RU2819238C1 - Wheel disc straightening bench - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to machine building, particularly, to wheel disks repair equipment, which is used in car service workshops. Wheel disc straightening bench comprises bed with spindle assembly with horizontal axis of rotation and faceplate for wheel disc fixation. There are straighteners and a lifting-and-rotary table driven by a power cylinder. Table is made with load-carrying surface for support of wheel disc rim and is connected to power cylinder by means of mechanism, the latter comprises guide bush rigidly fixed on the bed and rod arranged therein to displace and rotate axially. Lower end of the rod interacts with the rod of the power cylinder, and a table is rigidly fixed on the upper end.

EFFECT: as a result, facilitating the process of lifting the wheel disc onto the bench, simplifying the alignment of the axes of rotation and mounting holes of the disc and the faceplate and the possibility of straightening discs of different sizes.

7 cl, 6 dwg, 2 ex

Description

Field of technology to which the invention relates

The invention relates to the field of mechanical engineering, more specifically to equipment for repairing wheel rims, used in car service workshops.

State of the art

The “wheel rim” is usually understood as the critical part of the wheel, consisting of the rim - the rotation surface on which the tire is mounted, and the disk-shaped (end) part - the hub, which serves to secure the wheel to the vehicle axle. Often the “rim” is simply referred to as the “rim” of the wheel. In the application materials, both terms are used: “wheel” and “disk” as equivalent.

All known machines for straightening wheel rims can be divided into two large groups. The first group includes devices with a vertical orientation of the spindle rotation axis, on which the repaired wheel disk is fixed, for example, see patents: US 6367303, (publ.) 04/09/2002; ES 2216670, 10/16/2004; RU 124599U1, 02/10/2013; US 20200338612, 10/29/2020.

In such designs, with a vertical orientation of the spindle axis, installation and fastening of the wheel rim, as a rule, does not present any big problems. The operator simply places the disk on the horizontal surface of the bed and slides it along it to subsequently align the axes of the disk and the spindle faceplate and connect them.

The second group includes machines for straightening wheel rims with a horizontal spindle rotation axis, for example, see patents: DE 102005011313, RU86508 U1, RU2567771, RU 126638 U1, US 20060260121, US 10189066, US 20040035164, RU 22 36924, MD1524, RU 122921 U1 and others.

In these devices, the wheel disk has a cantilever fastening, and therefore its installation, which involves aligning the axes and mounting holes of the spindle faceplate and the wheel disk and their subsequent connection, is quite a big problem. So a modern alloy car wheel weighs about 25 kilograms. In order to install it on the machine, the operator has to lift the disk to the level of the spindle and, holding it suspended with one hand, align the axes of the disk holes and the faceplate, and then install the mounting bolts in the aligned holes and fix them. Therefore, to perform high-quality installation of the disk, as a rule, the labor of two or even three workers is used.

As the closest analogue, the design of a machine for straightening automobile wheel rims was adopted, see invention patent RU 2567771, IPC: B21D 3/16, B21D 1/00, publ. November 10, 2015

Similar features of the known and inventive designs are the presence of a frame, a spindle assembly mounted on it with a horizontally oriented axis of rotation and a faceplate for securing the wheel disk, as well as mechanisms and tools for preliminary and final straightening (hereinafter referred to as straightening means).

The disadvantages of the closest analogue include the complexity and high labor intensity of installation, alignment and fastening of the wheel rim on the spindle axis, and the lack of means to facilitate these operations.

The proposed technical solution is aimed at solving the above-mentioned problem of the complexity of installing a wheel on a machine.

The technical result of the proposed invention is to increase productivity and reduce the labor intensity of work associated with installing a wheel rim on a stand (loading it), due to the mechanization of lifting and simplifying the alignment of the rotation axes and mounting holes of the wheel rim and faceplate. At the same time, reliability and the ability to work with wheel rims of any size are ensured.

The proposed solution can be used both for newly manufactured stands and for the modernization of existing stands.

Disclosure of the invention The solution to the above-mentioned problem and the achievement of technical results is ensured due to the fact that a stand for straightening wheel rims, containing a frame, a spindle assembly mounted on it with a horizontal axis of rotation and with a faceplate for securing the wheel rim, and means for straightening, according to the claimed invention, equipped with a lift-and-turn table driven by a power cylinder, wherein the table is made with a load-bearing surface adapted to support the rim of the wheel disk, and is connected to the power cylinder through a mechanism including a guide bushing rigidly fixed to the frame and installed in it with the possibility of linear movement and axial rotation rod, the lower end of which interacts with the rod of the power cylinder, and the table is rigidly fixed at the upper end.

Equipping the stand with a lifting and rotary table of this design, structurally coupled with the stand frame, makes it possible to facilitate the process of lifting and installing the wheel rim on the stand and significantly simplify the alignment of the rotation axes and mounting holes of the wheel rim and faceplate, thereby increasing the productivity of repair work. At the same time, the design of the lift-and-turn table allows you to work with wheel rims of different sizes and ensures high reliability of operation, regardless of the weight and dimensions of the rims being moved.

The load-bearing surface of the table is preferably formed by a pair of parallel rolls, their ends installed in the end walls or in the table frame. In this case, the rolls can be fixedly fixed, or they can be installed with the possibility of free axial rotation, which is more preferable. This design of the load-carrying surface is simple, versatile and provides stable support for the wheel disk mounted on the rim (surface of rotation), that is, in a vertical position in which the disk axis is oriented horizontally. Versatility implies the ability to work with wheel rims of any diameter and height (width).

The rod on which the table is rigidly fixed, essentially forming a table leg, can be installed in the guide sleeve by means of two bearings. In this case, at the lower end of the rod, opposite to the fastening of the table, a recess is formed that interacts with a spherical protrusion made at the end of the power cylinder rod.

This connection eliminates a rigid connection and allows the rod to perform linear movement inside the guide sleeve and at the same time rotate freely about its axis. The result is vertical movement (raising and lowering) of the table and its rotation. The guide sleeve, rigidly fixed to the stand frame, together with the rod form a kind of hinge, the design of which, unlike other possible hinges, ensures reliable operation of the loading mechanism, even under conditions of increased loads, for example, when loading heavy and oversized disks.

A pneumatic cylinder or a hydraulic cylinder can be used as a power cylinder.

In order to further develop the mechanization of production, the loading device can be equipped with an automatic control unit for the power cylinder. Sensors are connected to the block: a table lift tracking sensor and a disk profile tracking sensor, installed on the bed and table, respectively.

Brief description of drawings

The essence of the proposed technical solution and the possibility of its industrial applicability are illustrated by the following examples of implementation and drawings, which depict:

figure 1 - general view of the stand, axonometric projection;

figure 2 - fragment I from figure 1 (section);

figure 3 - fragment II from figure 1 (section);

Fig.4 is a view of the stand with a lift-and-turn table in the lower working position, deployed to receive the wheel;

Fig. 5 (a-c) illustrates the operation of the loading device;

Figure 6 is an example of the implementation of a stand with an automatic loading control unit.

Carrying out the invention

An example of a stand for straightening wheel rims, made in accordance with the present invention, is presented in Fig.1. The stand contains a frame 1 on which a spindle assembly 2 is installed with a horizontal axis of rotation and a faceplate 3 with holes for securing the wheel rim, means for straightening, which may include various mechanisms and tools for mechanical impact on deformed areas of the rim of the wheel rim, means for controlling deviations and etc. (positions are not marked, since the stand’s instrumental equipment can be anything). The stand is equipped with a loading device made in the form of a lifting and turning table 4 driven by a power cylinder 5, for example a pneumatic cylinder mounted on the frame 1. A hydraulic cylinder can also be used as a power cylinder 5.

The table 4, the load-bearing surface of which is intended to accommodate the wheel disk, is rigidly fixed to the upper end of the movable rod 6, installed with the possibility of linear movement and free axial rotation in the guide sleeve 7, rigidly fixed to the frame 1 by means of a bracket 8 (see Fig. 2) . Rod 6 is installed in sleeve 7 by means of bearings 9 and 10.

The lower end of the rod 6 interacts with the rod 11 of the power cylinder 5. In this case, to allow free axial rotation and linear movement of the rod 6, their connection to each other is made hinged, for which a spherical protrusion 12 is made at the end of the rod 11, interacting with a recess 13 of the corresponding shape formed at the lower end of the rod 6 (see Fig.3). Thus, the rod 11 can push the rod 6 up or pull it down, depending on the specified direction of movement, and does not interfere with the axial rotation of the rod 6 inside the sleeve 7.

The load-bearing surface of the table 4 is preferably formed by a pair of parallel rolls 14, fixed at their ends in the table frame 15 (see Fig. 4). This design makes it possible to install wheel rims with support on the rim and the disk axis being oriented horizontally, while the rim sizes can be any. This version of the load-carrying surface of the table 4 is the simplest, and therefore preferable, but does not exclude other possibilities, for example, making the table surface with protrusions or, on the contrary, with recesses that form cradle for the wheel rim and ensure that the wheel is held in a vertical position.

Lever 16 for controlling the pneumatic distributor of power cylinder 5 can be placed on the stand frame 1, in the operator’s free access area.

To load the wheel rim onto the stand, the operator moves the table 4 to the lower position and installs the wheel 17 to be straightened with the rim support on the rollers 14 of the table 4 (see Fig. 5a).

By switching the lever 16 of the pneumatic distributor, the operator starts the power cylinder 5, while its rod 11 extends upward and pushes the rod 6, ensuring vertical movement of the table 4 with the wheel 17 mounted on it, which rises to the level of the spindle 2 (see Fig. 5b). Next, the operator turns the table 4 with the wheel 17 and brings it into the working area of the spindle 2 (see Fig. 5c).

By additionally turning on and off the power drive, the operator achieves the alignment of the wheel disk 17 and the faceplate 3, after which, by rotating the wheel disk 17 resting on the rollers 14, he achieves alignment of the mounting holes of the disk and the faceplate 3. The cylindrical surface of the rollers 14, which has linear contact with the surface of the rim disk 17, provides ease of rotation and further simplifies the process of aligning the holes, into which the operator then installs mounting bolts and fixes disk 17 relative to spindle 2.

To improve the smooth rotation of the wheel on the table 4, the rolls 14 can be installed in the supporting frame 15 with the possibility of free axial rotation.

During all operations associated with installing the wheel rim and securing it to the spindle axis, the table 4 holds the wheel 17, freeing the operator’s hands, which allows the latter to independently perform all operations with minimal physical exertion.

Upon completion of the installation and securing of the wheel 17, the operator lowers the table 4, turns it away and lowers it to the lower position, after which he can begin performing repair work.

In another example of the invention, the loading device may be equipped with an automatic control unit 18 and sensors 19 and 20 connected to it (see Fig. 6). The table lift tracking sensor 19 is fixed on the frame 1 near the power cylinder 5 and monitors the lift, for example, by moving the power cylinder rod. The disk profile tracking sensor 20 is installed on the table 4 and provides non-contact measurement of the wheel disk profile geometry for the purpose of subsequent calculation of its diameter.

In this case, the operator controls the wheel loading using the control panel of block 18.

The software of block 18 ensures that it performs the following functions: polling sensors, receiving readings from them, calculating the disk diameter and lifting height based on sensor readings, generating and transmitting control commands to the lifting and turning actuators.

For an emergency stop, for example in case of incorrect actions or danger, the operator can press the “stop” button on the control panel of unit 18.

Claims (7)

1. A stand for straightening wheel rims, containing a bed, a spindle assembly mounted on it with a horizontal axis of rotation, and a faceplate for securing the wheel rim, and means for straightening, characterized in that it is equipped with a loading device in the form of a lift-and-turn table driven by a power cylinder, wherein said lifting and turning table is made with a load-carrying surface for supporting the rim of the wheel disk and is connected to the power cylinder through a mechanism including a guide bushing rigidly fixed to the frame and a rod installed in it with the possibility of linear movement and axial rotation, the lower end of which interacts with a power cylinder rod, and a lift-and-turn table is rigidly fixed at the upper end. 2. A stand for straightening wheel rims according to claim 1, characterized in that the load-bearing surface of the lift-and-turn table is formed by a pair of parallel rolls. 3. A stand for straightening wheel rims according to claim 2, characterized in that the rollers are installed with the possibility of free axial rotation. 4. A stand for straightening wheel rims according to claim 1, characterized in that the rod is installed in the guide sleeve by means of two bearings, while at the lower end of the rod a recess is formed to accommodate a spherical protrusion made at the end of the power cylinder rod. 5. A stand for straightening wheel rims according to claim 1, characterized in that the power cylinder is made in the form of a pneumatic cylinder. 6. A stand for straightening wheel rims according to claim 1, characterized in that the power cylinder is made in the form of a hydraulic cylinder. 7. A stand for straightening wheel rims according to claim 1, characterized in that the loading device is equipped with an automatic control unit for the power cylinder and sensors connected to it for tracking the lifting of the lift-and-turn table and tracking the profile of the disk, installed on the frame and the lift-and-turn table, respectively .