Stepper Indexer
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Pacific Scientific 5240 Sigma Line Stepper Indexer $150.00 |
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Slo-Syn 3180-PI Servo Stepper Motor Indexer / Driver $499.95 |
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DNS MOTOR STEPPER INDEXER H 2-39-43110 $582.60 |
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DNS MOTOR STEPPER INDEXER V 2-39-43111 $803.86 |
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Horner Electric HE693STP111E Indexer Stepper Motor $325.00 |
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Parker Compumotor LE Series LE57-51 Micro Stepper Step Drive Motor Indexer $64.79 |
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Lot 7 Parker Compumotor OEM010 Indexer Stepper Motor Gear Motor Vexta 2-Ph PK244 $49.99 |
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Parker Hann OEM Series Compumotor OEM010 Single Axis Indexer Stepper CNC $225.00 |
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NEW PARKER OEM750X INDEXER STEPPER DRIVE $709.00 |
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PARKER OEM750X INDEXER STEPPER DRIVE OEM750X $429.00 |
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PARKER OEM750X INDEXER STEPPER DRIVE $425.00 |
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Vexta 2-Phase Driver UI2120G Stepper Driver with built in indexer CNC Router $225.00 |
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Parker Compumotor Zeta4 Stepper Indexer Drive ++ $349.95 |
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DEK 265GS/GSX/LT #9SE07 FWD STEPPER MOTOR ASSEMBLY – X FWD HOME/STEPPER/INDEX $125.00 |
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SUPERIOR ELECTRIC SP155A-9214 SLO-SYN STEPPER STEPPING MOTOR PRESET INDEXER $199.99 |
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Horner Electric HE693STP111E Indexer Stepper Motor $355.00 |
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API P315X SERIES P315X-H-X3 STEPPER INDEXER DRIVE $675.00 |
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PARKER COMPUMOTOR OEM ZL6 STEPPER DRIVE INDEXER OEMZL6 $399.00 |
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New Parker Compumotor Indexer Stepper Drive OEM350 $292.00 |
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ORMEC G20-AYB-00 ULTRADRIVE STEPPER INDEXER DRIVE $89.99 |
Automating A Swill Brand – Automation Industry
Automating a Beverage Line – Automation Globe
The organization chose the PXI platform from automation supplier National Instruments Corp., Austin, Texas. With it, says Hammond, ?we probably easily synchronize industrial digital I/O, motion, and vision and use one controller. With LabView (National Instruments? graphical programming environment) we probably also make use of the same programming language for motion, vision and industrial digital I/O. Having one controller for all operations, and also just one programming language, reduced the general number of the internal system, making it more cost-effective than PLCs.? They created a system featuring a six-position rotary indexing table that could be dropped into an existing conveyor line. This procedure removes the cans that come from the in-feed conveyor and loads them onto the rotary Nuclear Link Indexer Review. After sequencing through the top-seal operation, the cans are placed on that outgoing conveyor that carries them to one of six wide packing conveyor tables. Different types of can labels can all employ exactly the same top-seal type, along with the cans are automatically shunted into the packing conveyor to lose manual sorting. Pneumatic actuators are being used to pick the cans and operate a customized label applicator. ?We had to select pneumatics for his or her high speeds to satisfy overall cycle time,? reflects Hammond.
At station 1, a container is picked up that come from the in-feed conveyor and placed into a spindle base on the index table. Three cameras then take pictures of the can at station 2 and examine the figures for the bar code. When the bar code can’t be read, the can is rotated for a better view. The seal is directed to the top level of your can at station 3 and also the seal wings are pressed the actual side of many can at station 4. Station 5 removes the cans that come from the rotary index table and loads them onto the out-feed conveyor. Station 6 is a normally empty position that’s monitored of the presence of a container that remains on account of an out-of-tolerance diameter.
?Station 2 was a challenge implement and are still achieve the desired performance,? recalls Hammond. On this station, the position of those bar code first had to be detected throughout the perimeter of your can. The background artwork of your label made this difficult as a result of the variety of color variations, surface finishes and patterns. A custom, three-level detection and discrimination scheme was created to fulfill this challenge.
?This happened further complicated by way of the distortion within the images from the center of the camera field of view (FOV). The presence of any bar code which was a with the fringe of the FOV could possibly be identified, but the resolution and distortion prevented the reading of those bar code. In this instance, the can was rotated to center the pull up bar code in the nearest camera FOV.? After reading the pull up bar code, an alternate rotation of those can was needed to orient the can for correct applying the highest seal along at the next station. As a consequence of space constraints, the position and quantity of cameras could not allow for complete 360-degree viewing. If no bar code was detected in the first views because of the cameras, the can was rotated to apply the hidden parts of the cans in the view of the cameras. ?Worst-case positions of a can may require seven images and three moves to complete the operation for the station.? At station 2, a big stepper motor drove the spindle against a friction drive wheel. As soon as the rotary index table was nearby the index point, the stepper was driven in for the pneumatic slide. At nearly precisely the same time, a spindle break was released with another pneumatic mechanism. While this all was going on at station 2, the opposite operations for the other stations continued in parallel to reach the part cycle time.
