[ad_1]
Hearken to this text
The PPE module examined by gantry robotic will energy the Gateway area station. Supply: Bell-Everman
NASA’s Artemis Program plans to ship people again to the moon to ascertain a lunar floor base and area station. Generally known as Gateway, the area station shall be powered by the Energy and Propulsion Component, or PPE, module, which makes use of giant arrays of superior, multi-junction photo voltaic cells to generate 60 kilowatts of energy.
To make sure the PPE’s success, it’s essential to check the photo voltaic arrays with superior simulation that replicates daylight and measures every circuit’s efficiency. Engineered by Angstrom Designs Inc., the photo voltaic simulator heads have to be positioned at quite a few factors alongside the size and width of the photo voltaic arrays.
That course of that’s normally achieved utilizing automation frames that encompass linear movement levels. As a result of the PPE’s photo voltaic arrays are so giant, normal frames constructed for typical array sizes couldn’t present the mandatory vertical and horizontal movement.
Bell-Everman designed, engineered and fabricated a customized movement system that permits the Angstrom Designs photo voltaic simulator heads to check the PPE’s photo voltaic panels. And to make sure that the simulator heads are totally calibrated, we additionally constructed the I-formation gantry robotic that calibrates and validates the simulator efficiency in opposition to photo voltaic cell requirements.
Right here’s a deep dive into the mechanical challenges of assembly the movement system’s particular necessities.
Bell-Everman finds probably the most cost-effective design
An early design featured two bending tracks — one on the bottom and the opposite roughly 30 ft. excessive close to the highest of the panels. The tracks would help the LED photo voltaic simulators — a 3,500-lb. load — permitting them to check one deployed array, then go across the bend and check an array on the opposite aspect of an enormous scaffold construction.
However this resolution, which might function like an I-formation gantry, required specialised bearing techniques. This elevated design complexity and rapidly drove the venture past funds, given the peak and cargo necessities.
Instead design, Bell-Everman engineered a movement system that makes use of a cell base for X and Y motions, and a servo-controlled Z to boost the photo voltaic simulators up a three-story tall vertical tower. This mobile-robot gantry design was probably the most cost-effective possibility and drastically diminished system complexity.
Register now.
Body, movement system should keep upright
As a result of photo voltaic simulator payload, all the body of the mobile-robot gantry needed to bear plenty of weight and preserve the simulator LED arrays parallel to the photo voltaic array. This required a major quantity of finite factor evaluation to make sure the subframe may stand up to the forces of hoisting the load — and survive a seismic occasion with out toppling over.
Additionally, the totally constructed movement system is giant and should be capable to make a flip across the finish of a deployment construction in a really tight flooring plan.
Initially constructed to check the PPE’s panels, NASA can proceed to make use of the movement system to check future space-going applied sciences.
Heavy cantilevered lifting handles forces
The 240 photo voltaic simulator heads are nested in a pantographic morphing array in three balanced pivoting segments, which transitions between two preparations: a 2-by-18-ft. grid and a 6-by-6-ft. grid. Because the array actuates, it imparts excessive second forces on the movement system’s body.
The PPE photo voltaic simulator body’s pantographic morphing array of three balanced pivoting segments homes nested pLEDss heads within the open slots. Supply: Bell-Everman
To accommodate these forces, we used heavier-than-usual linear bearing rails and crossed curler bearings with an 8-in. bore to go Ethernet communication and 40 kW {of electrical} energy per section.
The array and morphing construction characterize a 3,500-lb. cantilevered load on the vertical tower, requiring a counterbalance to each stability second masses on the tower and supply one thing near impartial buoyancy.
Gross motion of the mixed payload and LED array is supplied by a ten,000-lb. drum hoist. To realize vertical movement, a single ServoBelt Heavy Linear is used with Bosch Rexroth drives and enormous redundant cables.
The counterbalance design ensures that the vertical drive solely sees a weight imbalance of fifty to 300 lb. — greater than sufficient respiration room for the ServoBelt Heavy LoopTrack drive, which may accommodate as much as 600 lb. of linear power.
Additionally, due to the counterbalance, any drive failure wouldn’t end in dropping this precious load. Threading these cables via pulley redirects permits the counterweight and payload to be raised collectively to their mid-height from a parked place on the backside.
This fascinating and totally redundant cable structure permits full impartial buoyancy all through the vary of the coarse positioning hoist.
Tower constructed piece by piece
The vertical tower supporting the photo voltaic simulator load will attain three tales excessive when totally constructed. As a result of it was too tall to suit contained in the constructing the place it was made, the tower was inbuilt three items.
We made a shorter counterbalance cable set to permit the underside part for use for full practical testing throughout the low ceiling of our meeting bay.
Because the raise travels up the finished vertical tower, any vibrations induced by imperfections the place every part is related would have an effect on the simulator efficiency and diagnostic high quality. We joined every tower part with a particular multigenerational technique of splicing, just like our long-travel gantry techniques. These common splicing joints allow easy vertical movement throughout the splices.
Z-axis automation for getting round
The movement system’s actuation is operated by hand aside from the Z-axis journey, which is totally automated. Due to the excessive worth of space-going photo voltaic arrays like this, it is much better to manually transfer axes of movement which have any likelihood of damaging the array.
An electrical-powered tug pulls all the system for big actions, together with when the system is faraway from or put into storage. When the system is introduced close to the PPE photo voltaic array, tremendous changes are made with lever arms connected to the system’s wheels. When the proper place is achieved, screw ft are lowered to the ground.
Absolutely constructed, the photo voltaic simulator tower reaches three tales. Right here, the pantographic morphing array is present in its six-by-six-foot configuration. Supply: Bell-Everman
Electrical system designed to keep away from flames
As a result of the simulator homes 240 of the 500-watt pLEDss heads, a big problem of this venture was managing over 120 kW of energy.
That includes many breakers and branches, {the electrical} system is designed to forestall overheating and fireplace injury ought to shorts happen at any degree.
Calibration system is separate
To make sure that Angstrom Designs’ programmable LED photo voltaic simulators (pLEDss) carry out efficiently, they have to be calibrated in opposition to photo voltaic cell requirements known as isotypes.
We additionally designed a calibration system for the PPE photo voltaic simulator to check in opposition to, consisting of an I-format gantry that homes the photo voltaic cell isotypes.
Generally known as the “Calibot,” this I-frame gantry robotic is able to calibrating the pLEDss heads whereas the system is in both morphing place.
pLEDss heads have full spectral management to present match junctions for cells from single junction as much as six junctions. Supply: Angstrom Designs
When the Calibot is maneuvered to the pLEDss tester, management containers are linked, and docking mechanisms protect the optimum standoff distance throughout calibration. Each the PPE simulator system and the Calibot shall be saved with NASA in the identical facility.
The pantographic morphing array consists of three smaller subarrays that every include 80 pLEDss heads. Every subarray has its personal terminal blocks and cables.
Every head’s DC energy provide is delivered 220 VAC to permit using smaller 18-gauge energy wires. Due to the quantity of harnessing, it is very important scale back weight and area for the practically 400 cables working to the breaker containers.
Based mostly on the early I-format gantry design — which wanted to make a U-turn across the help scaffold holding two photo voltaic arrays, a flooring mounted cable observe and a information system — the full price for the facility supply alone was estimated to be roughly $200,000.
Because of the mobile-robot gantry design with easy extension cordage, this expense was diminished to $6,000 and solely 150 ft of cable.
The complete venture may have been achieved with a big, track-based I-format gantry. However Bell-Everman simplified the design with cell gantry robots, considerably lowering system complexity and prices.
I-Kind linear robots that includes ServoBelt Linear actuators excel at point-to-point movement management. Supply: Bell-Everman
[ad_2]