This invention relates to the field of anti slip devices, specifically it is an anti slip device for automobile wheels with wheel disk arranged at the inner side plane of the wheel.
We are familiar with anti slip devices for automobile wheels, which are installed on the automobile wheel. Anti slip elements are predominantly made in the form of readjustable arms, which are fitted with surfaces of engagement. In case of need, these arms are put to working position, in which the surfaces of engagement bear against the peripheral surface of a tire. Arms are put to the work position either manually or by means of systems, which are mechanical, pneumatic, or electric. Mostly pneumatic control systems are used in commercial vehicles.
Well-known anti slip devices for wheels of commercial vehicles are with regard to wheel construction of a commercial vehicle complex, include a large number of moving parts, and are bulky. In addition, individual types of known solutions have different qualities, they differ in reliability, price, and actual usability.
The purpose of the invention is to create an anti slip device for automobile wheels with wheel discs arranged at the inner side of the wheel, whereas such anti slip device would not protrude outside neither in the home, nor working position over the outer side plain of the wheel, would enable remote control, and would be simple and reliable both in terms of functionality and controllability.
The above stated purpose is achieved by the anti slip device for automobile wheels with wheel discs arranged at the inner side plane of the wheel, loading-bearing part of which is attachable from the outside on the wheel disc as per the invention, substance of which is grounded in the fact that there is an extensible body slidingly, in the direction parallel to the wheel axis, placed on the load-bearing part, and inside the extensible body there are arms fulcrumed around the axes parallel to the wheel axis, which are, at their ends, fitted with surfaces of engagement, which, in the working position, bear against the peripheral tire surface.
The anti slip device is placed on the load-bearing part in a guidance, which is favorably made up by at least two pipes attached to the load-bearing part, while there is one outer pipe slidingly placed on each of these pipes, and this outer pipe is attached to the extensible body.
In pipes attached to the load-bearing part, tensile springs are arranged and attached by one end to the load-bearing part, and by the other end to the extensible body.
The anti slip device is fitted with drive for movement of the extensible and for turning of arms with surfaces of engagement. The drive is pneumatic, and it comprises source of compressed air, bellows for shifting of the extensible body, pneumatic motors for turning of arms with surfaces of engagement, and control components. Control components are fitted with remote electronically operated regulation elements.
Arm are fulcrumed on bearers, which are radially-slidingly and sprung placed in the extensible body. This way, contact of the surfaces of engagement with the peripheral surface of the tire is achieved in the course of driving.
One possible way of configuration of the anti slip device as per the invention is depicted on the attached drawings, where
The anti slip device consists of a load-bearing part 4, which is assembled to the wheel disc 3 with tire 1 from the outer side by a regular method, e.g. by means of screws and nuts.
Disc 3 is placed closer to the inner side plane of the wheel, where it is connected to the rim 2. This way, the anti slip device practically does not protrude above the outer side plane of the wheel neither after it is mounted to the wheel, nor in the work position. This type of wheels can be found for example on trucks.
Guidance is fastened to the load-bearing part 4, on which the extensible body 8 is placed slidingly in the direction parallel to the wheel axis. The guidance is in the above described example of configuration comprised by two pipes 6 with axes parallel to the wheel axis.
Pipes 6 are fastened to the load-bearing part 4, and the outer pipes 5, which are attached to the extensible body 8, are slidingly placed on them.
Inside the pipes 6, tensile springs 7 are arranged between the load-bearing part 4 and the extensible body 8, and these springs draw the extensible body 8 to the load-bearing part 4.
In the extensible body 8, arms 9 are fulcrumed around axes parallel to the wheel axis, and the arms 9 are fitted with surfaces of engagement 10, which are basically perpendicular to the arms 9, on outer ends.
The device is fitted with drive, which is in this case pneumatic, for travel of the extensible body 8 and for turning of the arms 9. The drive includes source 13 of compressed air ordered on the load-bearing part 4. The source 13 of the compressed air is connected via control components 14 to the bellows 15 for extruding the extensible body 8 and to the pneumatic motors 16 for turning of arms 9 with surfaces of engagement 10. The control components 14 comprise electronically controlled regulation elements for remote control from the cab. Interconnection between the parts of the pneumatic circuit may be carried out by not depicted pressure hoses.
In an installed position, the device is attached to the wheel disc 3 by means of the load-bearing part 4, and the tensile springs 7 draw the extensible body 8 to the load-bearing part 4. The arms 9 with surfaces of engagement 10 are slightly turned to the home position, in which they do not protrude radially above the circumference of the extensible body 8.
When the anti-slip device needs to be set to the working position, i.e. to the state when the surfaces of engagement 10 bear against the tire peripheral surface 1, interconnection of the source of the compressed air 13 with the inner area of the bellows 15 takes place by means of an electric signal sent remotely from the vehicle cab to the respective control component 14.
By expanding the bellows 15, the extensible body 8 is extruded against the force of the tensile springs 7 outside from the wheel. By another electric signal received by the respective control component 14, interconnection between the source 13 of compressed air and pneumatic motors 16, which slightly turn the arms 9 with surfaces of engagement 10, is established. In this state, the compressed air is released from the bellows 15, and the tensile springs 7 draw the extensible body 8 to the load-bearing part 4. Within this movement, the surfaces of engagement 10 reach the position closely above the tire peripheral surface 1. The anti slip device is in the working position now. Fit of the surfaces of engagement 10 of arms 9 on the tire peripheral surface 1 during driving is enabled by the fact that the arms 9 are fulcrumed on the bearers 11, which are sprung and slidingly in the radial direction placed in the extensible body 8. Springing is ensured by springs 12.
After the anti slip device returns to the home position, firstly the extensible body 8 slides outward from the wheel by the way described above, and the surfaces of engagement 10 this way gets outside of contact with the tire peripheral surface 1. Based on the electric signal, the respective control component 14 in this position moves to a position, when the compressed air is released from the pneumatic motors 16 and is brought to their other areas, by which the arms 9 turn to the home position over the transmission. In this state, after releasing the compressed air from the bellows 15, the extensible body 8 slides back to the home position due to the effect of tensile springs 7.
There are four arms 9 in this configuration example. Their number may differ in accordance with spatial dimension.
Number | Date | Country | Kind |
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2015-192 | Mar 2015 | CZ | national |