

The baseline may be chosen from a variety of means such as mechanical, laser, camera, ultra sonic, magnetic, electromagnet, electrical, optical, wave, pressure or non-pressure sensor, calculation, or other suitable means which will point, touch, measure, or indicate a relative position or spatial relationship between the first fixed point located onboard the vehicle such as on or in proximity to the body, frame, suspension, or axle and the second fixed point on or in proximity to an axle or suspension member.

A controller of the present invention may include means such as a computer or logic system for transmitting and receiving signals utilizing wire or wireless, fiber optics, radio waves or Bluetooth, or other suitable means for communicating axle alignment and related data, such as axle alignment conditions or instructions, to an actuator, receiver or handheld receiver, onboard display, remote computer, or onboard computer. The signals used to indicate and transmit axle alignment data and/or instructions may include wireless signals such as cell or satellite signals. These signals may be sent to a main dispatch terminal to notify an operator of axle alignment conditions or the adjustment made to a particular axle by the onboard axle alignment system.

The present invention can be embodied in part in the form of computer-implemented processes and apparatuses for practicing those processes. The present invention can also be embodied in part in the form of computer program code containing instructions embodied in tangible media, such as floppy diskettes, CD-ROMs, memory chips, hard drives, or any other computer readable storage medium, wherein, when the computer program code is loaded into and executed by an electronic device, such as a computer, micro-processor or logic circuit, the device becomes an apparatus for practicing the invention.

The present invention may also include a receiver or transmitter which may be used to communicate axle alignment condition during a manual routine axle alignment check when the vehicle is not in operation. For example, a vehicle may require an axle alignment check before the vehicle is assigned for operation. The technician may have a receiver which can link to and check any vehicle that has the present alignment apparatus installed and perform radio controlled axle alignment using the remote transmitter or perform the axle alignment manually if necessary. An auxiliary battery could be used to power the present invention when no other power source is available.

The above embodiments of the present invention may further be arranged in any combination or configuration suitable for determining a measurable relationship between two or more points located onboard the vehicle. The measured relationship between points located onboard the vehicle may include, but not limited to, vector angles and/or baseline vectors originating from either location point.

Alternatively, when using GPS as one embodiment of the present invention, a GPS receiver antenna may be mounted on the right side of the axle, a GPS receiver antenna may be mounted on the left side of the axle, and a GPS receiver antenna may be mounted on the vehicle's outer body or roof and is used as a master control point. GPS data received from the GPS antennas located at the right side axle and at the roof may be stored by a computer for comparison until GPS data from the GPS antennas located at the left side axle and roof is collected. Alternatively, a wheelbase measurement may be obtained utilizing a GPS receiver antenna at one axle and a GPS receiver antenna at another axle, which are on the same side of the vehicle, and utilizing a GPS receiver antenna located at the roof to determine a distance between the two GPS antennas located at the axles.

Alternatively, multiple GPS antennas may be arranged in a compass orientation onboard the vehicle. For example, a first set of GPS antennas may be utilized on or in proximity to the vehicle such as on the vehicle's outer body or roof and arranged to establish a line perpendicular to the vehicle's centerline. A second set of GPS antennas may be attached in a line relative to a central axis of a hub or wheel cap located at the outer end of an axle. This configuration, with respect to a proper axle alignment condition, establishes a baseline which is perpendicular to the vehicle's centerline and parallel to the axles. Any deviation from parallelism would be detected by GPS means and used for determining one or more axle alignment conditions, one or more axle alignment instructions, and/or controlling one or more axle alignment actuators attached relative to the vehicle's axle or suspension member. Alternatively, the GPS antennas may be arranged in any orientation about the vehicle and still achieve the desired function of the present invention.

The axle' alignment may be further monitored and compared with the vehicle's performance data gathered through monitoring engine operating conditions, speed, rpm, cylinder head pressure, temp, torque, thrust, transmission parameters, tire pressure, and vehicle front end suspension movement. A driver's physical condition may be evaluated or estimated based on the obtained data, such as physical effort to steer the vehicle.

Additional sensors may be included in conjunction with the present invention such as a steering sensor mounted relative to the vehicle's front steering and in communication with the present axle alignment invention. This combination may be used for actively communicating axle alignment conditions relative to the front steerable axles with respect to the non-steerable axles which may be used for distinguishing between axle alignment conditions and wheel alignment conditions.

The present invention, when used on multiple axles and multiple vehicles such as a tractor trailer vehicle, may identify the particular vehicle (tractor or trailer), the particular axle (first, second, or third from the rear), the particular side of the axle (left or right), the particular direction in which to align the axle (forward, rearward, transverse), and to determine when the axle's alignment is correct.

The present invention may include timers as part of the control and logic system for controlling signals in order to dampen, delay, or maintain a consistent sequence of events on corrective actions.

The telescoping trailing arm described in FIG. 5a may alternatively include a manual adjustment for adjusting the trailing arm. The adjustment may include positioning means such as but not limited to rotary, oscillatory, or linear.

The camera described in FIG. 14 may be selected from the group of rangefinder devices such as optical depth sensors, CCD sensors, CCD camera, or CMOS camera, LED, depth perception light sources, radiated light in 2D or 3D, radiation emitter, radiation detector, position sensitive detector, or other suitable radiation source which may be used for communicating a distance between the camera and an object used as a reference point or bench mark, whereby a distance between two or more points onboard the vehicle may be determined.

The present invention may further include, but not limited to, utilizing a satellite of the Global Positioning Satellite (GPS) network, a satellite of the Galileo satellite network, a satellite of the Global Navigation Satellite System (GLONASS) network, a Wide Area Augmentation System (WAAS) enabled satellite and a European Geostationary Navigation Overlay Service (EGNOS) enabled satellite. The invention may further include Differential Global Positioning System (DGPS) and one or more DGPS equipped receivers and antennas. The invention may utilize a combination of GPS and Inertial Measurement Unit (IMU) or other suitable measurement means for determining a measurable relationship between two or more points located onboard the vehicle and use this information to determine one or more axle alignment conditions, one or more axle alignment instructions, and/or controlling one or more actuator devices mounted relative to the vehicle's axle or suspension member. Alternatively the present invention may utilize GPS receiver and antennas coupled with a computer for determining axle misalignment caused by a leaning vehicle such as having an uneven load, low airbag, or low tire.

In addition to the above description, the present alignment apparatus and method should not be limited to only alignment of tractor trailer axles but may be used for automatically aligning suspension control arm, or axles of other vehicles, such as passenger cars, van, trucks, buses, race cars, rail vehicles, and aircraft tandems.

Many features and advantages of the present invention are apparent from the detailed specifications. The appended claims are intended to cover all such features and advantages of the invention which fall within the true spirit and scope of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation illustrated and described and accordingly all suitable modifications and equivalents may be resorted to falling within the scope of the invention.

Claims

1. A method for determining a vehicle's axle alignment condition while said vehicle is either stationary or in motion, comprising: establishing a first point on or in proximity to the vehicle's body or frame; establishing a second point on or in proximity to the vehicle's axle; providing means for determining a measurable relationship between said first and said second point; and using said measurable relationship for determining said axle alignment condition.

2. A method for determining a vehicle's axle alignment condition while said vehicle is either stationary or in motion, comprising: providing means onboard said vehicle for determining a measurable relationship between two or more points located on said vehicle; and determining said axle alignment condition based on said measurable relationship, whereby said axle alignment condition can be determined while said vehicle is said stationary or in motion.

3. The method as in claim 2, further comprising establishing an association between said measurable relationship of said points and at least one selected from the group consisting of a vehicle's body or frame centerline, vehicle's geometric centerline, or vehicle's direction of travel.

4. The method as in claim 2, further comprising providing means for calculating a distance between said points by utilizing a Global Positioning System or satellite network.

5. The method as in claim 2, further comprising providing at least one wave source selected from the group consisting of a light wave, electromagnetic wave, or ultra sonic wave, whereby said wave source can be used in the process of determining said measurable relationship.

6. The method as in claim 2, further comprising providing an encoder or potentiometer used in the process of determining said relationship between said points.

7. The method as in claim 2, further comprising providing at least one algorithm selected from the group consisting of determination of an axle alignment condition, instruction for axle alignment or realignment, instruction for controlling an axle alignment actuator, instruction for controlling air supply to one or more airbag suspensions, or instruction for controlling air supply to one or more tires.

8. The method as in claim 2, further comprising providing one or more actuators mounted on or in proximity to an axle or suspension member, said actuator being selected from the group consisting of linear, rotary, or oscillatory.

9. The method as in claim 2, further comprising at least one selected from the group consisting of a computer for processing data relative to said axle alignment condition, a display for viewing information relative to said axle alignment condition, or a remote receiver for receiving information relative to said axle alignment condition.

10. An apparatus for determining a vehicle's axle alignment condition while said vehicle is either stationary or in motion, comprising: means onboard a vehicle for determining a measurable relationship between two or more points located on said vehicle; and means for determining at least one axle alignment condition based on said measurable relationship, whereby said axle alignment condition can be determined while said vehicle is said either stationary or in motion.

11. The apparatus as in claim 10, wherein said means for determining a measurable relationship between said points further comprises a GPS receiver.

12. The apparatus as in claim 10, wherein said means for determining a measurable relationship between said points further comprises at least one wave source selected from the group consisting of a light wave, electromagnetic wave, or ultrasonic wave.

13. The apparatus as in claim 10, wherein said means for determining a measurable relationship between said points further comprises at least one algorithm selected from the group consisting of determination of an axle alignment condition, instruction for axle alignment or realignment, instruction for controlling one or more axle alignment actuators, instruction for controlling air supply to one or more airbag suspensions, or instruction for controlling air supply to one or more tires.

14. The apparatus as in claim 10, further comprising one or more directional sensors for detecting a baseline relative to a vector or vector angle.

15. The apparatus as in claim 10, further comprising one or more encoders or potentiometers used in combination with a mechanical rod or linkage.

16. The apparatus as in claim 10, further comprising one or more actuators mounted on or in proximity to an axle or suspension member, said actuator being selected from the group consisting of linear, rotary, or oscillatory.

17. The apparatus as in claim 10, further comprising a telescoping trailing arm.

18. The apparatus as in claim 10, further comprising a remote receiver or remote computer.

19. The apparatus as in claim 10, further comprising an onboard display.

20. The apparatus as in claim 10, further comprising an air supply unit.