초록 ▼

A method is provided for measuring the milling depth of a road milling machine, the machine being operative to mill a ground surface with a milling roller lowered to a milling depth to create a milling track, the machine including at least one side plate located to at least one side of the milling r

A method is provided for measuring the milling depth of a road milling machine, the machine being operative to mill a ground surface with a milling roller lowered to a milling depth to create a milling track, the machine including at least one side plate located to at least one side of the milling roller to engage an untreated ground surface, and the machine including a stripping plate operative to be lowered onto the milling track generated by the milling roller. The method includes measuring the milling depth of the milling track, the measuring including detecting a measurement value of a ground engaging sensor engaging the milling track.

대표청구항 ▼

1. A self-propelled road milling machine, comprising: a machine frame;at least two front ground engaging supports, and at least one rear ground engaging support;front and rear lifting columns supporting the frame from the ground engaging supports, each of the front and rear lifting columns comprisin

1. A self-propelled road milling machine, comprising: a machine frame;at least two front ground engaging supports, and at least one rear ground engaging support;front and rear lifting columns supporting the frame from the ground engaging supports, each of the front and rear lifting columns comprising a position sensor configured to detect a lifted condition for a respective lifting column;a milling roller supported from the frame for treatment of a ground surface;a height adjustable stripping plate arranged behind the milling roller and operable to be lowered, during operation, into a milling track generated by the milling roller; andfirst and second height adjustable side plates arranged on opposite sides of the milling roller, at least one of the side plates comprising a plurality of position sensors spaced apart in a traveling direction of the milling machine, wherein each side plate position sensor generates position signals representing changes in position for a respective side plate. 2. The self-propelled road milling machine of claim 1, wherein the plurality of side plate position sensors are integrated with hydraulic piston/cylinder units for lifting or lowering the respective side plates. 3. The self-propelled road milling machine of claim 2, wherein each of the first and second side plates comprise a plurality of position sensors spaced apart in a traveling direction of the milling machine. 4. The self-propelled road milling machine of claim 3, wherein the position signals from the position sensors for one or more of the side plates are representative of one or more of a transverse inclination or a longitudinal inclination of the machine frame. 5. The self-propelled road milling machine of claim 2, wherein each of the front and rear lifting columns comprise the position sensor of the respective lifting column integrated with a hydraulic piston/cylinder unit of the respective lifting column for lifting or lowering the respective lifting column. 6. The self-propelled road milling machine of claim 1, wherein each of the front and rear lifting columns comprise the position sensor of the respective lifting column integrated with a hydraulic piston/cylinder unit of the respective lifting column for lifting or lowering the respective lifting column. 7. The self-propelled road milling machine of claim 6, wherein the stripping plate comprises one or more position sensors configured to generate position signals representing changes in position for the stripping plate. 8. A method of controlling a milling machine, the milling machine having a machine frame, a milling roller supported from the machine frame, front and rear ground engaging supports, front and rear lifting columns supporting the machine frame from the ground engaging supports, and first and second side plates on opposing sides of the milling roller, the side plates being height-adjustable with respect to the machine frame, the method comprising: receiving position sensing signals from first and second position sensors spaced apart in a traveling direction on one or more of the side plates; andmeasuring a displacement of the one or more of the side plates with respect to the machine frame, based on the received position sensing signals. 9. The method of claim 8, further comprising calculating a current milling depth of the milling roller based at least in part on received position sensing signals from the position sensors on the one or more of the side plates. 10. The method of claim 9, further comprising automatically controlling a vertical adjustment of the milling roller based at least in part on the calculated current milling depth with respect to a set milling depth value. 11. The method of claim 10, further comprising automatically controlling the vertical adjustment of the milling roller via vertical adjustment of at least the front lifting columns. 12. The method of claim 8, further comprising automatically controlling both of a milling depth and an inclination of the machine frame by controlling a lifted condition of at least one of the lifting columns. 13. The method of claim 8, wherein each of the side plates comprise first and second position sensors spaced apart in the traveling direction. 14. The method of claim 13, wherein the method further comprises calculating one or more of a transverse inclination of the machine frame and a longitudinal inclination of the machine frame based on the received position sensing signals from the position sensors for each of the side plates. 15. The method of claim 13, further comprising measuring a displacement of the detected position for the side plates with respect to each other. 16. A method of measuring a milling depth of a milling machine, the milling machine having a machine frame, a milling roller supported from the machine frame, front and rear ground engaging supports, front and rear lifting columns supporting the machine frame from the ground engaging supports, and first and second side plates on opposing sides of the milling roller, the side plates being height-adjustable with respect to the machine frame and each comprising first and second piston-cylinder units spaced apart in a traveling direction, the method comprising: detecting a lifted condition of each of the lifting columns with a position sensor included as part of each respective lifting column;detecting changes in position for one or more of the side plates with at least first and second position sensors integrated as part of the first and second piston-cylinder units, respectively, for the one or more of the side plates;calculating a current milling depth of the milling roller based at least in part on the detected changes in position for the one or more side plates; andautomatically controlling a vertical adjustment of the milling roller based on the calculated current milling depth with respect to a set milling depth value. 17. The method of claim 16, wherein the automatic controlling of the vertical adjustment of the milling roller is via vertical adjustment of at least the front lifting columns. 18. The method of claim 17, further comprising calculating one or more of a transverse inclination of the machine frame and a longitudinal inclination of the machine frame based on position signals from the position sensors for each of the side plates. 19. The method of claim 17, further comprising measuring a displacement of a detected position for the side plates with respect to each other. 20. The method of claim 16, further comprising: detecting one or more of a longitudinal inclination of the machine frame and a transverse inclination of the machine frame from information including at least received position sensing signals from the at least first and second position sensors of the one or more of the side plates; andautomatically controlling the lifted condition of at least one of the lifting columns so as to automatically establish a predetermined inclined position of the machine frame relative to a ground or traffic surface.