The invention relates to a method of, and system for, obtaining an indication of the soil strength of soil over which a compactor roller travels. The method includes determining the depth to which a drum of the compactor roller penetrates into and depresses the soil when the compactor roller travels
The invention relates to a method of, and system for, obtaining an indication of the soil strength of soil over which a compactor roller travels. The method includes determining the depth to which a drum of the compactor roller penetrates into and depresses the soil when the compactor roller travels over a soil surface. The system includes a compactor roller, a measuring arrangement and a processor which is operatively connected to the measuring arrangement and which is configured to process data received from the measuring arrangement. The measuring arrangement includes an inertial measurement unit which is operatively connected to the compactor roller, wherein the arrangement is configured to obtain an indication of the soil strength of soil over which the compactor roller travels during operation, by determining the depth to which the drum penetrates into and depresses the soil over which it travels.
대표청구항▼
1. A method of obtaining an indication of the soil strength of soil over which an impact compactor travels, the method including: determining, when the impact compactor travels over a soil surface, a stroke depth to which a non-round impact drum of the impact compactor penetrates into and depresses
1. A method of obtaining an indication of the soil strength of soil over which an impact compactor travels, the method including: determining, when the impact compactor travels over a soil surface, a stroke depth to which a non-round impact drum of the impact compactor penetrates into and depresses the soil during application of an impact blow by the impact drum to the soil surface, wherein a duration of the impact blow begins when an impact face of the impact drum strikes the soil surface and ends when the impact face lifts away from the soil surface. 2. The method of claim 1, wherein the step of determining the stroke depth to which the impact drum penetrates into and depresses the soil includes measuring, by using a measuring arrangement, the amount of relative displacement between: the impact drum of the impact compactor, or a mounting arrangement of the impact compactor which displaceably mounts the impact drum to a chassis structure of the impact compactor, anda reference/datum point. 3. The method of claim 2, wherein the reference/datum point is the chassis structure or part of the impact compactor which is unaffected by the displacement of the impact drum relative to the chassis structure. 4. The method of claim 3, wherein the step of determining the stroke depth to which the impact drum penetrates into and depresses the soil includes measuring, by using a distance measuring device, the distance between: an axle assembly of the impact compactor on which the impact drum is mounted, or a drag link via which the axle assembly is mounted to the chassis structure, wherein the axle assembly and the drag link form part of the mounting arrangement; andthe chassis structure. 5. The method of claim 1, wherein a mounting arrangement of the impact compactor on which the impact drum of the impact compactor is mounted and which displaceably mounts the impact drum to a chassis structure of the impact compactor, includes one or more hinged/pivotal connections via which the impact drum is connected to the chassis structure of the impact compactor, and wherein the method includes monitoring, by using an angular measurement device/arrangement, the relative angular displacement between two hingedly connected parts of one, or each, of the hinged/pivotal connections. 6. The method of claim 5, wherein the impact compactor includes the chassis structure, a drag link, at least one impact drum of non-round shape which is rotatably mounted to the drag link, and a drop link via which the drag link is connected to the chassis structure, wherein the drop link is pivotally/hingedly connected to both the chassis structure and the drag link at spaced apart positions, and wherein the drop link and the drag link form part of a drum mounting arrangement, wherein the method includes: measuring, by using an angular measurement device/arrangement, the relative angular displacement between the drag link and the drop link; and/or the drop link and the chassis structure, with the change in angular displacement being indicative of the amount of relative displacement between the impact drum and the chassis structure, which, in turn, is indicative of the stroke depth to which the impact drum of the impact compactor penetrates into and depresses the soil. 7. The method of claim 6, which includes, by using a processor, utilising the known lengths of the drop link and the drag link together with data obtained from the angular measurement device/arrangement, in order to obtain an indication of the amount of relative displacement between the impact drum and the chassis structure, which, in turn, is indicative of the stroke depth to which the impact drum of the impact compactor penetrates into and depresses the soil. 8. The method of claim 1, wherein the step of determining the stroke depth to which the impact drum penetrates into and depresses the soil includes: measuring the pressure in a cylinder of a pneumatic piston cylinder device which is operatively connected between a mounting arrangement of the impact compactor on which the impact drum of the impact compactor is mounted and which displaceably mounts the impact drum to a chassis structure of the impact compactor, and the chassis structure, andderiving, by using a processor, an indication of the amount of relative displacement between the impact drum and the chassis structure from the measured pressure, which, in turn, is indicative of the stroke depth to which the impact drum of the impact compactor penetrates into and depresses the soil. 9. The method of claim 1, wherein the step of determining the stroke depth to which the impact drum penetrates into and depresses the soil includes: measuring, by using an accelerometer, the amount of acceleration which the impact drum of the impact compactor is subjected to during an impact blow; andderiving, by using a processor, an indication of the amount of relative displacement between the impact drum and a chassis structure of the impact compactor to which the impact drum is displaceably mounted from the measured acceleration, which, in turn, is indicative of the stroke depth to which the impact drum of the impact compactor penetrates into and depresses the soil. 10. The method of claim 1, wherein the step of determining the stroke depth to which the impact drum of the impact compactor penetrates into and depresses the soil during an impact blow, when the impact compactor travels over the soil surface includes: obtaining data from an inertial measurement unit (“IMU”) which is mounted on the impact drum of the impact compactor or a mounting arrangement on which the impact drum is mounted and which displaceably mounts the impact drum to a chassis structure of the impact compactor, anddetermining, by using a processor, the stroke depth by utilising the data. 11. An impact compactor which includes: a chassis structure;at least one non-round impact drum which is rotatably mounted to the chassis structure via a drum mounting arrangement, wherein the drum mounting arrangement allows displacement of the at least one impact drum relative to the chassis structure such that the at least one impact drum is displaced upwardly and downwardly relative to the chassis structure as the impact compactor travels along a soil surface; anda measuring arrangement, which is operatively connected to the chassis structure and/or the drum mounting arrangement, and which obtains an indication of the soil strength of soil over which the impact compactor travels when the impact compactor travels over the soil surface by determining a stroke depth to which the at least one impact drum penetrates into and depresses the soil surface during application of an impact blow by the impact drum to the soil surface, wherein a duration of the impact blow begins when an impact face of the impact drum strikes the soil surface and ends when the impact face lifts away from the soil surface. 12. The impact compactor of claim 11, wherein the measuring arrangement includes an IMU which is mounted on the impact drum or the drum mounting arrangement. 13. The impact compactor of claim 11, wherein the measuring arrangement includes at least one distance measuring device which is: mounted on the drum mounting arrangement and directed towards the chassis structure or part of the impact compactor which is unaffected by the displacement of the at least one drum relative to the chassis structure; ormounted on the chassis structure or part of the impact compactor which is unaffected by the displacement of the at least one drum relative to the chassis structure and directed towards the drum or the drum mounting arrangement. 14. A soil compaction system which includes: an impact compactor;a measuring arrangement which includes an inertial measurement unit which is operatively connected to the impact compactor, wherein, when the impact compactor travels over the soil surface, the measuring arrangement obtains an indication of the soil strength of soil over which the impact compactor travels during operation by determining a stroke depth to which a non-round impact drum of the impact compactor penetrates into and depresses the soil during application of an impact blow by the impact drum to the soil surface, wherein a duration of the impact blow begins when an impact face of the impact drum strikes the soil surface and ends when the impact face lifts away from the soil surface; anda processor which is operatively connected to the measuring arrangement and processes data received from the measuring arrangement. 15. The system of claim 14, wherein the impact compactor comprises: a chassis structure;at least one impact drum which is rotatably mounted to the chassis structure via a drum mounting arrangement, wherein the drum mounting arrangement is configured to allow displacement of the at least one impact drum relative to the chassis structure such that the at least one impact drum can be displaced upwardly and downwardly relative to the chassis structure as the impact compactor travels along a ground surface; anda measuring arrangement, which is operatively connected to the chassis structure and/or the drum mounting arrangement, and which is configured to obtain an indication of the soil strength of soil over which the impact compactor travels when the impact compactor travels over a soil surface, by determining the stroke depth to which the at least one impact drum penetrates into and depresses the ground surface over which the impact compactor travels during operation. 16. The method of claim 10, wherein the step of determining the stroke depth to which a drum of the impact compactor penetrates into and depresses the soil during an impact blow includes determining a vertical component of acceleration data obtained from the IMU. 17. The method of claim 16, further comprising double integrating the vertical component of the acceleration data with respect to time. 18. The method of claim 17, wherein the step of determining a vertical component of acceleration data obtained from the IMU includes transforming acceleration data from the IMU from an IMU frame of reference to a gravity vector frame of reference by multiplying an acceleration vector by a direction cosine matrix. 19. The impact compactor of claim 12, further including a processor which is operatively connected to the measuring arrangement and which is configured to process data received from the measuring arrangement, wherein the processor is configured to determine the stroke depth to which the drum of the impact compactor penetrates into and depresses the soil during an impact blow by:determining a vertical component of acceleration data obtained from the IMU; anddouble integrating the vertical component of the acceleration data with respect to time. 20. The impact compactor of claim 19, wherein the processor is configured to transform acceleration data from the IMU from an IMU frame of reference to a gravity vector frame of reference by multiplying an acceleration vector by a direction cosine matrix.
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이 특허에 인용된 특허 (13)
Corcoran,Paul T., Compaction indication by effective rolling radius.
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