RU2765195C1 - Stand for testing pneumatic tires and elastic elements of vehicle suspensions - Google Patents

Abstract

FIELD: vehicles.

SUBSTANCE: invention relates to stands for testing elastic elements of vehicle suspensions and pneumatic tires. The stand for testing pneumatic tires and elastic elements of vehicle suspensions contains a base on which a traverse is installed, a folding hydraulic cylinder and a loading mechanism. The loading mechanism is installed on a pivot frame, between the end of which and the base, a screw mechanism is hingedly mounted. The axis of the swing frame is fixed on the lower part of the stand base and coincides with the vertical axis of the tire loading. The pusher drive is made in the form of a hydro-pulsator, which is installed vertically on the swing frame of the stand to the side of the caterpillar drive and is connected through a servo-hydraulic distributor with the pump and the hydraulic station tank. The upper branch of the track is secured against lateral displacement by means of two side rollers mounted horizontally on a vertical guide.

EFFECT: possibility of carrying out bench tests of a single-support suspension unit together with a rolling wheel on a hard surface with a different profile of irregularities.

1 cl, 8 dwg

Description

The invention relates to test equipment, namely to benches for testing elastic elements of vehicle suspensions and pneumatic tires, designed to determine the static and dynamic elastic characteristics and vibration-proof properties of the tested elements, as well as the characteristics of side slip and tire rolling resistance.

A well-known stand for static testing of tires of wheeled vehicles, containing a mechanism for loading the wheel with a vertical force, providing simulation of various loads, a mechanism for turning the wheel around a vertical axis and a plate chain conveyor with a flat rigid supporting surface of the plates, fixed from displacement in lateral directions and providing an unlimited rolling length wheels with minimal friction, and sensors of acting forces, movement of the support platform and deformation of the wheel tire (utility model patent 161103 RF, IPC G 01 M 17/02, 2015).

The disadvantage of this stand is the impossibility of determining the dynamic characteristics and vibration-proof properties of tires and suspension elements when loading the wheel and suspension with a real sprung mass and setting a different nature of the kinematic loading that simulates wheel rolling on a solid surface with different heights and frequency of irregularities, including random law , which is the main mode of loading vehicles.

The closest of the known technical solutions is a stand for testing pneumatic tires and elastic elements of vehicle suspensions, containing a base on which a mechanism for loading the tested elements is installed, including a crank mechanism connected to the drive and resting with its middle part on the base through a movable support rocker, one end of which is connected to the connecting rod through a safety mechanism and is connected to the base through a balancing mechanism, and the other end is connected through the test elements to the traverse, on which the load is suspended by means of a movable frame, two tilting hydraulic cylinders installed between the traverse and the base, an inertial mechanism installed between load and base, and measuring elements. The loading mechanism is additionally equipped with a pusher installed in a vertical guide mounted on the base, connected to the rocker arm and having support elements on the upper part, made in the form of two rubber-coated rollers and hard rollers installed between them in a checkerboard pattern, onto which, through a caterpillar belt with replaceable irregularities, having an elastic tension mechanism and enclosing the driven and driving drums mounted on the base, the tested elements connected with the traverse are supported, and the drive of the driving drum is connected through the clutch with the drive of the crank mechanism. In addition, the loading mechanism is additionally equipped with a swivel fork, on the vertical posts of which the axle of the test wheel hub is mounted, the upper part of the fork is connected to the crosshead through the tested elastic element, and through a swinging lever with a cardan joint it is connected to the movable frame, and the ends of the vertical posts are connected by means of two parallel adjustable rods are connected to each other with the base, and one of these racks is located between the rollers of the swing arm connected to the pusher, while the swing arm and the swing fork have one vertical axis intersecting with the axis of rotation of the tested wheel and passing through the center of the cardan joint, and the axles rollers and adjustable rods are located in the plane of contact of the tested wheel with the track (patent for invention 2133459 RF, IPC G 01 M 17/02, 1999).

This stand has a relatively low technical level, due to limited functionality to provide it with a loading mechanism of the random nature of the kinematic excitation of vibrations, which is the main mode of loading tires and suspension elements of vehicles. As a result, the stand does not allow to determine the real dynamic elastic characteristics of the rolling wheel, the forces and moments of rolling resistance, side slip characteristics, as well as the vibration-protective properties of the rolling wheel and suspension, taking into account the random nature of the impact from road roughness in the entire frequency range of transport vibration. In addition, due to the location of the loads under the caterpillar mover by hanging them to the traverse by means of a movable frame with a large vertical stroke, this stand has a caterpillar mover located high relative to the base, which makes it difficult to install and test, especially large diameter wheels.

In this regard, an important technical task is to create a new design of a bench for testing pneumatic tires and elastic elements of vehicle suspensions with fastening loads on top of the traverse and a new loading mechanism that provides different laws of kinematic loading, including the random nature of the distribution of irregularities, as well as the rotation of the caterpillar mover relative to the base at small angles and its installation at a lower height.

The technical result of the claimed invention is the possibility of carrying out bench tests of a single-support suspension unit together with a rolling wheel without and with tire side slip on a hard surface with a different profile of irregularities, including the random nature of their distribution, characteristic of real roads, as well as facilitating installation and testing, in including large diameter wheels, as well as facilitating the installation and fixing of the swing frame at a given angle.

The specified technical result is achieved by the fact that in the stand for testing pneumatic tires and elastic elements of vehicle suspensions, containing a base on which a traverse connected to the loads is installed by means of a movable frame in the vertical direction, a tilting hydraulic cylinder installed between the traverse and the base, and a loading mechanism test elements, including a caterpillar mover and a pusher connected to the pusher drive, installed in a vertical guide and having support elements on the upper part, made in the form of rigid rollers staggered, forming a roller table, on which through the caterpillar belt, covering the driven drum and the drive the drum connected with the drive of the caterpillar mover, the test elements connected with the traverse are supported, the loads are fixed on top of the traverse, and the loading mechanism is mounted on a rotary frame, between the end of which and the base a screw mechanism is pivotally mounted, the axis of which which is perpendicular to the radius drawn from the axis of the swivel frame to the hinge of the screw mechanism installed on it, while the axis of the swivel frame is fixed on the lower part of the stand base and coincides with the vertical axis of the tire loading, the pusher drive is made in the form of a hydraulic pulsator having a rod with a piston placed in housing, which is installed vertically on the rotary frame of the stand on the side of the caterpillar mover and through a servo-hydraulic distributor communicates with the pump and the tank of the hydraulic station, the pusher is made in the form of a vertical guide, which is installed on the rotary frame between the caterpillar mover and the hydraulic pulsator with the possibility of vertical movement, inside the vertical guide are installed two guide rollers, the axes of which are connected to the swivel frame, in the middle part of the vertical guide there is a side support, on top of which the roller table is fixed, at the upper end of the vertical guide there is an upper support resting on the end of the rod hydraulic pulsator, and the upper branch of the caterpillar tape is fixed from displacement in the lateral direction with the help of two side rollers mounted horizontally on a vertical guide.

Due to the fact that the weights are fixed on top of the traverse, a significant reduction in the installation height of the caterpillar mover and the tested elements relative to the stand base is provided, which facilitates the preparation and testing, especially of large diameter wheels.

Due to the fact that the loading mechanism is installed on a rotary frame, the axis of which is fixed on the lower part of the stand base and coincides with the vertical axis of the tire loading, and the upper branch of the track is fixed from displacement in the lateral direction using two side rollers, it is possible to test a tire with a side without turning the wheel relative to the base and the movable frame of the stand, which simplifies the fastening of the suspension elements and the wheel with a pneumatic tire to the movable frame and registration of the forces and moments acting on the wheel and suspension, and also allows testing large diameter wheels.

Due to the fact that the pusher drive is made in the form of a hydraulic pulsator having a rod with a piston placed in a housing that is installed vertically on the rotating frame of the stand on the side of the caterpillar mover and communicates with the pump and hydraulic station tank through a servo-hydraulic distributor, and the pusher is made in the form of a vertical guide, which is mounted on a rotary frame between the caterpillar mover and the hydraulic pulsator with the possibility of vertical movement, inside the vertical guide there are two guide rollers, the axes of which are connected to the rotary frame, in the middle part of the vertical guide there is a side support, on top of which the roller table is fixed, at the upper end of the vertical guide there is the upper support resting on the end of the hydraulic pulsator rod ensures vertical movement of the middle part of the upper branch of the caterpillar belt, on which the wheel rests during rolling, which is necessary to maintain the trajectory of the upper branch of the caterpillar tape simulating different laws of kinematic loading of the pusher, including their random nature. This expands the conditions of bench tests and brings them closer to the real modes of operation of the suspension and wheel rolling on rough roads. In addition, the reduction of axial and lateral forces acting on the hydraulic pulsator rod is ensured, which increases the reliability of its operation and facilitates the layout of the pusher drive and the supply of flexible pipelines from the pump and the hydraulic station tank to the servo-hydraulic distributor of the hydraulic pulsator installed on the side of the caterpillar mover.

Due to the fact that the upper branch of the track is fixed from displacement in the lateral direction with the help of two side rollers mounted horizontally on a vertical guide, the vertical movement of the side rollers is ensured along with the upper branch of the track under the action of the pusher and the perception of the lateral force that occurs during side slip tires in the contact patch with the ground. As a result, the upper branch of the caterpillar does not change its trajectory when turning at a small angle of the swing frame together with the caterpillar mover in a clockwise direction, which makes it possible to more accurately determine the side slip force of the tire.

Due to the fact that a screw mechanism is pivotally mounted between the base and the end of the swivel frame, the axis of which is perpendicular to the radius drawn from the axis of the swivel frame to the hinge of the screw mechanism installed on it, the minimum moment on the screw is ensured, and it also facilitates installation at the required angle and fixation of the swivel frame relative to the base of the stand when testing tires with side slip.

The general view of the stand (without the tested elements) is shown in Fig. 1, a caterpillar mover with a pusher - in Fig. 2, pusher (view from the reverse side) - in Fig. 3, side view of the stand (with test elements) - in Fig. 4, remote elements of Fig. 4 - in Fig. 5-8.

The stand for testing pneumatic tires and elastic elements of vehicle suspensions contains a base 1 having a lower flat part and an upper part made in the form of a vertical rack 2, on which vertical guide elements are installed in the form of two longitudinal skids with four movable roller bearings 3 connected to movable frame 4, made in the form of a plate with numerous holes for mounting different types of tested elements. On the upper part of the movable frame 4 there is a traverse 5 with a load 6 fixed on top of it, which is made of separate cast-iron bars, which allows you to change the sprung mass (Fig. 1 and 4).

On the lower part of the base 1 there is a rotary frame 7 (Fig. 1, 2 and 4), the axis 8 of which is fixed on the base 1 and coincides with the vertical loading axis of the test tire 9 (Fig. 4). Between the lower part of the base 1 and the end of the swivel frame 7, a screw mechanism 10 is pivotally mounted, the screw of which is connected to the base 1, and the nut 11 is pivotally connected to the swivel frame 7 (Fig. 2). In this case, the axis of the screw mechanism 10 is perpendicular to the radius drawn from the axis 8 of the rotary frame 7 to the nut 11 of the screw mechanism 10 installed on it, which makes it possible to rotate the frame 7 around the axis 8 at a small angle α = 0 ... 10 degrees. (Fig. 1, 2).

On the rotary frame 7 there is a mechanism for loading the tested elements, which includes a caterpillar mover (Fig. 1, 2) and a pusher (Fig. 2, 3).

The caterpillar mover includes a caterpillar belt 12, covering the driven drum 13 and the driving drum 14 mounted on the rotary frame 7, connected to the electric motor 15 through a belt or chain transmission 16. The driving drum 14 and the driven drum 13 are made in the form of rubberized rollers, and the driven drum 13 is installed on a crank connected by a tension spring 17 to the swivel frame 7, which provides tension to the upper and lower branches of the caterpillar belt 12 during the vertical movement of the upper branch under the action of the pusher (Fig. 2).

The pusher is made in the form of a vertical guide 18 mounted for vertical movement on a rotary frame 7 next to the caterpillar mover. Inside the vertical guide 18, two guide rollers 19 are installed, the axes of which are mounted on a vertical bracket 20 fixed on a rotary frame 7. On the side of the vertical guide 18 in its middle part there is a side support 21, on top of which a roller table 22 is fixed, made in the form of staggered rigid rollers (Fig. 3). At the upper end of the vertical guide 18 there is an upper support 23 resting on the end of the rod 24 of the hydropulsator 25 (Fig. 3).

The upper branch of the caterpillar belt 12 rests on the roller table 22 and is fixed from displacement in the lateral direction with the help of two side rollers 26 mounted horizontally on the vertical guide 18.

A piston 27 with a rod 24 is installed in the body of the hydropulsator 25, forming a piston 28 and a rod cavity 29 in it (Fig. 5, view A). The cavities 28 and 29 are connected through a servo-hydraulic distributor 30 with a pump and a hydraulic tank (not shown in the drawings). Software operation of the servo-hydraulic distributor 30 allows you to perform the following modes of movement of the rod 24: harmonic; triangular (with constant speed); rectangular; in the form of a short pulse; random law simulating a real road profile.

The tested tire 9 is mounted on the upper branch of the caterpillar belt 12 and attached to the movable frame 4 with the help of guide levers 31, on which the elastic and damping elements of the suspension under test are installed (in Fig. 4).

To ensure the installation and removal of the tested elements of the suspension and tire 9, a winch 32 is installed on the base 1, and an arrow 33 with blocks on the vertical rack 2, through which the cable 34 is thrown with a hook 35 at its end (Fig. 1 and 4).

For an additional possibility of moving the movable frame 4 relative to the vertical rack 2 and testing with free vibrations of the sprung mass on the test suspension and tire 9 along the vertical rack 2 between the base 1 and the movable frame 4, a tilting hydraulic cylinder 36 is installed, which has rollers 37 at the end of the rod, included in nest 38, fixed on the movable frame 4 (Fig. 1 and 4; Fig. 6, view B and Fig. 8, view D).

To tilt the hydraulic cylinder 36 on the movable frame 4, a lever lock-tilt mechanism is installed, the lever 39 of which, through the rod 40, is pivotally connected to the rotary lock 41, which has a pin for entering the end hole of the rod of the hydraulic cylinder 36 and a spring-loaded bolt 42, installed perpendicular to the axis of the hydraulic cylinder 36 and interacting with the upper end of its stem (Fig. 8, view D).

To fix the movable frame 4 with the traverse 5 and the load 6 relative to the vertical rack 2 of the base 1, at any mutual position, a locking mechanism is installed between them, which is made in the form of two spring-loaded clamping bars 43 mounted vertically on the tie bolts 44. The bolts 44 are installed movably in horizontal holes of the movable frame 4. The left ends of the bolts 44 are located in the longitudinal slots of the vertical rack 2, made in the form of I-beams, and are threaded for connection with the left clamping bar 43. The right clamping bar 43 can move along the axis of the bolts 44 until it stops against the outer ledges bolts 44. Between the bars on the bolts 44, compression springs are installed, expanding the clamping bars 43 in different directions, which provides gaps on both sides of the I-beam shelves of the vertical rack 2. Bolts 44 provide reliable fixation of the movable frame 4 relative to the vertical rack 2, which is necessary for determination of static elastic characteristics teak tire 9 and the elastic element of the suspension, as well as to determine the working diagrams of the tested elements during dynamic tests. To perceive the vertical load when the movable frame 4 is fixed relative to the vertical post 2, the upper and lower horizontal stops 45 are fixed on the movable frame 4, which are installed in the longitudinal slots of the vertical post 2 on both sides close to the upper and lower ends of the clamping bars 43 (Fig. 4; Fig. 7, view B).

The measuring elements of the stand include four force sensors, four displacement sensors, two vertical acceleration sensors and a rotation angle sensor, which are connected to the measuring complex of the stand. To fix the readings, strain gauge measuring equipment is used.

The proposed stand works as follows.

To install the tested elements of the suspension and tire 9 on the stand, the reclining hydraulic cylinder 36 is manually transferred to a vertical position (Fig. 1 and 4). At the same time, the length of the hydraulic cylinder 36 is set such that its rollers 37 enter the wedge-shaped socket 38 mounted on the movable frame 4, and the pin of the rotary lock 41 of the lever lock-tilt mechanism - into the end hole of the hydraulic cylinder rod 36 (Fig. 6, view B and Fig. 8, view D). Further, with the help of locking bolts 44 of the blocking mechanism, a gap is created between the I-beam shelves of the vertical rack 2 and spring-loaded clamping bars 43, as a result of which the movable frame 4 is unlocked relative to the vertical rack 2 of the base 1 (Fig. 7, view B).

With the help of the hydraulic cylinder 36, the traverse 5 with the load 6 is lifted to the required height to be able to be installed on the upper branch of the caterpillar belt 12 of the test suspension and the tire 9, which are lifted by the winch 32 by means of the cable 34, the boom 33 and the hook 35. Then the test suspension is fixed with the tire 9 on the movable frame 4 with the help of guide levers 33 (Fig. 4). At the same time, with the help of the screw mechanism 10 and the nut 11, the required angle b of rotation of the frame 7 around the axis 8 is set, providing a given tire slip angle 9 within 0 ... 10 degrees relative to the direction of movement of the track 12 (Fig. 1 and 2).

Determination of the static elastic characteristics of the tested suspension and tire 9 is possible in two ways: using a hydraulic cylinder 36 and a hydraulic pulsator 25.

When using a hydraulic cylinder 36, the movable frame 4 is slowly moved up and down, compressing or expanding the elements under test.

When using a hydropulsator 25, the movable frame 4 is fixed relative to the vertical rack 2 with the help of locking bolts 44, which press the spring-loaded strips 43 on both sides to the shelves of the I-beams of the vertical rack 2, which are installed between the upper and lower horizontal stops 45, fixed on the movable frame 4. Next, with with the help of a hydraulic station, the rod 24 of the hydraulic pulsator is slowly moved, the body 25 of which is installed vertically on a rotary frame 7 next to the caterpillar mover in a plane passing through the vertical axis of loading of the test tire 9. Together with the rod 24, the upper support 23 of the vertical guide 18 moves, inside which two guides are installed roller 19, the axes of which are mounted on a vertical bracket 20, fixed on a rotary frame 7. Together with the vertical guide 18, the side support 21 installed in its middle part moves, on top of which the roller table 22 is fixed, on which the upper branch of the caterpillar belt 12 rests, which leads to compression or tension of the tested suspension elements and tire 9 mounted on top of the track 12 (Fig. 3 and 4). When this hydropulsator 25 operates as follows.

In the course of compression of the tested elements, the liquid from the pumping station through the servo-hydraulic distributor 30 enters the piston cavity 28 of the hydraulic pulsator 25, the piston 27 with the rod 24 moves up and displaces the liquid from the rod cavity 29 into the tank of the pumping station. In the course of stretching the tested elements, the liquid from the pumping station through the servo-hydraulic distributor 30 enters the rod cavity 29 of the hydropulsator 25, the piston 27 with the rod 24 moves down and displaces the liquid from the piston cavity 28 into the tank of the pumping station (Fig. 5, view A).

In this case, the deformations of the tested elements are simultaneously measured by the corresponding displacement sensors and the load along the loading axis by the force sensor. According to the results of measurements in the coordinates "force - deformation", the static elastic characteristics of each tested element are built.

Testing of the elements of a single-support suspension and tires 9 during free vibrations can be carried out on the stand in the following ways: by dropping the sprung mass and by pulling up using a reclining hydraulic cylinder 36, as well as by pushing the tested elements up or down using a hydraulic pulsator 25.

To carry out tests during free oscillations by the dropping method, the movable frame 4, together with the load 6 and the tested elements, is lifted by the hydraulic cylinder 36 until the test tire 9 is separated from the upper branch of the track 12 by a predetermined value. Then, a sharp downward pressure is made on the lever 39 of the lock-and-tilt mechanism, as a result of which, through the rod 40, the lock 41 is rotated counterclockwise, the pin of which comes out of the end hole of the hydraulic cylinder rod 36. At the same time, the upper end of the hydraulic cylinder rod 36 is pushed out by the spring-loaded bolt 42 to the right side, as a result of which the rollers 37 come out of the socket 38 (Fig. 8, view D), and the hydraulic cylinder 36 leans to the side until it stops in the restrictive buffer of the vertical column 2 (Fig. 1). Under the action of the sprung weight, the load 6 falls down and after the test tire 9 touches the upper branch of the track 12, the sprung mass performs free damped oscillations on the test suspension and tire 9, which can be recorded using a displacement sensor and recording equipment of the test bench.

To carry out tests during free vibrations by pulling up with a hydraulic cylinder 36, the movable frame 4 is lowered down together with the load 6, compressing the suspension under test and the tire 9 by the calculated value. By pressing the control lever 39, the hydraulic cylinder 36 leans to the side. Under the action of the compression force of the tested elements, the load 6, together with the traverse 5 and the movable plate 4, moves upward. In this case, the movable frame 4 moves along the vertical guides of the stand in ball bearings 3.

For testing with free vibrations by the push method, using the hydropulsator 25, an impulse is set up or down, as a result of which its rod 24 moves sharply up or down by a given value. This leads to a sharp movement of the vertical guide 18 together with the side support 21 and the roller table 22, on which the tested wheel with tire 9 rests through the upper branch of the caterpillar belt 12. As a result, the load 6 receives an upward or downward force impulse through the tested elements, which causes its free damped vibrations on the movable frame 4, which are also recorded by the measuring system of the stand.

To determine the dynamic characteristics of the tested suspension with tire 9, they are compressed by a hydraulic cylinder 36 to a predetermined value and the movable frame 4 is blocked relative to the vertical rack 2 using clamping bars 43 and locking bolts 44 of the blocking mechanism (Fig. 8, view B). Using hydropulsator 25 set the loading mode with different frequency and amplitude of movement of its rod 24, including the random nature of their distribution.

The movement of the rod 24 causes a vertical movement of the side support 21, the roller table 22 and the upper branch of the caterpillar belt 12, covering the driven 13 and 14 drums mounted on the rotary frame 7. When the caterpillar drive is turned on, the drive drum 14, connected to the electric motor 15 through a belt or chain drive 16, drives the track 12, the tension of which is provided by the tension spring 17 of the tension mechanism. The movement of the track 12 causes the rotation of the tested wheel with tire 9. The speed of the track 12, and hence the rolling speed of the tested wheel with tire 9, can be changed smoothly by adjusting the speed of the electric motor 15 (Fig. 1 and 2), for example, using a frequency converter. At the same time, using force sensors and displacement sensors, the dynamic characteristics of the tested elements are determined (working diagrams, dynamic elastic characteristics and damping characteristics).

To determine the amplitude and phase-frequency characteristics of the oscillations of the sprung and unsprung masses, the test suspension and tire 9 are loaded with a sprung mass, the value of which is set by the weight of the cast-iron bars 6 fixed on the traverse 5. Next, the hydraulic pulsator 25 sets the harmonic law of movement of the side support 21 of the vertical guide 18 with different frequencies , causing forced oscillations of the sprung and unsprung masses. Movements of the vertical guide 18 (kinematic disturbance), loads 6 (sprung mass) and wheel axle with tire 9 (unsprung mass), as well as their accelerations are recorded by sensors. These data are fed into the measuring complex of the stand, which records oscillograms of oscillations of the sprung and unsprung masses and kinematic disturbance, on the basis of which it is possible to construct amplitude-frequency and phase-frequency characteristics of absolute and relative displacements and accelerations, characterizing the vibration-protective properties of the elastic elements of the suspension and the non-rotating tire 9. Similarly, tests are carried out with a rotating tire 9, for which a caterpillar drive is turned on.

To determine the coefficient of tire rolling resistance on a solid road surface in the absence of kinematic perturbation, the test tire 9 is pressed against the track 12 either by the hydraulic cylinder 36 or the rod 24 of the hydraulic pulsator 25 to a given load determined by the force sensor, and the movable frame 4 is blocked relative to the vertical rack 2 of the base 1 locking bolts 44 and clamping bars 43 of the locking mechanism. The electric drive 15 of the track 12 is switched on, the necessary rolling speed of the tested tire 9 is set using a frequency converter, and the total tangential force is determined using a force sensor. By dividing the latter by the vertical force, the rolling resistance coefficient is determined. This test is carried out at different rolling speeds of the tested tire 9 and, based on the measurement results, a graph is plotted in the coordinates "rolling resistance coefficient - speed".

To determine the coefficient of rolling resistance of the tire with force excitation of oscillations and the absence of kinematic perturbation, a small load is eccentrically fixed on the rim of the tire under test 9 to set the required unbalance value. Further tests are carried out in the same way as above.

To determine the rolling resistance coefficient of a tire during kinematic excitation of oscillations, the test tire 9 is pressed against the track 12 by the sprung mass. The electric drive 15 of the track 12 is turned on and the tests are carried out in the same way as above.

To determine the side slip characteristics of the tire 9, the rotary frame 7, the axle 8 of which is fixed on the base 1, is rotated by means of the screw mechanism 10 at a predetermined angle determined by the rotation angle sensor. To do this, the screw is rotated, along which the nut 11 moves, pivotally connected to the swivel frame 7. The electric drive 15 of the track 12 is turned on, the upper branch of which, when the tire 9 lateral slips, is kept from moving in the lateral direction by means of two side rollers 26, the axes of which are parallel to the vertical the loading axis of the tested tire 9. Due to the fact that the side rollers 26 are mounted on the vertical guide 18, free vertical movement of the upper branch of the caterpillar belt 12 is ensured with the side slip of the rotating tire 9 and the transfer of lateral force to the rotary frame 7.

Further tests are carried out in the same way as above. In this case, the lateral force of the tested tire 9 is measured by a force sensor mounted on a movable frame 4. According to the measurement results, a graph is plotted in the coordinates “lateral force - angle of rotation” at various rolling speeds.

Thus, the claimed technical result is achieved, which consists in the possibility of carrying out bench tests of a single-support suspension unit together with a rolling wheel without and with tire side slip on a hard surface with a different profile of unevenness, including the random nature of their distribution, characteristic of real roads, in facilitating installation and testing, including large diameter wheels, as well as facilitating the installation and fixing of the swivel frame at a given angle.

Claims (1)

Stand for testing pneumatic tires and elastic elements of vehicle suspensions, containing a base on which a traverse is installed by means of a frame movable in the vertical direction, connected to the loads, a tilting hydraulic cylinder installed between the traverse and the base, and a mechanism for loading the tested elements, including a caterpillar mover and a pusher connected with the pusher drive, installed in the vertical guide and having support elements on the upper part, made in the form of rigid rollers arranged in a checkerboard pattern, forming a roller table, onto which, through the caterpillar belt, covering the driven drum and the drive drum, connected to the caterpillar drive, the tested elements connected with the traverse are supported, characterized in that the weights are fixed on top of the traverse, and the loading mechanism is mounted on a rotary frame, between the end of which and the base a screw mechanism is pivotally mounted, the axis of which is perpendicular to the radius, check given from the axis of the swivel frame to the hinge of the screw mechanism installed on it, while the axis of the swivel frame is fixed on the lower part of the stand base and coincides with the vertical axis of the tire loading, the pusher drive is made in the form of a hydraulic pulsator having a rod with a piston placed in a housing that is installed vertically on the swivel frame of the stand on the side of the caterpillar mover and through a servo-hydraulic distributor communicates with the pump and the tank of the hydraulic station, the pusher is made in the form of a vertical guide, which is installed on the swivel frame between the caterpillar mover and the hydraulic pulsator with the possibility of vertical movement, two guide rollers are installed inside the vertical guide, the axes of which are connected to the rotary frame, in the middle part of the vertical guide there is a side support, on top of which the roller table is fixed, at the upper end of the vertical guide there is an upper support resting on the end of the hydropulsator rod, and the upper branch g of the caterpillar belt is fixed from displacement in the lateral direction with the help of two side rollers mounted horizontally on a vertical guide.

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