The present disclosure relates to a roller screed, and particularly a powered roller screed. More particularly, this disclosure relates to a portable powered roller screed.
According to the present disclosure, a powered roller screed apparatus is provided for leveling uncured concrete. The roller screed apparatus comprises a roller, a first operator roller controller coupled to the roller at a first end, and a second operator roller controller coupled to the roller at the second end. The roller includes a longitudinal axis and a cylindrical outer surface about the longitudinal axis. The first operator roller includes a rotary driver coupled to the roller and configured to rotate the roller about the longitudinal axis of the roller. The first operator roller controller also includes a roller mover coupled to the rotary driver and a speed control coupled to the rotary mover and configured to provide an input to the rotary driver.
In an illustrative embodiment, the rotary driver comprises a power source configured to provide rotational output and a rotary transmitter coupled to the power source and the roller, the rotary transmitter transferring the rotational output from the power source directly to the roller through a single stage at a ratio of about 1:1.
Illustratively, the power source may comprise an internal combustion engine. In other embodiments, the power source may comprise an electric motor.
In some illustrative embodiments, roller screed apparatus comprises a roller and an operator controller means for smoothing uncured concrete by rotating the roller to move uncured concrete while simultaneously pulling the roller screed apparatus such that the roller levels and smoothes the uncured concrete to a predefined level.
In some embodiments, the means for rotating the roller comprises power source means for providing rotational output and rotational transmitter means for transmitting the rotational output from the power source to the roller to roll the roller about a longitudinal axis of the roller. The rotational output from the power source means may have an axis of rotation that is generally parallel to the longitudinal axis of the roller. The rotational transmitter means may transmit rotational output from the power source to the roller through a single stage at a ratio of about 1:1.
Additional features of the disclosure will become apparent to those skilled in the art upon consideration of the following detailed description of illustrative embodiments exemplifying the best mode of carrying out the disclosure as presently perceived.
The detailed description particularly refers to the accompanying figures in which:
Referring to an illustrative diagram of a roller screed apparatus 10 shown in
In one illustrative embodiment of a powered roller screed apparatus 10 shown in
In use, roller assembly 12 is positioned on a pair of forms 28 (shown at the left side of
Referring now to
Various gear reduction ratios may be utilized in gearbox 50. For example, in some embodiments motor 48 may be a higher or lower speed internal combustion engine and gearbox 50 may have any of a number of ratios based on the size of motor 48 and the speed of rotational output from motor 48. Roller assembly 12 comprises a roller tube 212 having a diameter of about 4.5 inches. In other embodiments, roller tube 212 may be larger or smaller diameters and the reduction ratio of gearbox 50 may be chosen to control the rotational speed of roller tube 212 about axis 22.
In the illustrative embodiment of
Leg 70 is coupled to shaft 66 through a coupler 74. Coupler 74 comprises a lock collar 76 received on shaft 66 and a lock 78. Lock 78 comprises a t-shaped handle 84 and a threaded shaft (not shown). Lock collar 76 comprises two flanges 80 and 82. The threaded shaft of lock 78 is received through an aperture (not shown) in flange 80 and through an aperture (not shown) in leg 70. Flange 82 comprises a threaded hole (not shown) configured to receive the threaded shaft. Lock 78 is tightened by rotating handle 84 in a clockwise direction and is released by rotating handle 84 in a counter-clockwise direction. As lock 78 is tightened, flanges 80 and 82 are drawn together against leg 70 such that lock collar 76 is frictionally locked to shaft 66 and leg 70 is limited from rotating about axis 72 due to the clamp pressure between flanges 80 and 82 and leg 70. When lock 78 is released, leg 70 is positionable to any of a number of positions about axis 72. Once a position is selected, lock 78 is tightened to secure leg 70 in place. In this way, leg 70 may be positioned to support roller screed apparatus 10 or to an out-of-the-way position while roller screed apparatus 10 is in use.
In the illustrative embodiment, speed control 54 comprises a squeeze handle 86 pivotably coupled to a mount bracket 88. Mount bracket 88 is coupled to shaft 66 of roller mover 52 and is positioned such that squeeze handle 86 is accessible by operator 18 when operator 18 is using grip 64. Squeeze handle 86 is pivotable about an axis 90 relative to mount bracket 88. A throttle cable 62 is coupled to squeeze handle 86 such that pivoting about axis 90 actuates throttle cable 62. Throttle cable 62 provides a signal 56 to motor 48 to vary the speed of motor 48, which thereby varies the speed of rotation of roller assembly 12 about axis 22.
Mount end 68 of shaft 66 of roller mover 52 is received in a support bracket 92 coupled to a housing 94 of rotary transmitter 58. Support bracket 92 comprises a base 96 which couples to housing 94 and a clamp 98 coupled to base 96. Clamp 98 comprises a first portion 104 and a second portion 106 coupled to first portion 104 by two fasteners 100, 100. First portion 104 and second portion 106 are configured to form an aperture 102 sized to receive shaft 66. When shaft 66 is received in aperture 102, fasteners 100 are tightened to clamp shaft 66 between first portion 104 and second portion 106. Aperture 102 has a cylindrical shape which defines an axis of rotation 108. Shaft 66 is pivotable to any of a number of positions about axis 108 to adjust the position of roller mover 52 relative to rotary driver 26. When shaft 66 is positioned, clamp 98 is tightened to maintain the position of roller mover 52 relative to rotary driver 26. In some embodiments, one or both of the fasteners 100, 100 may be replaced by a lock similar to lock 78 to permit the position of roller mover 52 to be adjusted without the aid of tools. In other embodiments, first portion 104 may be pivotably mounted to base 96 to permit clamp 98 to pivot about a vertical axis relative to rotary transmitter 58.
Rotary driver 26 further comprises a lift handle 110 coupled to housing 94 by another support bracket 116 positioned at a top of rotary transmitter 58. Lift handle 110 provides a grip point for an operator 18, 20, 46 to grip and thereby move roller screed apparatus 10. Referring now to
Illustratively, rotary transmitter 58 has a single stage coupling power source 46 output 60 directly to roller assembly 12. As shown in
Driver pulley 128 comprises a rim 134 coupled to an axle 136. Axle 136 has a bearing end 138 and an input end 140. Bearing end 138 is supported in a bearing 142 (best seen in
Referring to
Rotation of driver pulley 128 transfers motion to connector belt 132 which is also frictionally engaged with a rim 148 of follower pulley 130. As shown in
Tension is maintained in connector belt 132 by a pair of tension adjusters 170 and 172. Tension adjuster 170 comprises a fixed block 172 coupled to side plate 126 by a pair of fasteners 174. Fixed block 172 comprises a through-hole 176 has a longitudinal axis 178. Tension adjuster 170 further comprises a threaded shaft 180 which comprises a threaded body 182 and a head 184. Threaded body 182 passes through through-hole 176 and has an end 186 which is coupled to a sliding block 188. Tension adjuster 170 further comprises a threaded nut 190 received on threaded body 182 of shaft 180. Nut 190 is positioned such that a lower surface 192 of nut 190 engages an upper surface 194 of fixed block 172. Engagement of nut 190 on shaft 180 maintains the position of sliding block 188 relative to fixed block 172. Further, rotation of nut 190 changes the spacing between sliding block 188 and fixed block 172.
Sliding block 188 comprises a through-hole 200 which also acts as a journal bearing as to axle 136 of driver pulley 128. Through-hole 200 supports axle 136. Sliding block 188 further comprises a pair of slots 204, 204 which each have a longitudinal axis parallel to the longitudinal axis 178. Tension adjuster 170 further comprises two fasteners 202, 202. Each fastener 202 passes through a slot 204 and a through-hole 206 formed in each side plate 120, 122. Fasteners 202, 202 act as clamps when tightened to clamp sliding block 188 in position.
Axle 136 of driver pulley 128 is supported by sliding block 188 and passes through a slot 198 formed in each side plate 126 and 122. Slots 198 each have a longitudinal axis parallel to the longitudinal axis 178. As the distance between fixed block 172 and sliding block 188 is changed, axle 136 is positioned within the slots 198 to vary the distance between axle 136 of driver pulley 128 and axle 162 of follower pulley 130. Varying the distance between axles 136 and 162 varies the tension in connector belt 132. In the illustrative embodiment, driver pulley 128 and follower pulley 130 are the same size. Since pulleys 128 and 130 are connected through a v-belt connector belt 132 the rotational motion is transferred therebetween at a ratio of approximately 1:1. In other embodiments, the sizes of pulleys 128 and 130 may be varied to change the ratio to some other ratio such as 1:2 or 2:1. It should be understood that any of a number of ratios may be chosen.
Also, in some embodiments, pulleys 128 and 130 may be replaced with sprockets and connector belt 132 may be replaced with a drive chain. When sprockets and a chain are used, it should be understood that the ratios between the sprockets may be varied similarly to the pulleys 128 and 130.
Roller assembly 12 comprises driver hub 166, roller tube 212 coupled to driver hub 166, and a follower hub 214 coupled to roller tube 212. Connector 164 of driver hub 166 comprises a keyed receptacle 216 which is configured to receive keyed portion 154 of axle 162 to transfer rotation from axle 162 to roller assembly 12. Follower hub 214 comprises a cylindrical shaft 216 having a longitudinal axis that is generally coincident with axis of rotation 22 of roller assembly 12.
Second operator roller controller 16 comprises a grip 218 coupled to a shaft 220 and a bearing housing 222 coupled to shaft 220. Bearing housing 222 has a bearing 224 which is sized to receive shaft 216 of follower hub 214 such that hub 214 rotates within bearing 224. Second operator roller controller 16 is retained on follower hub 214 by a fastener 226 received in a threaded hole 228 formed in shaft 216 of follower hub 214. Second operator roller controller 16 is used by second operator 20 to position roller screed apparatus 10 and to pull roller screed apparatus 10 in working direction 36 to level uncured concrete 44. Bearing housing 222 comprises a ball joint which permits second operator roller controller 16 to be positioned in a number of orientations relative to roller assembly 12. This reduces the chance for side-loading bearing 224 when second operator roller controller 16 is pushed or twisted during use.
This application claims priority under 35 U.S.C. § 119(e) to U.S. Provisional Application Ser. No. 60/677,445, filed May 3, 2005, which is expressly incorporated by reference herein.
Number | Date | Country | |
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60677445 | May 2005 | US |