The present disclosure generally relates to automatic control processes in machines and, more particularly, relates to automatic control processes for use on paving machines to reduce transition marks in the paved mat.
Paving machines are used to apply, spread and compact a mat of material relatively evenly over a desired base. These machines are regularly used in the construction of roads, parking lots and other areas where a smooth durable surface is required for cars, trucks and other vehicles to travel. A paving machine generally includes a hopper for receiving paving material from a truck and a conveyor system for transferring the paving material rearwardly from the hopper for discharge onto a roadbed base. Screw augers may be used to spread the paving material transversely across the base in front of a screed assembly. The screed assembly smoothes and somewhat compacts the paving material and, ideally, leaves a mat of uniform depth and smoothness.
The screed assembly is drawn behind the paving machine by a pair of pivotally mounted tow arms. The screed assembly includes a main screed and one or more screed extensions disposed behind (or, in some embodiments, in front of) and adjacent to the main screed. The extension(s) are slidable transversely to the direction of travel of the paving machine and allow varying widths of paving material to be laid.
Road mat thickness is determined, in part, by the position of the tow arms and the angle of attack of the screed assembly relative to the base. To pave an even surface, the trailing edge of the main screed, and at least the inner end of the trailing edge of the screed extension should remain in the same plane. A change in the vertical height of the tow arms may cause the trailing edge of the main screed to be disposed at a different elevation than the trailing edge of the screed extension, at least temporarily. This difference in elevation can cause inconsistencies or discontinuities in the paved mat.
U.S. Pat. No. 6,352,386 (“Heims”) issued Mar. 5, 2002 describes a road finisher having a chassis and a floating laying beam that includes a basic beam and an extendable beam. The laying beam is attached to the chassis by tie bars. Each tie bar is pivotally articulated on its front end on the chassis. The point of articulation is adjustable in height with respect to the chassis.
Heims discloses height adjusting devices that keep the respective rear edges of the basic beam and of the extendable beam in the same plane. According to Heims, a pair of sensors is mounted on the tow arm. The sensors are offset from one another in the direction in which the mat is being laid. The sensor offset is the same as the offset distance between the basic beam and the extendable beam. In addition, the sensors are arranged at such a height above the reference plane, the underlying carriageway, that they measure the same vertical distance from the reference plane when the surfaces of the basic beam and of the extendable beam run parallel with respect to the reference plane. According to the disclosure, with any desired setting angle alpha, the difference in height between the sensors mounted on the tow arms corresponds to a height difference X between the extendable beam and the basic beam and is used to derive a height correction for the extendable beam. While such an arrangement may be beneficial, precise alignment and calibration is needed. Inaccurate readings may occur due to close proximity of the sensors to vibrating or rotating parts, inaccurate calibration during machine set up, and positional movement of the sensors or of the basic beam and extendable beams caused by normal wear and tear over time at paving work sites. A better design is needed.
In accordance with one aspect of the disclosure, a paving machine for paving a mat on a base is disclosed. The mat having a first surface section contained in a first plane and a second surface section contained in a second plane, the second surface section adjacent to the first surface section. The paving machine comprising a frame, a tow arm connected to the frame and pivotable about a pivot point, a screed assembly connected to the frame by the tow arm, a sensor mounted on the screed assembly, and a controller. The screed assembly includes a main screed plate and an extension plate. The main screed plate is configured to pave the first surface section of the mat. The extension plate includes an extension trailing edge having an inner end. The extension plate is configured to pave the second surface section of the mat. The sensor is configured to sense transition marks in the mat proximal to an intersection between the first and second surface sections and is further configured to transmit data indicative of the transition marks to the controller. The controller may be configured to, while the paving machine is paving, determine from the data received from the sensor when the inner end is disposed above or below the first plane, and move the inner end to the first plane.
In accordance with another aspect of the disclosure, a method of automatically reducing transition marks made by a screed assembly of a paving machine in a mat while paving the mat over a base. The mat having a first surface section contained in a first plane and a second surface section contained in a second plane. The second surface section is adjacent to the first surface section. The paving machine includes a frame, a tow arm connected to the frame and pivotable about a pivot point, the screed assembly connected to the frame by the tow arm, a sensor mounted on the screed assembly, and a controller. The screed assembly includes a main screed plate and an extension plate. The main screed plate is configured to pave the first surface section of the mat. The extension plate includes an extension trailing edge having an inner end. The extension plate is configured to pave the second surface section of the mat. The sensor is configured to sense transition marks in the mat proximal to an intersection between the first and second surface sections and to transmit data indicative of the transition marks to the controller. The method comprising, while paving, determining, by the controller based on data received from the sensor, when the inner end is disposed above or below the first plane, and moving, by the controller based on the determining, the inner end to the first plane.
In accordance with a further aspect of the disclosure, a paving machine for paving a mat on a base is disclosed. The mat having a first surface section contained in a first plane and a second surface section contained in a second plane, the second surface section adjacent to the first surface section. The paving machine may comprise a frame, a tow arm connected to the frame and pivotable about a pivot point, a screed assembly connected to the frame by the tow arm, a plurality of sensors mounted on the screed assembly, a frame inclinometer mounted on the frame and configured to measure a frame slope in relation to a horizontal plane at a first point in time and a second point in time, a screed inclinometer mounted on the screed assembly and configured to measure a screed slope of the main screed plate in relation to the horizontal plane at the first point in time and the second point in time, and a controller. The screed assembly includes a main screed plate and an extension plate. The main screed plate is configured to pave the first surface section of the mat. The extension plate includes an extension trailing edge having an initial inner end. The extension plate is configured to pave the second surface section of the mat. The plurality of sensors are configured to sense transition marks in the mat proximal to an intersection between the first and second surface sections and are further configured to transmit data indicative of the transition marks to the controller. The controller configured to, while the paving machine is paving, calculate a frame slope change and a screed slope change, determine whether the frame slope change is different than the screed slope change, when the first plane and the second plane are parallel and the frame slope change is different than the screed slope change, move the extension trailing edge to the first plane, and when the second plane is disposed at an angle to the first plane and the frame slope change is different than the screed slope change, move the initial inner end to the first plane.
The paving machine 100 may further include a hopper 122 adapted for storing a paving material, and a conveyor system including one or more conveyors 124 configured to move paving material from the hopper 122 to the screed assembly 118 at the rear 108 of the frame 102. The conveyors 124 may be arranged at the bottom of the hopper 122 and, if more than one is provided, may be positioned side-by-side and run parallel to one another back to the rear 108 of the frame 102. While an endless path conveyor 124 is shown, one or more feed augers or other material feed components may be used instead of or in addition to the conveyor 124.
One or more augers 126 may be arranged near the rear 108 of the frame 102 to receive the paving material supplied by the conveyor 124 and spread the material evenly beneath the screed assembly 118. Although only one auger 126 is shown in
The screed assembly 118 is connected to the frame 102 by a pair of tow arms 128 (only one of which is visible in
Changing the position of the tow arms 128 at pivot point P relative to the base 119 to be paved changes the thickness of the resulting paved mat 120 and also, temporarily, changes the angle of attack of the screed assembly 118 relative to the base 119 being paved. This change in angle of attack is due to the natural pivot movement of the tow arms 128 about the pivot point P when the pivot point P is raised or lowered. While such change to the angle of attack also effects the thickness of the paved mat 120, the change is typically temporary. Because the screed assembly 118 “floats” on the paving material, the screed assembly 118 eventually “floats” to the higher or lower elevation set by the new position of the tow arms 128 and returns to the original angle of attack set for the screed assembly 118.
As shown in
In addition to being movable relative to the main screed 132, each screed extension 134 may also be configured such that the height of the screed extension 134 (and its extension plate 144) can be adjusted relative to the base 119 during paving. As shown in
The extension plate 144 includes an extension trailing edge 146. The extension trailing edge 146 is the lower edge of the extension plate 144 that is in contact with the paved mat 120 (see
As best illustrated in
In some embodiments, the first plane 156 and the second plane 158 may be the same plane.
In other embodiments, the first and second surface sections 152, 154 of the mat 120, and their respective first and second planes 156, 158 may be oriented at an angle θ to each other (as measured from the first surface section 152 to the second surface section 154). For example, in
During paving, transition marks 162 (see
Transition marks 162 may happen in a number of ways. For example, if the main screed trailing edge 139 (
When the height of the tow arms 128 at pivot point P is adjusted up to increase the thickness of the mat 120, the screed assembly 118 will initially pivot somewhat about pivot point P thereby temporarily increasing the angle of attack of both the main screed plate 136 and the extension plate 144. The plate that is further away from the pivot point P will dig downward to a greater depth relative to the other plate. For example, in
If the height of the tow arms 128 (
A transition ridge 164 can also happen if the screed extension 134 is disposed at an angle to the main screed 132.
When the tow arms 128 (
In some embodiments, the extension plate 144 may be oriented at an angle to the main screed plate 136 but the extension plate 144 may not be in a fully extended position.
The paving machine 100 may further include one or more sensors 172 (see
The paving machine 100 may also include a controller 174. The controller 174 may include a processor 176 (
The term “computer readable medium” as used herein refers to any non-transitory medium or combination of media that participates in providing instructions to the processor 176 for execution. Such a medium may comprise all computer readable media except for a transitory, propagating signal. Common forms of computer-readable media include, for example, a floppy disk, a flexible disk, hard disk, magnetic tape, or any other magnetic medium, a CD-ROM, any other optical medium, or any other medium from which a computer processor 176 can read.
The controller 174 is not limited to one processor 176 and memory component 178. The controller 174 may be several processors 176 and memory components 178.
The controller 174 is operably connected to the sensors 172. The tow arm actuators 130 (
There are factors, other than an increase or decrease in the height of the tow arms 128, that may change the angle of attack of the main screed plate 136 relative to the base 119 being paved. For example, the operator may adjust the angle of attack of the main screed plate 136 and the extension plate 144, manually or electronically, or an external factor such as a change in the temperature or consistency of the paving material may cause the angle of attack to change.
In another embodiment, the paving machine 100 may further include one or more frame inclinometers 180 (
In the illustrative embodiment, the frame slope βF is 0° as measured by the frame inclinometer 180 and the screed slope βS is 0° as measured by the screed inclinometer 182. 14B is a schematic illustration of the frame slope βF and the screed slope βS at a second point in time T2. In
Also disclosed is a method of automatically reducing transition marks 162 made by the screed assembly 118 of the paving machine 100 in the mat 120. The method may comprise while paving, determining, by the controller 174 based on data received from the sensor 172, when the inner end 148 is disposed above or below the first plane 156, and moving, by the controller 174 based on the determining, the inner end 148 to the first plane 156.
Also disclosed is an exemplary method of reducing transition marks 162 made by the screed assembly 118 of the paving machine 100 in the mat 120. Referring now to
In block 1210, based on operator input, the controller 174 increases or decreases the height of the tow arms 128 at the pivot point P in a direction perpendicular to the base 119 to be paved.
In block 1220, the controller 174 receives data from the sensors 172 indicating whether there is a change in the characteristics of the (paved) mat 120. In one embodiment, the controller 174 determines from the data that there is a transition mark 162 such as a transition ridge 164 in the mat 120 between the first and second surface sections 152, 154 of the mat 120. In another embodiment, the controller 174 may determine from the data that there is a transition waver 166 because the transverse position of the intersection 160 between the first and second surface sections 152, 154 of the mat 120 has moved (left or right).
In block 1230, the controller 174 determines whether the main screed trailing edge 139 and the extension trailing edge 146 have been configured by the operator to pave first and second surface sections 152, 154 of the mat 120 in planes that are substantially parallel to each other. In some embodiments, this information may be retrieved from memory 178 by the controller 174. If yes, the method proceeds to block 1240. If no, the method proceeds to block 1260.
In block 1240, the controller 174 determines whether the inner end 148 is disposed above or below the first plane 156. If yes, the method proceeds to block 1250.
In block 1250, the controller 174 moves the inner end 148 to the first plane 156. If the controller has previously determined in block 1230 that the main screed trailing edge 139 and the extension trailing edge 146 have been configured to pave first and second surface sections 152, 154 of the mat 120 in planes that are substantially parallel to each other, the controller 174 will move the entire extension trailing edge 146, including the inner end 148, to the first plane 156. The method then proceeds to block 1255.
In block 1255, the controller 174 receives data from the sensors 172 indicating whether there is additional change in the characteristics of the (paved) mat 120 indicative of the presence of an additional transition mark 162. If the controller 174 determines from the data that there is a transition mark 162 such as a transition ridge 164 in the 120 mat between the first and second surface sections 152, 154 of the mat 120 the method proceeds back to block 1240. In some embodiments, the controller 174 may be configured to determine over a period of elapsed time that there are no further changes in surface characteristics of the mat 120 (no further transition marks 162) before the method 1200 ends. This allows the controller 174 to maintain the extension trailing edge 146 and its inner end 148 in the first plane 156 as the elevation of the main screed plate 136 and first surface section 152 gradually changes to the increased or decreased mat thickness determined by the selected tow arm 128 position of block 1210.
In block 1260, the controller 174 determines whether the main screed plate 136 and the extension plate 144 are oriented at an angle to each other. This information may also be retrieved from memory 178 by the controller 174. If so the method proceeds to block 1265.
In block 1265, the controller 174 determines whether the extension plate 144 is fully extended. If yes, the method proceeds to block 1240. If no, the method proceeds to block 1270.
In block 1270, the controller 174 determines the position of the initial inner end 170 on the extension trailing edge 146. This information may also be retrieved from memory 178 by the controller 174. The controller 174 then determines whether the initial inner end 170 is disposed above or below the first plane 156. If yes, the method proceeds to block 1280.
In block 1280, the controller 174 moves the initial inner end 170 to the first plane 156. The method then proceeds to block 1290.
In block 1290, the controller 174 receives data from the sensors 172 indicating whether there is an additional change in the characteristics of the (paved) mat 120 (transition mark 162). If the controller 174 determines from the data that there is still a transition mark 162 such as a transition waver 166 in the mat 120 between the first and second surface sections 152, 154 of the mat 120 the method proceeds back to block 1270. In some embodiments, the controller 174 may be configured to determine over a period of elapsed time that there are no additional changes in surface characteristics of the mat 120 (transition marks 162) before the method 1200 ends. This allows the controller 174 to maintain the initial inner end 170 of the extension trailing edge 146 in the first plane 156 as the elevation of the main screed plate 136 and first surface section 152 gradually changes to the increased or decreased mat 120 thickness determined by the selected tow arm 128 position of block 1210.
Also disclosed is an exemplary alternative method of reducing transition marks 162 made by the screed assembly 118 of the paving machine 100 in the mat 120. Referring now to
In block 1310, the controller 174 receives data from the frame inclinometer 180 indicating the slope of the frame 102 at a first point in time T1 and at a second point in time T2. The controller 174 also receives data from the screed inclinometer 182 indicating the slope of the main screed plate 136 at the first point in time T1 and at the second point in time T2. Alternatively, the controller 174 may receive data from the screed inclinometer 182 indicating the slope of the main screed 132 (instead of the main screed plate 136) at the first point in time T1 and at the second point in time T2.
In block 1320, the controller calculates a frame slope change (the change in slope for the frame 102 from T1 to T2) and a screed slope change (the change in slope for the main screed plate 136 from T1 to T2). The controller 174 further determines from the data whether the change in slope for the frame 102 from T1 to T2, the frame slope change, is different than the change in slope for the main screed plate 136 from T1 to T2, the screed slope change. Alternatively, if the controller 174 in block 1310 receives data from the screed inclinometer 182 indicating the slope of the main screed 132 (instead of the main screed plate 136) at the first point in time T1 and at the second point in time T2, the controller in block 1320 may determine from the data whether the change in slope for the frame 102 (frame slope change) is different than the change in slope for the main screed 132 (screed slope change). If yes, the process proceeds to block 1330. If no, the process returns to block 1310.
In block 1330, the controller 174 determines whether the main screed trailing edge 139 and the extension trailing edge 146 have been configured by the operator to pave first and second surface sections 152, 154 of the mat 120 in planes that are substantially parallel to each other. In some embodiments, this information may be retrieved from memory 178 by the controller 174. If yes, the method proceeds to block 1350. If no, the method proceeds to block 1360.
In block 1350, the controller 174 moves the inner end 148 to the first plane 156. In one embodiment, the amount and direction of movement is determined by the difference between the change in slope for the frame 102 (from T1 to T2) as compared to the change in slope for the main screed plate 136 (from T1 to T2). In another embodiment, the amount and direction of movement is determined by the difference between the change in slope for the frame 102 (from T1 to T2) as compared to the change in slope for the main screed 132 (from T1 to T2). If the controller 174 has previously determined in block 1330 that the main screed trailing edge 139 and the extension trailing edge 146 have been configured to pave first and second surface sections 152, 154 of the mat 120 in planes that are substantially parallel to each other, the controller 174 will move the entire extension trailing edge 146, including the inner end 148, to the first plane 156. The method then proceeds to block 1355.
In block 1355, the controller 174 receives data from the sensors 172 indicating whether there is change in the characteristics of the (paved) mat 120 indicative of the presence of a transition mark 162. If the controller 174 determines from the data that there is a transition mark 162 such as a transition ridge 164 in the 120 mat between the first and second surface sections 152, 154 of the mat 120 the method returns to block 1350. This allows the controller 174, to check the accuracy of the adjustment made to the position of the inner end 148 (in block 1350). In some embodiments, the controller 174 may be configured to determine over a period of elapsed time that there are no changes in surface characteristics of the mat 120 (no transition marks 162) before the method 1300 ends.
In block 1360, the controller 174 determines whether the main screed plate 136 and the extension plate 144 are oriented at an angle to each other. This information may also be retrieved from memory 178 by the controller 174. If so the method proceeds to block 1365.
In block 1365, the controller 174 determines whether the extension plate 144 is fully extended. If yes, the method proceeds to block 1350. If no, the method proceeds to block 1370.
In block 1370, the controller 174 determines the position of the initial inner end 170 on the extension trailing edge 146. This information may also be retrieved from memory 178 by the controller 174.
In block 1380, the controller 174 moves the initial inner end 170 to the first plane 156. The method then proceeds to block 1390.
In block 1390, the controller 174 receives data from the sensors 172 indicating whether there is a change in the characteristics of the (paved) mat 120 (transition mark 162). If the controller 174 determines from the data that there is a transition mark 162 such as a transition waver 166 in the mat 120 between the first and second surface sections 152, 154 of the mat 120 the method proceeds to block 1380. This allows the controller 174, to check the accuracy of the adjustment made to the position of the initial inner end 170 (in block 1380). In some embodiments, the controller 174 may be configured to determine over a period of elapsed time that there are no additional changes in surface characteristics of the mat 120 (transition marks 162) before the method 1300 ends.
The features disclosed herein may be particularly beneficial to paving machines 100. Use of the features enables reduction in transition marks 162, for example, transition ridges 164 or transition waver 166, so that the mat 120 laid down by the paving machine 100 has an even surface from start to finish and does not have ridges or steps or lanes of uneven width.
Number | Name | Date | Kind |
---|---|---|---|
5362176 | Sovik | Nov 1994 | A |
5546123 | Ikeda | Aug 1996 | A |
5924819 | Breidenbach | Jul 1999 | A |
6113309 | Hollon | Sep 2000 | A |
6270284 | Sovik | Aug 2001 | B1 |
6273636 | Johanpeter | Aug 2001 | B1 |
6283672 | Sovik | Sep 2001 | B1 |
6352386 | Heims | Mar 2002 | B2 |
6435766 | Titford | Aug 2002 | B1 |
7491014 | Sick | Feb 2009 | B2 |
8128314 | Buschmann | Mar 2012 | B2 |
8221025 | Buschmann | Jul 2012 | B2 |
8591142 | Mittleman | Nov 2013 | B2 |
20140186115 | Graham et al. | Jul 2014 | A1 |
Number | Date | Country | |
---|---|---|---|
20160237629 A1 | Aug 2016 | US |