CLEANING MACHINE FOR A ROAD OR PAVEMENT OR GUTTER

Abstract

The invention is in the field of a cleaning machine for a road or pavement or gutter. These machines are used to remove objects, such as small items, such as leaves, and dirt from a road or the like, using a broom system for cleaning the road or the like, and typically a storage for removed objects and dirt.

Claims

1. A cleaning machine for cleaning at least one of a road, a pavement, and a gutter comprising a vehicle, the vehicle comprising at least one with respect to the vehicle vertically and horizontally movable broom system, a controller for moving said broom system, characterized in a pavement track system comprising a 3D camera providing 3D-images, pattern recognition software adapted to process the 3D-images, wherein the pattern recognition software identifies a side of the road, and wherein the pattern recognition software measures a distance from the vehicle to the side of the road, and wherein the controller is adapted to move the broom-system sideways with respect to the vehicle such that a distance between the broom system and side of the road is controlled.

2. The cleaning machine according to claim 1, wherein the controller is adapted to move the vehicle sideways such that a distance between the broom system and side of the road is controlled.

3. The cleaning machine according to claim 1, wherein the controller adapts the distance in view of broom wear.

4. The cleaning machine according to claim 1, further comprising a second broom system, and a third broom system.

5. The cleaning machine according to claim 1, wherein the software adapts for contrast and wherein the software adapts for shadow effects, and wherein the software is trained for recognizing the pavement.

6. The cleaning machine according to claim 1, adapted to be steered by one of an operator and a driver.

7. The cleaning machine according to claim 6, wherein the software is adapted to validate a position of the rising edge, and wherein the rising edge is validated on at least two consecutive 3D-images.

8. The cleaning machine according to claim 1, wherein the control is electronic, and wherein a CAN-bus is used for control.

9. The cleaning machine according to claim 1, wherein the controller is adapted to be manually over-ride.

10. The cleaning machine according to claim 1, wherein the controller is adapted to maintain the distance between the broom system and side of the road at a constant value within a predetermined limit.

11. The cleaning machine according to claim 1, wherein an orientation of the 3D-camera is adaptable, and adaptable to be in a height position providing images of the side of the road.

12. The cleaning machine according to claim 1, wherein brooms are adapted to sweep debris and dirt to a suction point, and wherein brooms are adapted to move with respect to the cleaning-machine in a horizontal direction and vertical direction, and wherein the cleaning machine comprises a suction system for up-taking debris and dirt from the suction point, connected to the suction opening a suction tube, at the other end of the suction tube a container for receiving dirt and debris, and a fan for providing suction, and wherein the cleaning machine comprises at least one ventilation opening, and an outlet, and further comprising a display (5).

13. A pavement track system computer program comprising instructions for operating the cleaning machine according to claim 1, the cleaning machine comprising a vehicle, the vehicle comprising, at least one with respect to the vehicle vertically and horizontally movable broom system, a controller for moving said broom system, characterized in a pavement track system comprising a 3D camera providing 3D-images, pattern recognition software adapted to process the 3D-images, wherein the pattern recognition software identifies a side of the road, and wherein the pattern recognition software measures a distance from the vehicle to the side of the road, and wherein the controller is adapted to move the broom-system sideways with respect to the vehicle such that a distance between the broom system and side of the road is controlled, the instructions causing the computer to carry out the following steps: loading 3D images, identifying the pavement; determining a distance between the broom system and pavement; and maintaining said distance within predetermined limits by moving said broom system by means of the controller sideways.

14. The pavement track system computer program according to claim 13, further comprising instructions for recognition of a curb, and neglecting the dirt and debris to be removed visible in the image, and compensating for broom-wear, and adapting for difficult image situations.

Description

SUMMARY OF THE FIGURES

[0031] FIG. 1 show an exemplary embodiment of the present machine.

[0032] FIGS. 2a-b show a third broom system.

[0033] FIGS. 3a-d show operational aspects of the present cleaning machine.

DETAILED DESCRIPTION OF THE FIGURES

[0034] In the figures: [0035] 1 Cleaning machine [0036] 2a first right hand broom [0037] 2b optional second left hand broom [0038] 2c optional third broom [0039] 3 suction mouth [0040] 4 suction tube [0041] 5 container [0042] 6 filter [0043] 7 outlet [0044] 8 suction fan [0045] 9 side shift [0046] 10 3D camera

[0047] FIG. 1 show an exemplary embodiment of the present machine.

[0048] FIGS. 2a-b show a third broom system, indicated with a circle.

[0049] The figures are further detailed in the description and examples below.

[0050] The present cleaning machine takes over a significant part of the manual control of several functions of the sweeper, during sweeping operation. This reliefs the driver of a difficult, tiring task.

[0051] In an example the present modification is designed and integrated in the sweeper, leaving all existing/present functions of e.g. the Ravo type 5 machine otherwise unchanged. Controlling these functions can still be performed manually, but also an automatic mode is available.

[0052] The present sweeper, or streetsweeper, can best be described as a large domestic vacuum cleaner. All typical components of a vacuum cleaner are typically there: an engine driving a (centrifugal) fan that creates vacuum, thus creating air movement in a suction nozzle that picks up dirt/debris. Through a (suction)tube the airflow transports the dirt/debris into the dirt/debris container (See FIG. 1). To be able to work on a road surface, the machine typically meets a number of road-specific requirements: (i) it provides sufficient cleaning width: as the width of the suction nozzle is typically only 30 cm, this is too narrow to deliver efficient cleaning. To increase the cleaned surface width, brooms are added, that move dirt/debris from both sides (L+R) to the center of the machine, where the suction nozzle is located (See FIG. 1); (ii) as a standard two brooms (L+R) are typically provided, which result in a total sweeping width of approximately 2 meters; (iii) an optional third 3rd broom is provided for an increased width with approximately 70-90 cm extra. It also provides an increased flexibility to reach into corners and other hard to reach areas. (iv) As the brooms typically use a certain force on the ground, that is kept more or less constant, independent from shape of the road-surface, speed-bumps and broom wear (a worn broom weighs less than a new one) This load-regulating system is based on a spring-loaded mechanism; (v) The brooms are best kept in a rather precise position relative to the side of the road and/or curb to function properly; when they are too far from the curb dirt/debris may be missed, when they are too close to the curb hairs/wires from the broom may be pushed flat to the surface, and the broom may not work properly. This relative position is typically determined by two factors: The position of the entire machine; this may be controlled by the driver/operator, steering the machine towards- or away from the curb (normal/standard steering function of the vehicle); The position of the 2 standard brooms, relative to the machine; to provide easy, fast position changing of the brooms, vertically and horizontally movable broom system onto which these brooms are preferably mounted on a sub-frame (“broom carriage”) that can move sideways (perpendicular to the driving direction of the vehicle); this system is called “side-shift” and enables the brooms to be positioned closer or further away to the curb. This side-shift, and the relative position of the broom with respect to the machine is controlled with a sensor, the sensor measuring the relative position and capable of adapting the relative position. This movement is controlled by hand, with a controller, by the operator. Electrical signals from the joystick (part of the controller) are connected to the computer controlling the machine (PLC); this PLC in its turn sends electrical signals to the hydraulic valves (operator, joystick). The physical movement of the entire broom carriage is typically powered by a hydraulic cylinder (See FIG. 1); (vi) The principle of operating the 3rd broom is identical to that of the standard brooms, but it is mounted on a separate frame and thus able to function independent from the standard brooms (See FIGS. 2a and 2b).

[0053] The above describes functionality of the present sweeper, relating to proven Ravo 5 technology.

[0054] The integration of the present invention into the Ravo 5 machine may be done mainly electrically, such as through software, or by adding an electrical function to an existing (hydraulic) component. An example of the latter is an additional, electrically controlled steering function. This allows the electronic machine control to influence the mechanical/hydraulic steering unit, thus creating automated steering.

[0055] Addition of the 3D camera to the machine, creating a 3D image to determine the distance between the machine and the curb, by image recognition, and bring this information with respect to the distance to the control-computer of the machine, allows the introduction of an automatic sweep function, relieving the driver of a tiring task, creating better efficiency, and more safety.