Equipment

HP Jet Fusion 5600

Typical part accuracy of ±0.2 mm up to 100mm, then ±0.2% for larger dimensions. Achieves general tolerances comparable to ISO 2768-m.

HP Jet Fusion 5210 Pro

Dimensional Accuracy typically meets ±0.2mm up to 100mm, then ±0.2% of the part length for larger dimensions. Highly dependent on part geometry, orientation, and cooling protocol.

HP Jet Fusion 5420W

Typically ±0.3 mm up to 100 mm, then ±0.3% of the nominal dimension for larger features. Generally conforms to ISO 2768-m for non-critical dimensions.

HP Jet Fusion 580

Typical dimensional accuracy is ±0.3mm for parts under 100mm, and ±0.3% for larger dimensions. This aligns with an IT13-IT14 tolerance grade, or roughly ISO 2768-m for general dimensions, though complex geometries can vary.

HP Jet Fusion 4200

Typical dimensional accuracy of ±0.2 mm (±0.008 in) for features under 100mm, plus an additional 0.002 mm/mm for larger dimensions. Capable of producing parts that generally fall within the ISO 2768-m tolerance class for non-critical features.

UnionTech Lite 600 HD

Typical accuracy of ±0.1 mm for dimensions under 100 mm, and ±0.1% for dimensions over 100 mm. Higher precision can be achieved on critical features with process tuning. Excellent for parts requiring IT10-IT12 tolerance grades.

UnionTech Lite 800 HD

Typical accuracy is ±0.1mm for dimensions ≤100mm, or ±0.1% for dimensions >100mm. Part accuracy is highly dependent on geometry, orientation, and post-curing protocol. Achieves surface finishes comparable to ISO N7-N8 before secondary finishing.

UnionTech RSPro 1400

Typical accuracy of ±0.1mm for dimensions under 100mm, plus ±0.1% of feature length for dimensions over 100mm. High-resolution mode can achieve finer detail but does not significantly improve global dimensional accuracy over the large platform.

UnionTech RSPro 800

Typical accuracy is ±0.1% of the part dimension, with a minimum deviation of ±0.1 mm. Higher accuracy can be achieved through process optimization and for smaller parts.

UnionTech Martrix 190

Typically achieves ±0.1 mm for dimensions < 100 mm, and ±0.1% for larger dimensions. Higher precision is achievable with fine-tuned material profiles and controlled environmental conditions.

BLT S210

As-printed dimensional accuracy is typically within ±0.1 mm for features under 100 mm. Post-machining is required for tolerances tighter than ISO 2768-f or IT Grade 10. Surface finish (Ra) as-printed is around 6-12 μm, requiring secondary finishing.

BLT S310

As-printed dimensional accuracy is typically within ±0.1 mm on small features (<100mm), or 0.2% on larger dimensions, roughly equivalent to ISO 2768-m. Critical features require post-machining to achieve IT6-IT7 tolerances.

BLT S400

As-printed dimensional accuracy typically falls within ±0.1mm for features under 100mm, or ±0.2% for larger dimensions. Critical features require post-machining to achieve tolerances of IT7 or better.

BLT S600

As-printed: Typically ±0.1 to ±0.2 mm over a 100 mm length. After post-machining of critical features, can achieve tolerances conforming to IT7 grade or better (e.g., ISO 2768-f). Surface roughness as-printed is Ra 6-15 μm, requiring secondary finishing.

BLT S800

As-printed: ±0.1% of nominal size (with a minimum of ±0.1mm). Tighter tolerances (IT7 or better) are consistently achieved through post-machining operations on critical features.

Bambu Lab X1 Carbon

Typical dimensional accuracy is ±0.15mm or ±0.5% of the feature dimension, whichever is greater. Highly dependent on material selection, print orientation, and calibration. Not a substitute for CNC machining for features requiring tolerances tighter than ISO 2768-m.

Bambu Lab X1E

Typical dimensional accuracy: ±0.2 mm or ±0.5% of the nominal dimension, whichever is greater. Not suitable for applications requiring tolerances tighter than ISO 2768-m without post-processing.

Bambu Lab P1S

Typical dimensional accuracy is within ±0.2 mm or ±0.5% of the feature dimension, whichever is greater. Highly dependent on part geometry, material selection, and print orientation.

Bambu Lab P1P

Typically ±0.2mm or ±0.5% of feature dimension, whichever is greater. Precision is highly dependent on material selection, part geometry, and slicer calibration (e.g., flow rate, pressure advance). Not suitable for applications requiring tolerances tighter than ISO 2768-coarse.

Bambu Lab A1

Typical dimensional accuracy: ±0.2 mm or ±0.5% of nominal dimension, whichever is greater. Not suitable for applications requiring IT-grade tolerances.

Bambu Lab A1 mini

Typical dimensional accuracy is within ±0.15 mm or ±0.5% of the dimension, whichever is greater, under controlled conditions with properly dried filament. Not suitable for applications requiring IT-grade tolerances.

HeyGears UltraCraft A2D

Typical dimensional accuracy is ±0.1mm for the first 100mm, with an additional ±0.05% for larger dimensions. Feature detail resolution is limited by the native 50μm XY pixel size.

HeyGears UltraCraft DS

Typical dimensional accuracy of ±0.05mm for features under 100mm, with high repeatability across builds. Capable of producing surface finishes (Ra) of 1-3 µm on non-supported surfaces, suitable for master patterns or end-use parts with minimal post-processing.

HeyGears UltraCraft A2D Ortho

Typical dimensional accuracy of ±0.05 mm for features under 50mm. Repeatability is high, but final accuracy is heavily dependent on part geometry, print orientation, and post-curing protocol.

HeyGears Reflex

Typically ±0.1 mm for general dimensions under 100mm. Critical feature accuracy can achieve ±0.05 mm, highly dependent on part geometry, orientation, and material properties. Comparable to ISO 2768-f for specific, optimized features.

Creality K1 Max

Typical dimensional accuracy: ±0.1mm for features under 100mm, or ±0.2% for larger dimensions. Repeatability is highly dependent on regular calibration, material selection, and ambient conditions.

Creality K1C

Typical dimensional accuracy of ±0.1mm on features under 100mm. Precision is highly dependent on material choice, print speed, and meticulous calibration; not a substitute for CNC machining when tolerances tighter than ISO 2768-m are required.

Creality Ender-3 V3 Plus

Typical dimensional accuracy is ±0.2 mm or ±0.5% of the feature dimension, whichever is greater. With material-specific tuning (flow, pressure advance) and a stable environment, critical features under 100mm can achieve ±0.1 mm repeatability.

Creality Halot-Mage Pro

Typical dimensional accuracy: ±0.1mm for features under 100mm, with an additional ±0.1% for larger dimensions. Not suitable for applications requiring IT grades better than IT14 without part-specific calibration and compensation.

Kings Kings 600 Pro

Typically achieves ±0.1mm for dimensions under 100mm, and ±0.1% for dimensions over 100mm. Higher precision is achievable with material-specific parameter tuning and strict environmental control.

Kings Kings 1700

Typically ±0.1mm for dimensions under 100mm, or ±0.1% of part dimension for larger features. Exceeds ISO 2768-m for general tolerances on well-calibrated runs.

Kings Kings 450

Typically ±0.1 mm for dimensions under 100 mm, or ±0.1% for larger dimensions. Can achieve surface roughness (Ra) of 1-3 μm after standard post-processing.

EOS P 396

Typical dimensional accuracy of ±0.25 mm or ±0.15% of nominal dimension (whichever is greater). Often compliant with plastic tolerance standards like DIN 16742-T for additive manufacturing.

EOS M 290

As-printed typical part accuracy of ±0.1mm for the first 100mm, with an additional ±0.05% of part length thereafter. Surface roughness (Ra) as-printed is typically 6-15 µm depending on orientation and parameters. Post-machining can achieve tolerances down to IT6 or better (e.g., ±0.01mm) on critical features.

Stratasys F370

Achievable accuracy is typically within +/- 0.200 mm or +/- 0.002 mm/mm, whichever is greater. Part-to-part repeatability is high due to the controlled thermal environment.

Stratasys Fortus 450mc

Typically achieves ±0.127 mm for first 25.4mm, with an additional ±0.0015 mm/mm for dimensions beyond that. Suitable for functional prototypes and fixtures where general tolerances (e.g., looser than ISO 2768-m) are acceptable prior to any secondary machining.

Stratasys J850 Prime

Typical accuracy of ±0.1 mm for features under 100mm, or up to ±0.2% of part length for full model size. This is heavily dependent on geometry, orientation, and material choice.

Farsoon FS422M

As-printed: Typically ±0.1mm on features under 100mm, and 0.1-0.2% on larger dimensions. Conforms to ISO 2768-m for general tolerances. Post-machining is required for features needing IT6-IT7 grade precision.

Farsoon HT403P

Typical dimensional accuracy is ±0.2% of the nominal dimension, with a lower limit of ±0.2 mm. Part-to-part repeatability is highly dependent on consistent powder management and thermal field stability.

Haitian Mars III 60T

Part dimensional tolerance is capable of achieving DIN 16742 TG6, equivalent to IT10-IT12. This is heavily dependent on mold tooling quality, material stability, and process control. Machine's platen position repeatability is typically within ±0.05 mm.

Haitian Mars III 90T

Achievable part tolerance is typically within ±0.1mm. For well-designed parts and high-quality tooling under stable process control, critical dimensions can hold IT10-IT12 (ISO 286), with specific features reaching ±0.05mm.

Haitian Mars III 120T

Typically achieves IT10-IT12 for general production. Can reliably hold ±0.05 mm on critical dimensions (achieving IT8-IT9) when paired with a high-precision mold, stable material, and a tightly controlled process.

Haitian Mars III 160T

General part tolerance: ±0.1 mm (conforming to ISO 2768-m). Can achieve ±0.05 mm on critical dimensions with a high-quality mold and stable process control. Dimensional repeatability corresponds to IT Grade 10-12.

Haitian Mars III 200T

Typically achieves part dimensional tolerances of ±0.10 mm to ±0.25 mm, conforming to ISO 2768-m. With a high-quality mold and a stable, optimized process, critical dimensions can be held within ±0.05 mm. Excellent shot-to-shot weight repeatability, typically <0.2%, is standard.

Haitian Mars III 250T

Typically achieves DIN 16742 TG6-TG7. Capable of achieving ±0.05mm on critical, well-supported dimensions with a high-precision mold, stable material, and tightly controlled process parameters.

Haitian Mars III 320T

Part tolerance achievable: ±0.10mm on most dimensions. With a high-precision mold and a stable, decoupled molding process, critical features can hold ±0.05mm. Generally capable of producing parts that meet DIN 16742-TG6 standards.

Haitian Mars III 380T

Capable of producing parts to ISO 2768-m (medium) tolerances. With a high-quality mold and stable process, critical dimensions can achieve a process capability within the IT11-IT13 tolerance grade.

Haitian Mars III 470T

Achievable part tolerance typically falls within IT11-IT13. For well-designed parts and high-quality tooling, dimensional stability of ±0.1 mm can be maintained on critical features, though general tolerances are closer to ISO 2768-m.

Haitian Mars III 530T

General Tolerance: ±0.1 mm. Capable of achieving IT8-IT10 grade with a high-precision mold, stable material, and a tightly controlled process.

Haitian Mars III 600T

Typical part tolerance: ±0.1 mm on features up to 100mm. Can achieve DIN 16742-TG6 under a stable process window with high-quality tooling. Not intended for micro-molding tolerances.

Haitian Mars III 800T

General tolerance capability of ISO 2768-m (medium). Achieves part-dependent dimensional tolerances of ±0.1 mm to ±0.2 mm, corresponding to industrial standard IT10-IT12.

Haitian Mars III 1000T

General part tolerance: ISO 2768-m (e.g., ±0.1mm to ±0.3mm depending on dimension). Capable of achieving IT10-IT12 on well-designed parts with a high-quality mold and a stable, decoupled molding process.

Haitian Jupiter III 450T

General part tolerance: ISO 2768-m. Critical dimensional control can achieve ±0.1 mm, highly dependent on part geometry, material selection, and high-quality mold construction. Not suitable for micro-molding tolerances.

Haitian Jupiter III 550T

Typically achieves ISO 2768-m. Capable of holding ±0.05mm on specific, well-controlled features under a stable process, with general part tolerances in the IT10-IT12 range.

Haitian Jupiter III 650T

Part-level tolerance typically achieves DIN 16742-TG6 or ISO 20457 JS13. For critical dimensions under a stable process with a high-quality mold, ±0.1mm is achievable, but this is highly dependent on material choice, part geometry, and wall thickness consistency.

Haitian Jupiter III 750T

General purpose tolerance of ±0.15mm to ±0.25mm for dimensions under 300mm, subject to material and part geometry. Not suitable for applications requiring micron-level precision (e.g., IT8 or tighter). Conforms to general SPI (Society of the Plastics Industry) commercial tolerance standards.

Haitian Jupiter III 900T

Achievable part tolerance typically falls within IT11-IT13, heavily dependent on part design, material stability, and mold quality. For well-designed parts, ±0.15mm on non-critical dimensions is a practical expectation.

Haitian Jupiter III 1080T

Typical part tolerance achievable: ISO 2768-m (medium). For critical dimensions with a robust process and high-quality mold, can achieve down to ±0.10mm, corresponding to IT Grade 11-12.

Haitian Jupiter III 1200T

Part-dependent, typically achieves ISO 20457 CT10-CT12 (equivalent to IT11-IT13) for general dimensions on large parts. Critical features can be improved with advanced process control and superior mold tooling.

Haitian Jupiter III 1600T

Machine repeatability is high, but final part tolerance is dominated by mold quality, material selection, and process stability. Typically achieves general tolerances of ISO 2768-m. On a high-quality mold with a stable process, critical dimensions can hold ±0.1mm to ±0.2mm over a 500mm length.

Haitian Jupiter III 2100T

Part tolerance is highly dependent on mold quality, material stability, and process control. The machine's repeatability typically supports achieving DIN 16742 TG6-TG7, or general dimensional tolerances of ±0.1% to ±0.2% of nominal size for large parts.

Haitian Jupiter III 3000T

Generally achieves dimensional tolerances within ISO 2768-m. Critical feature repeatability can reach ±0.15mm, but overall part tolerance is highly dependent on part geometry, material thermal stability, and mold cooling efficiency. Warpage control over large surfaces is the primary quality challenge.

Zhafir Venus III 40T

Capable of achieving dimensional tolerances within ±0.02mm on well-designed parts and high-quality tooling. Consistently holds molding process parameters for production that meets ISO 286 Grade IT6-IT7 standards.

Zhafir Venus III 60T

Capable of achieving dimensional tolerances of ±0.02mm to ±0.05mm on critical features under stable process control. Corresponds to an IT Grade of IT8-IT10 depending on material and part geometry.

Zhafir Venus III 90T

Capable of producing parts meeting ±0.02mm to ±0.05mm on critical dimensions, enabling final part quality in the IT8-IT10 range. Shot-to-shot weight consistency is typically within ±0.1% under stable process control.

Zhafir Venus III 120T

Capable of consistently holding part tolerances of ±0.05mm (0.002 in) on well-designed parts and tooling. Routinely achieves molding process capabilities (Cpk) > 1.67 for critical dimensions. Conforms to DIN 16742 tolerance group TG5-TG6.

Zhafir Venus III 150T

Achieves typical part tolerances of ±0.05mm. Capable of holding critical dimensions to ±0.02mm with a high-quality mold, stable process, and engineering-grade material.

Zhafir Venus III 190T

Capable of achieving dimensional tolerances down to ±0.05 mm on well-designed parts with stable processing. Consistently holds a general tolerance grade of IT8-IT10, often tighter than ISO 2768-m for critical features.

Zhafir Venus III 230T

Capable of achieving dimensional tolerances down to ±0.02 mm on critical features under stable process control. Routinely holds part quality consistent with IT Grade 8-10, highly dependent on tool quality and material stability.

Zhafir Venus III 300T

Capable of holding dimensional tolerances of ±0.05 mm to ±0.1 mm on well-designed parts and high-quality molds. Corresponds roughly to IT Grade 8-10 or DIN 16742 TG5-TG7 depending on material and geometry.

Zhafir Venus III 450T

Capable of achieving dimensional tolerances of ±0.05mm on well-designed parts. Consistently holds process capabilities (Cpk) > 1.67 for critical dimensions, typically producing parts within the IT7-IT8 tolerance grade range.

Zhafir Venus III 600T

Capable of maintaining part dimensional tolerances within ±0.03mm to ±0.1mm, highly dependent on mold quality, material stability, and process control. Achieves part weight repeatability better than 0.1%, conforming to a process capability index (Cpk) > 1.67 in stable production.

Zhafir Zeres III 60T

Capable of achieving dimensional tolerances of ±0.05mm on small features. Can consistently hold general part tolerances within ISO 286 Grade IT9-IT10, with higher precision possible on critical-to-function dimensions depending on material and part geometry.

Zhafir Zeres III 90T

Process repeatability enables finished part tolerances of ±0.05 mm on critical dimensions with stable engineering polymers. Machine positioning repeatability is typically within ±0.01 mm, supporting a process capability (Cpk) > 1.67 for demanding applications.

Zhafir Zeres III 120T

Capable of achieving ±0.05mm on critical dimensions with a precision mold and stable process. General part tolerance typically conforms to DIN 16742-TG5/TG6.

Zhafir Zeres III 150T

Achieves dimensional tolerances up to IT Grade 7-8 on critical features. Typically holds ±0.05 mm to ±0.10 mm, depending on material selection and part geometry.

Zhafir Zeres III 190T

Capable of achieving IT8-IT10 on part dimensions under stable process control. Can hold critical feature tolerances down to ±0.05 mm, highly dependent on mold quality, material selection, and ambient conditions. Shot-to-shot weight repeatability is exceptional, typically < ±0.1%.

Zhafir Zeres III 230T

Achieves IT10-IT12 under standard production. With a precision mold and stable process parameters, part-to-part dimensional repeatability can be held within ±0.05mm to ±0.1mm, highly dependent on material choice and geometry.

Zhafir Zeres III 300T

Capable of achieving dimensional tolerances of ±0.05 mm on well-designed parts and stable processes. Typically conforms to IT Grade 8-10.

Zhafir Zeres III 450T

Capable of achieving dimensional tolerances of ±0.05mm to ±0.1mm, typically conforming to DIN 16742 tolerance group TG5-TG7 or an IT Grade of IT10-IT12, highly dependent on mold quality, material stability, and process control.

Zhafir Zeres III 600T

Typical achievable part tolerance: ±0.05 mm to ±0.15 mm. Highly dependent on mold quality, material selection, and part geometry. Process repeatability (CpK) can exceed 1.67 under stable, well-managed production conditions.

Arburg Allrounder H 400T

Consistently capable of achieving dimensional tolerances of ±0.02mm to ±0.05mm, dependent on material selection, part geometry, and mold quality. Can reliably hold DIN 16742 plastic tolerance groups TG5/TG6.

Arburg Allrounder H 500T

Capable of achieving IT7-IT8 grade tolerances on molded parts under stable process conditions. Routinely holds dimensional tolerances of ±0.05 mm on critical features. A process capability of Cpk ≥ 1.66 is achievable for stable, high-volume production.

Arburg Allrounder H 600T

Capable of achieving IT8-IT10 on part dimensions under a stable process. Typical achievable tolerance is ±0.08mm to ±0.20mm, highly dependent on material selection (especially differential shrinkage), part geometry, and mold quality.

Arburg Allrounder H 800T

Capable of achieving IT7-IT8 tolerance grade on well-designed parts and high-quality molds. Real-world part-level precision is typically in the ±0.08mm to ±0.15mm range for features >100mm, heavily dependent on material and part geometry.

Arburg Allrounder H 1000T

Machine repeatability supports extremely tight process windows, enabling part tolerances down to ±0.025mm on critical features, though final precision is dominated by mold quality and material stability. Consistently capable of producing parts that meet IT8-IT10 tolerance grades.

Arburg Allrounder H 1500T

Achievable part tolerance of ±0.05mm to ±0.15mm. Highly dependent on mold quality, material selection (e.g., amorphous vs. crystalline), and process control. Generally enables production within IT10-IT12 tolerance grades for standard parts.

Arburg Allrounder H 2000T

Typically achieves IT8-IT10 grade tolerances. For a well-designed part and mold, dimensional precision of ±0.1mm to ±0.25mm can be consistently held on large-scale components, subject to material shrinkage and geometry.

Arburg Allrounder H 2700T

Capable of achieving dimensional tolerances of ±0.05 mm on critical features, highly dependent on mold quality, material stability, and process control. Generally produces parts within ISO 2768-m or tighter.

Arburg Allrounder H 3200T

Achievable part tolerance: ±0.025mm to ±0.1mm, highly dependent on mold quality, material selection, and process control. Can consistently hold dimensional capabilities within IT Grade 7-8.

Arburg Allrounder H 4700T

Capable of achieving part tolerances within ISO 2768-f or tighter, often down to ±0.05mm on critical dimensions. Consistently produces parts meeting IT7-IT8 tolerance grades, highly dependent on mold quality and material stability.

Arburg Allrounder H 6500T

Achievable part tolerances of ±0.05mm to ±0.1mm, highly dependent on part geometry, material choice, and mold quality. Capable of maintaining high process capability (Cpk > 1.67) for dimensions that conform to ISO 2768-f.

Arburg Allrounder A 400T

Consistently holds ±0.02mm to ±0.05mm on critical dimensions, enabling production within IT8-IT10 tolerance grades, depending on material rheology and part geometry.

Arburg Allrounder A 600T

Capable of consistently holding dimensional tolerances of ±0.02mm to ±0.05mm on critical features, achieving quality grades of IT7-IT8 under controlled process conditions with a high-quality mold.

Arburg Allrounder A 800T

Capable of holding dimensional tolerances of ±0.05mm on critical features, dependent on part geometry, material stability, and mold quality. Generally exceeds ISO 2768-f.

Arburg Allrounder A 1000T

General part tolerance: ISO 2768-m. Critical functional dimensions can achieve ±0.05mm to ±0.1mm, depending on material choice, mold quality, and part geometry. Process is stable enough to consistently achieve a Cpk greater than 1.67 for critical-to-quality (CTQ) features.

Arburg Allrounder A 1500T

Typical Part Tolerance: ISO 2768-m (general), but capable of achieving ±0.02mm on critical features under controlled conditions. Shot-to-shot weight repeatability: <0.1%. Conforms to molding precision grade IT7-IT8.

Arburg Allrounder A 2000T

Achievable part tolerance of ±0.05 mm to ±0.1 mm on critical features, highly dependent on mold quality, material stability, and part geometry. Corresponds to a process capability of IT Grade 8-10.

Engel victory 50T

Part Tolerance: Can achieve ±0.05mm to ±0.1mm on critical dimensions, highly dependent on mold quality, material selection, and process control. Generally capable of producing parts conforming to DIN 16742 TG6/TG7.

Engel victory 80T

Machine repeatability allows for part production typically within ISO 2768-m or tighter, often achieving dimensional tolerances of ±0.05mm. Final part precision is heavily dependent on mold quality, material consistency, and process control. Positional repeatability of moving platen is < ±0.03mm.

Engel victory 120T

Capable of achieving dimensional tolerances within ±0.05 mm to ±0.15 mm, corresponding to an industrial grade of IT9-IT11. Final part precision is heavily dependent on mold quality, material stability, and process control.

Engel victory 160T

Typical part tolerance: ±0.05mm to ±0.1mm, highly dependent on part geometry, material, and mold quality. Process capability can reliably hold dimensional tolerances within an IT10-IT12 grade.

Engel victory 200T

Capable of achieving IT8-IT10 on part dimensions under a stable process. Shot-to-shot weight and dimensional repeatability can be held within ±0.02mm to ±0.05mm, highly contingent on mold quality, material consistency, and ambient factory conditions.

Engel victory 300T

Typical part tolerance achievable: ±0.05mm to ±0.15mm, contingent on material, part geometry, and mold quality. Machine's high repeatability enables stable production within IT Grade 10-12.

Engel victory 400T

Achievable part tolerance is highly dependent on mold quality and material, but the machine's repeatability supports tolerances of ±0.05 mm to ±0.1 mm on well-designed parts. Corresponds to a part quality grade of ISO 2768-f or better.

Engel victory 500T

Capable of achieving IT8-IT10 tolerances consistently. With a high-quality mold and stable process control, critical dimensions can reach ±0.05mm to ±0.08mm, heavily dependent on material selection and part geometry.

Engel duo 500T

Part-dependent, but the machine platform enables high precision. Capable of achieving part tolerances of ISO 2768-m (general) or IT8-IT10. Critical dimensions can often be held to ±0.05mm with a robust mold and process control.

Engel duo 650T

Capable of achieving dimensional tolerances of ±0.05mm to ±0.1mm on well-designed parts and high-quality molds. Corresponds to IT Grade 10-12, or tighter on specific features with process optimization. Heavily dependent on part geometry, material stability, and mold quality.

Engel duo 900T

Part-dependent, but capable of achieving ±0.05 mm on critical features with a precision mold and stable process. General part tolerance typically falls within IT10-IT12 or ISO 2768-m.

Engel duo 1100T

Achievable part tolerance of ±0.1mm to ±0.25mm on well-controlled features, generally conforming to IT10-IT12. Final precision is heavily dependent on mold quality, material stability, and process control rather than the machine alone.

Engel duo 1500T

Capable of achieving IT8-IT10 tolerances on well-designed parts. Part-to-part weight repeatability is exceptional, often within ±0.08% under stable process conditions. Final precision is heavily dependent on mold quality, material consistency, and ambient factory conditions.

Engel duo 2300T

Typically achieves IT10-IT12 for general large parts. Capable of holding IT8-IT9 on critical features with a precision mold and a stable process. A general dimensional tolerance of ±0.1 mm to ±0.3 mm is common, depending on part geometry, material, and size.

Engel duo 3200T

General dimensional tolerance: ±0.1mm to ±0.3mm over large spans, often governed by material shrinkage and process control rather than machine limitation. Capable of achieving part-to-part weight consistency within ±0.1% with iQ weight control.

Engel duo 4500T

Machine repeatability enables part dimensional tolerance of ±0.1mm to ±0.3mm over a 1000mm length, highly dependent on mold quality, material thermal stability, and ambient factory conditions. Typically capable of producing parts conforming to DIN 16742 tolerance group TG6-TG8.

Engel duo 5500T

Machine repeatability: ±0.01mm on injection stroke and pressure control. Achievable part-level dimensional tolerance typically conforms to DIN 16742 TG6/TG7, often within ±0.1mm to ±0.3mm over large spans, heavily dependent on mold quality, material selection, and ambient conditions.

Fanuc Roboshot α-SiB 15T

Achievable part tolerance: ±0.015 mm to ±0.05 mm on critical dimensions, highly dependent on material and part geometry. Part-to-part weight repeatability within ±0.03%. Corresponds to IT Grade 7-8.

Fanuc Roboshot α-SiB 30T

Achievable part tolerance of ±0.02mm to ±0.05mm, depending on material and geometry. Machine repeatability is sufficient to maintain a process Cpk > 1.67 on critical dimensions under stable conditions.

Fanuc Roboshot α-SiB 50T

Achievable part tolerances of ±0.01 mm to ±0.03 mm on critical features, contingent on mold quality and material stability. Corresponds to IT Grade 6-8 on molded features.

Fanuc Roboshot α-SiB 100T

Typical achievable part tolerance: ±0.02mm to ±0.08mm, heavily dependent on part geometry, material selection, and mold quality. Capable of producing parts within ISO 20457 Grade 3-4 (Fine to Medium).

Fanuc Roboshot α-SiB 130T

Capable of consistently holding part dimensional tolerances of ±0.025mm (0.001 inches) under stable process conditions. Routinely achieves molding tolerances equivalent to IT Grade 8-10, depending on material and part geometry.

Fanuc Roboshot α-SiB 150T

Achievable part dimensional tolerance of ±0.01 mm to ±0.03 mm on critical features, highly dependent on material, part geometry, and mold quality. Corresponds to IT Grade 7-9.

Fanuc Roboshot α-SiB 220T

Achievable part tolerance: ±0.02mm to ±0.05mm, highly dependent on part geometry, material, and mold quality. Machine positioning repeatability for injection and clamping axes is extremely high, typically ≤ ±0.01mm. This enables a process capability (Cpk) greater than 1.66 on critical dimensions under controlled conditions.

Fanuc Roboshot α-SiB 250T

Capable of achieving part tolerances down to ±0.02mm. Typically holds IT8 - IT10 on critical dimensions, heavily dependent on mold quality, material stability, and process control.

Fanuc Roboshot α-SiB 300T

Typically achieves ISO 2768-m for general features. Critical dimensions are capable of holding ±0.02mm to ±0.05mm under a stable, well-maintained process and a high-quality mold. Corresponds to a repeatable part tolerance grade of IT7-IT9.

Fanuc Roboshot α-SiB 450T

Consistently capable of holding dimensional tolerances of ±0.05mm on well-designed parts and high-quality tooling. Part production typically falls within ISO 20457 molding tolerance grade MT4-MT5 (equivalent to IT9-IT11) with a process capability (Cpk) exceeding 1.67 in stable mass production.

Sumitomo SE-EV-A 50T

Achievable part dimensional tolerance: ±0.025mm to ±0.05mm, highly dependent on part geometry, material selection, and mold quality. Capable of producing parts that meet IT8-IT10 tolerance grades.

Sumitomo SE-EV-A 75T

Capable of consistently holding dimensional tolerances of ±0.025mm to ±0.05mm on critical features. Typically achieves mold tolerance grades of IT8-IT10 depending on material choice and part complexity.

Sumitomo SE-EV-A 100T

Capable of achieving part dimensional tolerances of ±0.025mm to ±0.05mm, highly dependent on part geometry, material selection, and mold quality. Consistently holds process windows that meet or exceed IT Grade 8.

Sumitomo SE-EV-A 130T

Capable of achieving dimensional tolerances of ±0.02 mm to ±0.05 mm on critical features, consistently holding an IT7-IT8 grade with a high-quality mold and stable process control.

Sumitomo SE-EV-A 180T

Capable of achieving dimensional tolerances of ±0.025mm to ±0.05mm on critical features under stable process control (material dependent). Routinely holds a process capability index (Cpk) > 1.33 on key product characteristics (KPCs).

Sumitomo SE-EV-A 220T

Capable of achieving part-to-part dimensional consistency within ±0.01mm to ±0.025mm, highly dependent on material, part geometry, and mold quality. Consistently holds general tolerances equivalent to ISO 2768-f or tighter, often meeting molding-specific standards like DIN 16742 TG3/TG4.

Sumitomo SE-EV-A 280T

Capable of achieving IT7-IT8 tolerance grades on well-designed parts and high-quality tooling. Typical dimensional stability is within ±0.02mm to ±0.05mm.

Sumitomo SE-EV-A 350T

Achievable part tolerance: ±0.05 mm to ±0.1 mm on critical dimensions. Under a controlled process with a high-quality mold, a Cpk (Process Capability Index) of >1.67 is sustainable. This is significantly better than the typical ±0.2mm expected from older hydraulic machines.

Sumitomo SE-EV-A 450T

Can consistently achieve IT7-IT9 tolerance grade. Typical dimensional stability is within ±0.05 mm, highly dependent on part geometry, material selection, and mold quality.

Sumitomo SE-EV-A 500T

Part and material dependent, but capable of achieving DIN 16742 TG4-TG6. With a high-quality mold and stable process, dimensional tolerances of ±0.05mm on critical features are repeatable.

LK Potenza 130T

Capable of achieving IT8-IT10 on part dimensions. Typically holds tolerances of ±0.05mm to ±0.1mm, highly dependent on mold quality, material selection (e.g., PBT-GF30 vs. PP), and part geometry.

LK Potenza 200T

Capable of producing parts that meet ISO 2768-m standards. For well-designed parts and high-quality molds, critical dimensions can consistently hold tolerances of ±0.05mm to ±0.10mm, contingent on material and geometry.

LK Potenza 250T

Achievable part tolerance typically ranges from ±0.05mm to ±0.15mm, highly dependent on mold quality, material selection, and part geometry. In a stable process, it consistently holds a Cpk (Process Capability Index) greater than 1.33 on critical dimensions.

LK Potenza 320T

Typical achievable part tolerance: ±0.05mm to ±0.15mm, highly dependent on mold quality, material selection, and part geometry. Generally produces parts conforming to ISO 2768-m (medium).

LK Potenza 400T

Part dimensional tolerance achievable: IT8-IT10, depending heavily on part geometry, material, and mold quality. Machine position repeatability for key axes (injection, clamping) is typically within ±0.1mm, ensuring high shot-to-shot consistency.

LK Potenza 500T

Capable of achieving IT8-IT10 on part dimensions under a stable process. Shot-to-shot weight consistency is typically maintained within ±0.1%. Final part tolerance is heavily dependent on mold quality, material drying, and ambient factory conditions.

LK Potenza 600T

Achievable part tolerance is highly material and geometry dependent. Generally capable of producing parts within ISO 2768-m (medium). For critical dimensions on stable materials (e.g., PC, ABS), ±0.05mm to ±0.1mm is achievable with a high-quality mold and stable process control. Corresponds to IT Grade 11-13 for most features.

LK Forza 450T

Achieves typical part tolerances of ISO 2768-m (e.g., ±0.1mm to ±0.3mm depending on dimension). With a well-designed mold and stable process control (RJG or similar), critical functional dimensions can hold ±0.05mm. Overall process capability falls within the IT10-IT12 tolerance grade range.

LK Forza 550T

Part-level precision is highly dependent on mold quality, material stability, and process control. With a well-designed process, this machine is capable of holding part tolerances within ISO 2768-m (medium) or achieving dimensional repeatability of ±0.1% of nominal dimension, typically falling within a ±0.08mm to ±0.20mm range for most engineering-grade resins.

LK Forza 800T

Achievable part tolerance is highly dependent on material, part geometry, and mold quality. For a well-designed part and a CMM-verified tool, it consistently holds general tolerances of DIN 16742 TG6. Critical functional dimensions can often be held within ±0.15mm to ±0.25mm over 500mm.

LK Forza 1000T

Capable of achieving IT11-IT13 (DIN ISO 286) part tolerances, typically conforming to DIN 16742 TG6-TG7 for general engineering plastics with a well-maintained mold and a stable process.

LK Forza 1300T

Achievable part tolerance typically falls within ±0.1mm to ±0.3mm, heavily dependent on part geometry, material selection, and mold quality. Machine process repeatability is high, conforming to standards like ISO 20457.

LK Forza 1600T

Typically achieves DIN 16742 TG7-TG8 or part tolerances of ±0.2mm over large dimensions. For well-designed parts with stable processes, critical features can meet IT11 grade. Platen parallelism is maintained within 0.15mm.

LK Forza 2000T

Generally capable of achieving IT11-IT13 tolerance grades on large parts, highly dependent on mold quality and material stability. Positional repeatability of platens is typically within ±0.1 mm under load.

LK Forza 3000T

Capable of achieving part tolerances of ±0.1mm to ±0.3mm depending on material and geometry. Delivers exceptional shot-to-shot weight consistency (<0.1%) under stable process conditions, critical for Cpk/Ppk requirements in automotive manufacturing.

LK Forza 4000T

Part-dependent, but the machine's repeatability can support general purpose tolerances of ISO 20457 JS-12 / DIN 16742 TG6. For well-designed parts and high-quality molds, achieving ±0.1% of the nominal dimension is feasible.

LK Forza 5000T

Typical Part Tolerance: ±0.15mm to ±0.30mm over 100mm, highly dependent on part geometry, material selection, and mold quality. Capable of achieving DIN 16742 TG6-TG7 with a precision mold and stable process control.

LK Forza 7000T

Part tolerance typically achieves ISO 2768-m. Critical dimensions can be held to ±0.2mm to ±0.5mm over a 1500mm span, highly dependent on part geometry, material selection (especially filler content), and mold cooling design.

LK Eletta 100T

Capable of holding dimensional tolerances of ±0.05 mm on critical features, consistently meeting part quality standards equivalent to DIN 16742 TG5-TG6, assuming a high-precision mold and stable process.

LK Eletta 150T

Achieves dimensional tolerances of ±0.05 mm on well-designed parts and molds. Capable of producing parts within an IT8 - IT10 tolerance grade consistently. With process optimization and a high-quality mold, achieving IT7 on critical dimensions is feasible.

LK Eletta 200T

Achievable part tolerance: ±0.05 mm (highly dependent on mold quality, material, and part geometry). Machine positioning repeatability for clamp and injection axes is typically ≤ ±0.01 mm, enabling IT8-IT10 part tolerances under controlled conditions.

LK Eletta 300T

Consistently capable of holding dimensional tolerances of ±0.05 mm to ±0.1 mm on well-designed parts and production-grade molds. Achieves CT7-CT8 grade according to DIN 16742. Shot-to-shot weight repeatability is typically within ±0.1% due to the closed-loop servo control.

Yizumi UN-V5 100T

Achievable part tolerance: ±0.05 mm to ±0.15 mm. The final precision is heavily dependent on mold quality, material stability, and process control, but the machine's repeatability supports production within the IT10-IT12 tolerance range.

Yizumi UN-V5 160T

Achieves dimensional tolerances of ±0.05mm to ±0.1mm on well-designed parts and quality tooling. Corresponds to ISO 2768-m for general dimensions. Shot-to-shot weight repeatability is typically within ±0.15%.

Yizumi UN-V5 200T

Achievable part tolerance of ±0.05mm to ±0.1mm (equivalent to IT10-IT12). Final precision is highly dependent on mold quality, material stability, and process control, which this machine's stability enables.

Yizumi UN-V5 260T

Achievable part tolerance typically ranges from ±0.05 mm to ±0.1 mm, often meeting dimensional requirements for IT Grade 10-12. Final precision is heavily dependent on mold quality, material stability, and process parameter control, not just the machine itself.

Yizumi UN-V5 320T

Achievable part tolerance: ±0.05mm to ±0.20mm. Final precision is heavily dependent on mold quality, material selection (especially shrinkage characteristics), and process stability. Capable of producing parts to an ISO 2768-m (medium) standard for general dimensions.

Yizumi UN-V5 400T

Typical part tolerance: ±0.10 mm to ±0.25 mm (approximates to ISO 2768-m/k). Precision is highly dependent on mold quality, material stability, and process control.

Yizumi UN-V5 500T

General part tolerance: ±0.1mm to ±0.2mm (conforming to ISO 2768-m). Capable of achieving dimensional process capability (Cpk > 1.33) at an IT Grade of IT10-IT12 under a stable, optimized process.

Yizumi UN-V5 650T

Typically achieves ISO 2768-m for general parts. Capable of reaching IT8 - IT10 on critical dimensions with a high-quality mold and stable process control.

Yizumi UN-V5 800T

Typically achieves dimensional tolerances of ±0.1mm to ±0.3mm for features under 100mm, or ±0.15% of nominal for larger dimensions. Capable of meeting plastic tolerance standard DIN 16742-TG6 with a high-quality mold and stable process control.

Yizumi UN-V5 1000T

Achievable part tolerance typically falls within IT11-IT13 (ISO 286). With a high-precision mold, stable process control, and engineering-grade polymers, critical dimensions can be held to ±0.10 mm to ±0.25 mm over 100 mm, depending heavily on part geometry and material selection.

Chen Hsong JM Mark 6 100T

Consistently produces parts to IT Grade IT10-IT12. Achievable dimensional tolerance is typically ±0.05mm to ±0.15mm, highly dependent on part geometry, mold quality, and material selection (e.g., stable engineering plastics like PC vs. commodity plastics like PP).

Chen Hsong JM Mark 6 128T

Part dimensional repeatability typically falls within ±0.05mm to ±0.1mm. The final part tolerance is highly dependent on mold quality and material stability, but the machine can consistently support production achieving general tolerances of ISO 2768-m or part-specific IT Grades of IT10-IT12.

Chen Hsong JM Mark 6 168T

Achievable part tolerance of ±0.05 mm to ±0.1 mm on critical dimensions, depending on material and mold quality. Generally capable of producing parts conforming to ISO 2768-m (medium).

Chen Hsong JM Mark 6 208T

Achieves typical part dimensional tolerances of ±0.1mm. High process repeatability (shot-to-shot weight consistency <0.2%) allows for achieving a Cpk > 1.33 on well-designed molds and stable materials.

Chen Hsong JM Mark 6 268T

Typical part tolerance: ISO 2768-m. Can achieve ±0.1 mm on well-designed features. Critical dimensions may reach ±0.05 mm with rigorous process control, high-quality tooling, and a stable thermal environment.

Chen Hsong JM Mark 6 328T

Part dimensional tolerance typically falls within ISO 2768-m. For well-designed parts and high-quality molds, achieving ±0.1mm is standard. With stringent process control and material stabilization, critical dimensions can be held to ±0.05mm.

Chen Hsong JM Mark 6 408T

Achievable part tolerance of ±0.05mm to ±0.1mm on critical feature dimensions under stable process control. Overall part geometry typically conforms to ISO 2768-m. Final precision is heavily dependent on mold quality, material consistency, and ambient factory conditions.

Chen Hsong JM Mark 6 488T

Typical molded part tolerance: ±0.10mm to ±0.25mm. This corresponds to a process capability grade of approximately IT11-IT13, highly dependent on mold quality, material stability, and process control.

Chen Hsong JM Mark 6 568T

Achievable part tolerance of ±0.1 mm to ±0.2 mm on general dimensions (based on a 100mm feature). Capable of reaching ±0.05 mm on critical features with a high-quality mold, stable process control, and a suitable engineering-grade polymer.

Chen Hsong JM Mark 6 650T

Typically meets ISO 2768-m for general purpose molding. Can achieve dimensional tolerances of ±0.05mm to ±0.1mm on well-designed parts with a high-quality mold, stable process control, and consistent material.

EOS M 290

As-built dimensional accuracy is typically within ±0.1mm for general features. Critical feature accuracy can achieve ±0.05mm after process optimization. Post-machining is required for tolerances tighter than IT9.

Stratasys F900

Achievable accuracy is typically ±0.089 mm or ±0.0015 mm/mm (±0.0035 in. or ±0.0015 in./in.), whichever is greater. Part-to-part repeatability is high due to the thermally stable build environment.

Formlabs Form 3L

Typical dimensional accuracy: ±0.2% (with a lower limit of ±0.100 mm). Precision is highly dependent on part geometry, orientation, material properties, and post-curing process. For critical features under 50mm, accuracies of ±0.05mm to ±0.15mm are achievable with proper process control.

HP Jet Fusion 5210

Typically meets ISO 2768-m for general tolerances. Part accuracy is generally within ±0.2 mm for dimensions up to 100 mm, and ±0.2% for dimensions larger than 100 mm. Repeatability is high due to advanced thermal control.

Carbon M2

Typically achieves ±0.1 mm for features under 100mm, plus an additional ±0.001 mm/mm for larger dimensions. Part-to-part repeatability is high due to tight process control, often within ±0.05 mm for small, well-designed components.

Arburg Allrounder 470 A

Capable of holding dimensional tolerances of ±0.02mm to ±0.05mm on critical features under a stable process with a high-quality mold. General part tolerance often conforms to ISO 20457 CT5-CT7.

Fanuc Roboshot Alpha-S150iB

Capable of consistently holding dimensional tolerances of ±0.025mm to ±0.05mm on critical features. Can achieve IT7-IT8 grade tolerances under stable process control. Shot-to-shot weight repeatability within ±0.03%.

Engel Victory 120

High precision. Capable of achieving dimensional tolerances of ±0.025 mm to ±0.1 mm, highly dependent on material choice and part geometry. Shot weight repeatability is consistently below 0.1% due to advanced process controls.

Makino V33i

Positioning Accuracy: ±0.003 mm. Repeatability: ±0.0015 mm. Achievable part tolerance is consistently within the IT5 - IT6 grade, capable of holding features to ±0.005 mm under thermally-controlled production conditions.

Sodick ALC600G

Typical achievable tolerance: ±0.002mm to ±0.005mm. Conforms to dimensional accuracy in the IT5-IT6 grade range.

Haas VF-2SS

Typically holds ±0.05mm (ISO 2768-m) for general features. Capable of achieving ±0.02mm on critical dimensions under thermally stable conditions and with proper process control (approaching IT7).

Mazak Integrex i-200S

Capable of achieving IT6 grade tolerances. Positional accuracy typically within ±0.005mm and repeatability within ±0.002mm under thermally stable conditions.

Trumpf TruLaser 3030

Achievable tolerance of ±0.1 mm on most geometries, conforming to ISO 2768-m. Edge quality and feature precision can meet requirements within tolerance class ISO 9013-441. Kerf width control allows for fine features that can be characterized around IT9.

Amada HG 1303

Angular Accuracy: ±0.25° (with Bi-S angle sensor). Flange Dimension Tolerance: Conforms to ISO 2768-m, capable of achieving ±0.1mm on well-controlled processes. Ram positional repeatability is within ±1μm.

Buhler Carat 440

As-cast tolerances typically conform to ISO 8062-3 DCTG 8-10. With a stable process and high-quality tooling, critical features can approach DCTG 6-7. Subsequent CNC machining is required for tolerances tighter than ±0.15mm.

Farsoon HT430P

±0.15 mm or ±0.15% (whichever is greater). Consistently meets ISO 2768-m for linear dimensions when thermally stabilized.

Farsoon Flight HT403P

±0.10 mm for features < 50mm. Achieves superior fine-feature resolution due to the ultra-fine fiber laser spot size.

TPM3D P360

General tolerance of ±0.2 mm. Reliable for standard commercial plastics but less consistent on high-aspect-ratio thin walls.

TPM3D S320HT

±0.15 mm. Final precision is heavily dependent on specific material shrinkage rates (e.g., PEEK requires unique scaling factors).

Eplus3D EP-P420

±0.15 mm up to 100mm, then ±0.15%. Edge-to-edge consistency is high due to advanced optics.