Onefinity Elite Gen 2 CNC Documentation for the Onefinity Elite Gen 2 Foreman CNC router — hardware, software, job prep, operation, speeds/feeds, and safety. Onefinity Elite Gen 2 CNC Router Onefinity Elite Gen 2 CNC Router This tool is restricted to Makerspace Members, and requires a training before use. Request a training on Slack: #class-requests Workflow: (1) Design at home in VCarve Makerspace client edition → (2) Post-process toolpaths at the shop on master VCarve → (3) Run the job on the dedicated CNC shop PC via RTS-X. Never drive the machine from a personal laptop. Model Onefinity Elite Gen 2 Foreman (48×48 / ~49×49" cut area) Spindle Redline 80mm 1.5kW air-cooled, 110V, ER20 collet (up to 1/2" shank) Controller RealTime CNC (RTS-X) - shop PC only (no built-in HMI touchscreen) Date Purchased TBD Status Operational Link To Manual Onefinity Support - Gen 2 Elite Link to product page Gen 2 Elite Series Quick Reference Category Details Critical rules Training required • Dedicated CNC shop PC only - no personal laptops • Never leave the machine unattended while cutting • Wood and plastics only - no metals Key numbers ~49×49" cut area • ER20 collet, max 1/2" shank • Max ~1.5" bit diameter (VFD fault risk) • 3/4" spoilboard thickness Workflow Design at home (VCarve client) → Export G-code at shop (VCarve master) → Run job at shop (RTS-X on CNC PC) Get help Slack #woodworking • Onefinity support • RTS-X docs Description Our Onefinity Elite Gen 2 Foreman is a large-format CNC router for precision 2D and 3D cutting in wood and plastics. Members design projects at home in VCarve, generate toolpaths at the shop, and run jobs on the dedicated CNC computer using RTS-X. This machine replaces our retired homemade CNC router . Documentation New to this machine? Start with Safety Rules and read the pages in order - each page links to the next. Safety Rules Hardware and Machine Anatomy Software: VCarve and RTS-X Speeds and Feeds Preparing a Cut File Running a Job Maintenance and Troubleshooting Additional Resources Onefinity manuals and support RTS-X documentation VCarve Pro Makerspace Edition TBD: Shop photos of installed machine, T-tracks, spoilboard, and control station. Next: Safety Rules → Safety Rules ← Back to Onefinity hub Safety Rules Read this before operating the machine. These rules apply every time you use the Onefinity CNC - no exceptions. Training required - members only; request class on Slack #class-requests Never leave the machine unattended while cutting Approved materials: wood and plastics only - no metals Dust and chip hazards; fire risk from fine wood dust - especially important until dust collection is installed E-stop stops machine motion and spindle; does not shut down the shop PC Wear safety glasses; hearing protection recommended ← Hub | Next: Hardware and Machine Anatomy → Hardware and Machine Anatomy ← Back to Onefinity hub Hardware and Machine Anatomy Manufacturer Specifications (Gen 2 Foreman) Cut area: ~49" × 49⅞" (1245 × 1248 mm) Z travel (Z-20 slider): ~165 mm (~6.5") Gantry clearance: up to ~160 mm depending on Z-slider mount height Motion: closed-loop steppers; 60 mm X rail / 50 mm Y rails Spindle: Redline 80mm 1.5kW air-cooled - ER20 collet (up to 1/2" shank); max ~1.5" bit diameter recommended Power: 110V spindle Our Setup (Makerspace) Setting Value Implication Z-20 mount position Highest position Maximizes gantry clearance (~160 mm) but reduces effective Z reach to the spoilboard - plan job thickness accordingly Spoilboard 3/4" (19 mm) Include in Z-zero and max cut depth calculations; resurfacing removes material over time Workholding T-tracks Use T-track clamps and fixtures (no vacuum table) Dust collection Not installed yet Coming very soon - use shop vac / manual cleanup until installed Effective max work height also depends on spindle position in the mount and bit stick-out. Tall workpieces may eventually require lowering the Z assembly (trading gantry clearance for more Z reach). TBD: Exact effective max cut height measurement for our current mount + spoilboard setup. Bits and Collets The spindle uses an ER20 collet system . Collet size must match your bit’s shank diameter exactly - using the wrong size collet is a safety hazard. Spec Value Notes Collet type ER20 Standard ER20 collets; select size to match bit shank diameter exactly Max shank diameter 1/2" (12.7 mm) Largest ER20 collet size; do not attempt larger shanks Max bit diameter ~1.5" Larger bits have excess rotational mass and can fault the VFD - avoid Installation Two wrenches required One wrench on the spindle flat, one on the collet nut; never run with a loose collet Install and tighten the bit before any spindle power. Always inspect the collet for wear or damage before use; replace if needed. Component Glossary Component What it is Controlled by Spindle Motor that spins the cutting bit VFD + RTS-X VFD Variable Frequency Drive - converts power and sets spindle RPM RTS-X (must not be in manual/local mode during jobs) Z-20 slider Heavy-duty vertical axis assembly RTS-X motion firmware RTS-X controller Real-time motion controller (closed-loop on Elite) RTS-X firmware Shop PC Dedicated CNC computer at the makerspace RTS-X Windows app (sole interface - no HMI touchscreen) VCarve Pro CAM/design software - creates toolpaths, does not run the machine Separate from RTS-X Note: This machine does not have the optional Redline HMI touchscreen. All homing, zeroing, file import, simulation, and job execution happen through RTS-X on the dedicated shop PC. TBD: Physical layout diagram - shop photos of spindle, VFD, e-stop, shop PC station, and work area. Link stock Onefinity manual diagram until then. TBD: Shop-specific power outlet / breaker labeling. ← Safety Rules | Next: Software: VCarve and RTS-X → Software: VCarve and RTS-X ← Back to Onefinity hub Software: VCarve and RTS-X Getting Access Request CNC training on Slack: #class-requests Complete the CNC checkout/training class After checkout, an admin sends your Vectric/V&Co Makerspace invite so you can use the VCarve client edition at home Two separate software systems are involved: VCarve Pro for design and toolpath generation, and RTS-X for actually running the machine. VCarve Pro Makerspace Edition Our makerspace uses VCarve Pro Makerspace Edition . Members get a free client license for home use after training. At home (Client Edition) Install VCarve Pro from Vectric Sign in with your V&Co account after accepting a makerspace invite Design your project and run 3D preview/simulation Save your .crv project file Cannot save toolpaths or G-code from home - that requires the shop master edition At the shop (Master Edition) Licensed on makerspace computers (up to 5 installs) Installed on: the dedicated CNC computer(s) and the vinyl cutter computer Open the member’s .crv file (USB or cloud) Verify tooling and machine profile Save toolpaths → export G-code Transfer G-code to the dedicated CNC PC running RTS-X Helpful links: Vectric Makerspace login docs Vectric Makerspace overview video RTS-X (Realtime CNC) RTS-X is the only software that runs the machine. It handles homing, zeroing, spindle control, file import, simulation, and job execution. Rule: Always drive the machine from the dedicated CNC shop PC - never from a personal laptop or phone No HMI: We do not have the optional Redline touchscreen; the shop PC is the sole control interface Documentation and downloads: RTS-X Documentation Hub System Overview Settings reference Software downloads and updates Onefinity - Redline / Realtime Controller Manual Realtime Resources FAQ See also: Preparing a Cut File for post-processor setup. ← Hardware and Machine Anatomy | Next: Speeds and Feeds → Speeds and Feeds ← Back to Onefinity hub Speeds and Feeds Use this page as a reference when setting up toolpaths in VCarve. Start conservative - increase feed rate only after successful test cuts on scrap material. Match RPM to material type and bit diameter. 1.5kW spindle limit: Avoid bits larger than ~1.5" diameter - excess rotational mass can fault the VFD. Starter Values (Not Yet Shop-Verified) Values below are placeholders derived from manufacturer guidance and Vectric defaults. They will be replaced after test cuts at the makerspace. Material Bit type Diameter RPM Feed (IPM) Depth/cut Notes Hardwood Up-cut end mill 1/4" TBD TBD TBD From manual - verify at shop Plywood Up-cut end mill 1/4" TBD TBD TBD From manual - verify at shop MDF Up-cut end mill 1/4" TBD TBD TBD From manual - verify at shop Plastic Up-cut end mill 1/4" TBD TBD TBD From manual - verify at shop TBD: Shop-verified speeds and feeds after test cuts. Rows will be tagged "shop-verified" when confirmed. General Guidance Always confirm units (IPM vs mm/min) match your G-code post-processor Use VCarve’s tool database as a starting point, then verify on scrap material Reduce depth per pass if you hear chattering or see poor chip evacuation Refer to bit manufacturer recommendations for your specific cutter ← Software: VCarve and RTS-X | Next: Preparing a Cut File → Preparing a Cut File ← Back to Onefinity hub Preparing a Cut File Design at Home Checklist Confirm project units ( inches vs mm ) - must match your post-processor choice Set up the correct machine profile in VCarve (per the Onefinity + Vectric setup guide ): VCarve → Machine → Machine Configuration Management Click Download from the Cloud (upper-right corner) → Yes Manufacturer: Onefinity Series: Elite Redline (correct for Gen 2 Redline/Realtime) Model: Foreman 48×48 Configuration: Defaults (unless rotary added later) When saving toolpaths, choose: Onefinity Redline/Realtime (inch) or (mm) - match your project units Backup/manual post-processors: RealTime CNC Design your part and assign toolpaths - see Speeds and Feeds for starter values Run 3D preview / simulation in VCarve - check for unexpected plunges, tabs, and rapid collisions Save your .crv project and bring it to the shop via USB drive or cloud (either works) At the Shop - Export Toolpaths Open your .crv file on a master VCarve computer (CNC PC or vinyl cutter PC) Re-check tooling and run 3D preview again Save toolpaths → export G-code with the correct post-processor Transfer G-code to the dedicated CNC PC running RTS-X (USB or cloud) Once G-code is on the shop PC, continue to Running a Job for simulation, machine startup, and job execution. ← Speeds and Feeds | Next: Running a Job → Running a Job ← Back to Onefinity hub Running a Job Follow this checklist every time you run a job. Complete Preparing a Cut File and have your G-code on the shop PC before starting. Before Power-On (Safety-Critical) Install and tighten the bit first - before any spindle power; see Hardware and Machine Anatomy for collet and installation details Select the correct ER20 collet for your bit’s shank diameter Use two wrenches on the spindle nut; never run with a loose collet Clear the spoilboard area and confirm your workholding plan Wear safety glasses; hearing protection as needed Know the e-stop location Power-Up Sequence Verify e-stop is released Turn on main machine power Turn on VFD ; confirm it is in automatic/remote mode (NOT manual/local) Boot / wake the dedicated CNC shop PC; launch RTS-X Connect to the controller; home the machine Dust collection not yet installed - use shop vac for cleanup after cuts. Dust collection is coming soon. TBD: Preferred power-down order (VFD → main power). Shop-specific e-stop / power switch labeling. Job Setup 1. Secure the workpiece (T-tracks) Use T-tracks with appropriate clamps, hold-downs, or toe clamps Screwing into the 3/4" spoilboard is acceptable when clamps won’t work - avoid excessive holes Keep clamps and track hardware clear of the toolpath - check rapids in simulation Mind "no-go" zones near table edges where tracks may not reach 2. Set work zero (WCS) Standard practice for most jobs: XY zero: front-left corner of your workpiece - match the origin you set in VCarve Z zero: top surface of the material (most common), or spoilboard surface for through-cuts - match your VCarve setting In RTS-X: jog the bit to your XY zero point and zero the X and Y axes; lower the bit to just touch the material surface and zero the Z axis Use a paper slip or touch-off block for Z precision; avoid crashing the bit into the spoilboard TBD: Document our specific step-by-step touch-off procedure in RTS-X, with screenshots. Spoilboard is 3/4" thick. 3. Import G-code into RTS-X (USB or cloud) 4. Run simulation/preview in RTS-X Open the file in RTS-X and run the built-in preview/simulation before starting Confirm the bit does not plunge through material or into clamps/fixtures on the first rapid approach Verify the toolpath boundaries stay within your workholding setup Check that the first plunge point and rapid moves look correct relative to your zeroed position Consider watching the first few seconds of the cut at reduced feed override (e.g. 50%) until you are confident the job is running correctly 5. Position spindle over safe start point; confirm feed/speed in file During the Cut Remain at the machine and supervise the entire job. Zero tolerance for leaving unattended or leaving the room. Keep hands clear; never adjust clamps while the spindle is running Be ready to hit e-stop or feed-hold Shutdown Stop spindle; return to safe park position if applicable Remove workpiece and clean up Vacuum chips; check spoilboard for damage Power down VFD, then main power Log any issues on Slack ← Preparing a Cut File | Next: Maintenance and Troubleshooting → Maintenance and Troubleshooting ← Back to Onefinity hub Maintenance and Troubleshooting Maintenance Collet: Clean and inspect regularly; replace if worn or damaged Spoilboard: 3/4" board - monitor thickness as holes and resurfacing accumulate; resurface when uneven Dust collection / dust shoe: TBD - coming soon; add maintenance steps when installed Linear rails: Wipe down per Onefinity manual Report problems on Slack or to a shop officer Troubleshooting Symptom Likely cause Action VFD fault on start Manual mode, wrong startup order, oversized bit Check VFD is in remote/auto mode; press reset; verify bit size Homing fails Obstruction, e-stop engaged, limit switch Clear axis path, release e-stop, re-home Wrong cut size Inch/mm post-processor mismatch Re-export G-code with correct post-processor Crashes into clamps Wrong zero or skipped simulation Re-zero work coordinates, re-run RTS-X simulation Loose collet / bit pull-out Insufficient tightening Stop job; re-seat bit with two wrenches TBD: Dust collection troubleshooting once system is installed. ← Running a Job | End of guide - Back to hub