In CNC machining workshops—whether producing automotive engine components or medical device parts—the working hours of CNC machining directly affect production schedules, labor costs, and order delivery times. This key metric isn’t random; it depends on a mix of product design, equipment performance, process strategies, e dettagli operativi. Questo articolo analizza i principali fattori che influenzano, metodi di valutazione passo passo, ottimizzazioni di scenari tipici, e soluzioni a malintesi comuni, aiutandoti a calcolare con precisione e a ridurre in modo efficiente le ore di lavorazione.
1. Quali sono i principali fattori che influenzano l'orario di lavoro della lavorazione CNC?
CNC machining hours are shaped by four interconnected categories, each with specific sub-factors that can extend or shorten cycle times. Below is a detailed breakdown with quantifiable impacts:
1.1 Caratteristiche di progettazione del prodotto (Conto per 30-40% delle ore totali)
Design complexity directly increases tool path difficulty and processing steps.
| Design Factor | Impact on Working Hours | Esempio nel mondo reale | Optimization Tip |
| Shape Complexity | Non-standard surfaces, thin-walled structures, or deep narrow grooves add 20-50% to hours vs. simple blocks | Aviation supports with complex ribs need 5-axis linkage machining (8-12 hours/part) contro. 2-3 hours for simple brackets | Simplify non-critical contours; Avoid unnecessary deep grooves (>10x diameter) |
| Precisione & Surface Requirements | High-precision features (PER ESEMPIO., IT6-level holes) require 2-3x more time for semi-finishing + Test | Mirror-polished mold inserts need reduced feed rates (50-100mm/min) contro. 300-500mm/min for Ra 6.3μm surfaces | Use multi-step finishing (rough → semi-finish → finish) instead of repeated corrections |
| Tipo di materiale | Difficult-to-cut materials slow processing by 30-60% contro. easy-to-cut metals | Acciaio inossidabile (304) requires 80-120m/min cutting speed vs. 300-500m/min per leghe di alluminio | Choose carbide tools for steel; Utilizzare acciaio ad alta velocità (HSS) only for low-volume soft metal parts |
| Feature Quantity & Disposizione | Dense small holes/threads add 15-30% time due to tool changes | A 50mm×50mm aluminum plate with 20 M3 threads needs 40+ minuti (contro. 15 minutes for 5 Discussioni) | Group same-diameter features to reduce tool changes; Use multi-spindle heads for hole arrays |
1.2 Macchine utensili & Condizioni di processo (Conto per 25-35% delle ore totali)
Equipment capabilities and setup efficiency determine how quickly parts can be machined.
| Condition Factor | Impact on Working Hours | Parametri chiave | Cost-Benefit Note |
| Prestazioni dell'attrezzatura | High-rigidity machines cut roughing time by 20-30% contro. older models | A new vertical machining center (VMC) with 12,000rpm spindle finishes a steel block in 4 ore vs. 6 hours on a 8,000rpm VMC | Upgrading spindles (from 8k to 15k rpm) salva 15-25% on thin-walled part hours |
| Tool Configuration | Insufficient tool magazine capacity adds 10-20% manual tool change time | A 24-tool magazine handles a 5-operation part in 3 ore vs. 4 hours with an 8-tool magazine (esigenze 2 manual changes) | Prioritize tools for high-frequency operations; Use tool presetters to cut setup time |
| Clamp System | Quick-clamp tools reduce downtime by 40-60% contro. manual alignment | A hydraulic vise clamps a part in 2 minutes vs. 10 minutes for manual bolt clamping | Adopt zero-point positioning systems for batch production (repeat setup <1 minuto) |
| Raffreddamento & Lubrificazione | Poor cooling adds 15-25% time due to sticky chips or tool wear | Dry cutting aluminum causes 2-3x more tool changes (each taking 5-10 minuti) contro. high-pressure mist cooling | Use water-soluble coolants for steel; Air-oil mist for aluminum (reduces chip cleanup) |
1.3 Procedure & Strategie operative (Conto per 20-25% delle ore totali)
Smart process planning eliminates redundant steps and optimizes tool paths.
| Strategy Factor | Impact on Working Hours | Esempio pratico | Errore comune |
| Tool Path Planning | Ring cutting is 20-30% faster than row cutting for large surfaces | A 200mm×200mm aluminum plate takes 30 minutes with ring cutting vs. 45 minutes with row cutting | Avoid Z-axis straight down (causes tool shock); Use spiral down for deep cavities |
| Margin Allocation | Overly large roughing margins (PER ESEMPIO., >5mm) double finishing time | A steel part with 3mm roughing margin takes 2 hours to finish vs. 1 hour with 1.5mm margin | Follow “rough 70-80% di materiale, finish 20-30%” for balance |
| Exception Handling | Unplanned downtime (PER ESEMPIO., rottura degli utensili) can take up 10-15% of total hours | A missed emergency retraction space causes a tool strike, Aggiunta 2-3 hours of repair time | Reserve 5-10mm retraction space; Use collision detection software |
2. Come valutare passo dopo passo l'orario di lavoro della lavorazione CNC?
Accurate hour evaluation requires combining theoretical calculations with practical measurements. Below is a 3-stage method to avoid guesswork:
2.1 Palcoscenico 1: Raccolta dati di base (Getta le fondamenta)
Gather key information to set calculation parameters.
| Data Type | Collection Method | Critical Output |
| Drawing Analysis | Review tolerance zones, shape/position tolerances, e requisiti di trattamento termico | Divide processing into stages (PER ESEMPIO., pre-heat treatment roughing → post-heat treatment finishing) |
| Equipment Matching | Select machine tools by part size (PER ESEMPIO., gantry for >1m parts, VMC for <1m parts) | Calculate non-cutting time (PER ESEMPIO., gantry machines move at 10m/min vs. 20m/min for small VMCs) |
| Tool List Preparation | List tool type, diametro (D), and number of teeth; Calculate cutting speed (Vc) | Use formula: Velocità del fuso (S) = (Vc×1000)/(π×D) (PER ESEMPIO., Vc=300m/min for aluminum, D=10mm → S=9549rpm) |
2.2 Palcoscenico 2: Segmented Timing & Verifica (Validates Theoretical Data)
Test and adjust calculations with real machine runs.
- Empty Running Test: Lock the spindle and run the program. Record:
- Axis movement time (PER ESEMPIO., X/Y/Z axis travel time between features);
- Rapid positioning frequency (each positioning adds 2-5 Secondi);
- Redundant empty strokes (PER ESEMPIO., unnecessary tool returns to home).
Risultato: Eliminate 5-10% of non-cutting time by optimizing tool path order.
- First Piece Trial Cutting: Run actual machining and log:
- Start/end time for each process (ruvido, semifinishing, finitura);
- Tool change intervals (each manual change takes 3-8 minuti, automatic takes 10-30 Secondi);
- Spindle start/stop delays (aggiungere 2-3 secondi per ciclo).
Risultato: Adjust theoretical parameters (PER ESEMPIO., reduce feed rate if tool vibration occurs).
- Abnormal Time Statistics: Track non-value-added time:
- Tool replacement (5-15 minutes per broken tool);
- Program debugging (10-20 minutes for complex parts);
- Measurement waiting (5-10 minutes for CMM checks).
Risultato: These times often account for 10-20% of total hours—plan buffers accordingly.
2.3 Palcoscenico 3: Experience Coefficient Modification (Ensures Practicality)
Adjust theoretical hours to account for real-world variables.
| Modification Factor | Adjustment Ratio | Motivo |
| Safety Buffering | Aggiungere 5-15% to theoretical hours | Copes with material hardness fluctuations (PER ESEMPIO., ±10% in aluminum alloy hardness) or tool wear |
| Batch Effect | First part: +30-50% (includes tool setting/program verification); Subsequent parts: -10-20% | The first part of a batch takes 4 ore vs. 2.5-3 hours for parts 2-100 |
| Environmental Compensation | Aggiungere 5-10% in extreme temperatures (>30°C or <10° C.) | Shop floor heat causes machine thermal deformation, requiring more in-line measurements |
3. How to Optimize Working Hours in Typical CNC Machining Scenarios?
Different part types have unique time-consuming pain points—targeted optimizations deliver quick results. Below are two common scenarios:
3.1 Scenario 1: Aluminum Alloy Gearbox Housing
- Caratteristiche: Thin-walled cavity (2-3spessore mm) + 4 mounting surfaces + 12 M8 threaded holes.
- Key Time-Consuming Points:
- Roughing uses a large-diameter face mill (φ50mm) but requires 8-10 passes to remove material;
- Finishing needs a long-handled small-diameter tool (φ6mm) to clean cavity roots (slow feed rate: 80-120mm/min);
- Threaded holes have aluminum chip clogging, richiedere 3-5 blows per hole.
- Optimization Results:
| Optimization Measure | Tempo risparmiato | New Total Hours |
| Switch to honeycomb lightweight cutterhead (φ63mm) | 20-25% (reduces passes to 5-6) | Da 5 ore a 4 ore |
| Pre-coat tool with anti-stick coating (PER ESEMPIO., Tialn) | 15-20% (speeds root cleaning to 150-200mm/min) | Da 4 ore a 3.3 ore |
| Use air blow + vacuum suction during threading | 10-15% (eliminates re-blowing) | Da 3.3 ore a 2.9 ore |
3.2 Scenario 2: Stainless Steel Medical Surgical Instrument
- Caratteristiche: Micron-level tolerance (± 0,005 mm) + mirror surface (Ra ≤0.2μm) + complex curve contours.
- Key Time-Consuming Points:
- Engraving complex curves at slow speed (50-80mm/min) to avoid surface scratches;
- Manual grinding removes tool marks (prende 30-45 minuti per parte);
- 3D inspection (CMM) is done 3x per part (totale 20-30 minuti).
- Optimization Results:
| Optimization Measure | Tempo risparmiato | New Total Hours |
| Introduce ultrasound-assisted cutting (20-50kHz vibration) | 30-40% (speeds engraving to 120-150mm/min) | Da 8 ore a 6 ore |
| Use diamond-plated tools (Ra ≤0,1μm) for one-pass finishing | 40-50% (eliminates manual grinding) | Da 6 ore a 4 ore |
| Combine in-line laser measurement with final CMM check | 50-60% (reduces inspection to 10-12 minuti) | Da 4 ore a 3.7 ore |
4. What Are Common Misunderstandings About CNC Machining Working Hours?
Misconceptions lead to inaccurate planning and wasted resources. Below are two key myths and their solutions:
| Misunderstanding | Reality | Practical Countermeasure |
| “Same drawing = same working hours” | Equipment generation differences matter: Old CNC systems (≥10 years) process complex G-code 20-30% slower than new systems (≤5 years) | Establish an enterprise-level database: Store hours by material, equipment model, e processo; Update monthly |
| “Ignore non-cutting time” | Non-cutting time (Cambiamenti dello strumento, tool setting, misurazione) accounts for 25-40% of total hours (non 5-10% as assumed) | Use automatic tool changers (ATCs) per >5-parti degli strumenti; Adopt quick-setup fixtures (PER ESEMPIO., zero-point systems) |
5. Yigu Technology’s Perspective on Working Hours of CNC Machining
Alla tecnologia Yigu, vediamo working hours of CNC machining as a “mirror of process efficiency”—it reflects not just speed, but also the rationality of design, attrezzatura, e operazioni. I nostri dati mostrano 60% of hour waste comes from “hidden inefficiencies” (PER ESEMPIO., poor tool path planning, redundant inspections) rather than equipment speed limits.
We recommend a “digital-driven optimization” approach: For batch parts, we use CAM software to simulate tool paths (taglio 10-15% of empty time) and MES systems to track real-time machine data; Per parti complesse, we apply machine learning to historical data (PER ESEMPIO., 10,000+ part records) to auto-recommend optimal parameters (PER ESEMPIO., velocità di alimentazione, velocità del fuso). By combining standardized processes (for similar parts) and intelligent monitoring, we help clients reduce average working hours by 20-30% while maintaining quality.
6. Domande frequenti: Common Questions About Working Hours of CNC Machining
Q1: Can I use the same hour calculation formula for different materials?
NO. The core formula (cutting time = material volume / (feed rate × spindle speed × tool efficiency)) must be adjusted for material hardness. Per esempio, acciaio inossidabile (304) ha bisogno di un 0.6-0.8 efficiency coefficient vs. 1.0 for aluminum alloy—ignoring this leads to 20-40% underestimation of hours.
Q2: How much time does an automatic tool changer (ATC) save compared to manual tool changes?
An ATC takes 10-30 seconds per tool change vs. 3-8 minutes for manual changes. For a part needing 8 utensili, this saves 20-60 minutes per part—critical for batches >50 parti. Per piccoli lotti (<10 parti), manual changes may be cheaper (no ATC setup time).
Q3: Why do hours increase for parts with thin walls (<3mm) even if they’re simple in shape?
Thin walls require reduced cutting force (to avoid deformation), which means slower feed rates (50-70% of standard) and smaller depth of cut (0.1-0.3mm vs. 0.5-1mm). Per esempio, a 2mm aluminum wall takes 40 minutes to finish vs. 25 minutes for a 5mm wall—even with the same area.