Recherche

How to Choose a Motor for AGV Applications: Complete Selection Guide

How to Choose a Motor for AGV Applications

How to Choose a Motor for AGV Applications: Complete Selection Guide — Types, Torque Calculation & Caractéristiques

Choisir le bon motor for AGV (Véhicule à guidage automatisé) systems is one of the most consequential design decisions in mobile robotics. The drive motor directly determines traction performance, autonomie de la batterie, précision de positionnement, comportement thermique, and maintenance intervals — all of which feed into the total cost of ownership over a multi-year deployment.

This guide consolidates selection methodology used by AGV/AMR manufacturers worldwide. It covers motor type comparison, torque calculation formulas, gearbox matching, payload-based sizing, protection environnementale, and controller integration — with reference data from industrial motor platforms.

What Is an AGV Motor?

An AGV motor is an electric motor that provides propulsion, pilotage, and lifting force for automated guided vehicles and autonomous mobile robots. Unlike industrial motors that run at fixed speeds on mains power, AGV motors operate from battery voltage (typically 24V or 48V DC), must handle frequent start-stop cycles, and require closed-loop feedback for positioning accuracy.

The motor works as part of an integrated drive system that includes a gearbox, encodeur, frein, and motor controller. Each component must be matched to the vehicle’s payload, wheel diameter, target speed, slope requirements, and operating environment. A mismatched motor — even one with adequate rated power — can cause overheating, wheel slip, positioning drift, or premature bearing failure.

Key Functions of an AGV Motor

FonctionDescriptionMotor Requirement
Traction / ConduirePropels the vehicle forward, en arrière, and up slopesHigh continuous torque at low RPM; adequate peak torque for acceleration
PilotageControls direction via differential speed or articulated steeringPrecise speed matching between left/right motors; responsive torque control
Lifting / ForkRaises and lowers loads on forklift AGVsHigh holding torque; integrated brake for power-off safety
PositionnementStops the vehicle at docking stations with repeatable accuracyClosed-loop encoder feedback; low-speed smoothness

AGV Motor Types: BLDC, Servomoteur, Pas à pas, and Brushed DC

Four motor technologies compete in the AGV drive space. Each has distinct efficiency, coût, entretien, and control characteristics that make it suitable for specific payload classes and precision requirements.

1. CC sans balais (BLDC) Motor — The Dominant Choice

BLDC motors have become the mainstream drive solution for AGVs and AMRs due to their combination of high efficiency (85–92%), longue durée de vie (10,000–20,000+ hours), and low acoustic noise. They use electronic commutation instead of mechanical brushes, eliminating the primary wear component found in brushed motors.

For AGV applications, BLDC motors are typically paired with planetary gearboxes to multiply torque at the wheel. The integrated BLDC planetary gear motor — where motor and gearbox are supplied as a single unit — is the most common configuration for warehouse AMRs and logistics AGVs in the 50–500 kg payload range.

Key advantages for AGV deployment:

  • Efficacité de la batterie: 85–92% efficiency vs. 60–75% for brushed DC, directly extending operating time per charge
  • Maintenance-free operation: No brush replacement; bearing life is the limiting factor
  • Faible bruit: 48–55 dB typical, suitable for hospital and office environments
  • Closed-loop control: Compatible with Hall sensors and encoders for FOC (Contrôle orienté sur le terrain)
  • Gestion thermique: Lower resistive losses reduce heat generation in enclosed chassis
  • Compact form factor: High torque density in 42mm, 56millimètre, and 80mm frame sizes

For BLDC motor product specifications and configurations, voir notre BLDC motor product page.

2. DC Servo Motor — For Precision Applications

DC servo motors use closed-loop control with high-resolution encoder feedback to achieve millimeter-level positioning accuracy (repeatable error < ±0.1 mm with 17-bit absolute encoders). They offer 300% instantaneous overload capacity and superior dynamic response compared to standard BLDC motors.

Servo motors are typically specified for heavy-load AGVs (>1 ton payload), high-speed precision docking (≥2 m/s with ±5 mm stopping accuracy), and complex path control scenarios such as S-curve obstacle avoidance or synchronized multi-axis movement.

3. Stepper Motor — For Light-Load Precision

Stepper motors provide open-loop position control without encoder feedback, making them cost-effective for light-load AGVs and AGCs (Automated Guided Carts) where positioning accuracy requirements are moderate (±1–5 mm). They deliver high holding torque at zero speed and simple integration with stepper drivers.

Cependant, steppers lose torque rapidly at higher speeds and are susceptible to step loss under sudden load changes. Closed-loop stepper variants (hybrid steppers with encoder feedback) address these limitations for applications requiring higher reliability. For a detailed comparison of servo and stepper motor characteristics, voir notre Servo Motor vs Stepper Motor guide.

4. Brushed DC Motor — The Legacy Option

Brushed DC motors remain in use for low-cost AGV platforms due to their simple two-wire control and low upfront cost (30–50% cheaper than BLDC). They provide high starting torque and respond well to PWM speed control.

The trade-offs are significant: brush wear limits service life to 2,000–5,000 hours, efficiency is 60–75%, and brush arcing generates electrical noise and acoustic noise. For AGV fleets operating multiple shifts, the maintenance cost of brush replacement quickly exceeds the initial savings.

Motor Type Comparison Table

ParamètreMoteur BLDCServomoteur CCMoteur pas à pasMoteur à courant continu brossé
Efficacité85–92%90–95%70–80%60–75%
Durée de vie (heures)10,000–20,000+10,000–20,000+10,000+2,000–5,000
Précision de positionnement±0.5–2 mm (with encoder)±0.1 mm±1–5 mm (boucle ouverte)±5–10 mm
Plage de vitesseLarge (0–6,000+ RPM)Very wide (0–10,000+ RPM)Narrow (torque drops above 1,000 RPM)Large (0–5,000 RPM)
Niveau de bruit48–55 dB50–60 dB55–65 dB60–70dB
Coût (relative)MoyenHautLow–MediumFaible
EntretienAucun (bearing-limited)Aucun (bearing-limited)AucunBrush replacement
Overload Capacity150–200%300%Non recommandé200–300%
Typical Voltage24V / 48V48V / 72V12V / 24V24V / 48V
Best AGV ApplicationWarehouse AMR, logistics AGV (50–500 kg)Forklift AGV, heavy-load (>1 ton)AGC, light cart (<100 kg)Low-cost platforms, legacy systems

Torque Calculation for AGV Drive Motors

Torque calculation is the foundation of AGV motor selection. Estimating torque from catalog data without calculating actual wheel-side requirements leads to either undersized motors (surchauffe, stall) or oversized motors (wasted battery capacity, coût plus élevé).

Wheel Torque Formula

The required torque at each drive wheel is the sum of rolling resistance torque and acceleration torque:

Twheel = (m × g × μ × r) + (m × a × r)

SymbolParamètreTypical ValueUnité
mTotal mass (vehicle + maximum payload)50–2,000kg
gGravitational acceleration9.81m/s²
μRolling friction coefficient0.01–0.03 (smooth floor)dimensionless
rWheel radius0.05–0.15m
unTarget acceleration0.3–1.0m/s²

Worked Example: 150 kg Warehouse AMR

Pour un 150 kg AMR with 75 mm wheel radius (150 mm de diamètre), smooth warehouse floor (μ = 0.02), et 0.5 m/s² acceleration:

  • Rolling resistance torque: 150 × 9.81 × 0.02 × 0.075 = 2.21 N·m
  • Acceleration torque: 150 × 0.5 × 0.075 = 5.63 N·m
  • Total wheel torque (two wheels): 7.84 N·m
  • Per motor (dual drive): 3.92 N·m
  • With safety factor 1.5–2.0×: 5.9–7.8 N·m per motor

Torque Requirements by Operating Scenario

AGV drive motors face different torque demands depending on the maneuver being performed. Data from automotive manufacturing logistics applications shows the following patterns for a two-wheel differential AGV:

ScénarioTorque DemandKey Consideration
Linear travel~30 N·m (example: heavy AGV)Consistent torque to overcome friction; stability for constant speed
Arc turning36.8 N·m / 9.9 N·m (inner/outer wheel)Uneven load distribution; independent per-wheel torque control required
Zero-turn (pivot)~16.2 N·m per wheelHigh resistance; motor must overcome tire scrub torque
Slope climbing (5°)1.5–2× flat-ground torqueMust verify thermal margin for sustained climb
Emergency brakingPeak regenerative torqueBrake resistor or regenerative capacity must absorb energy

The safety factor of 1.5–2.0× applied to calculated torque accounts for floor irregularities, wheel wear, payload distribution asymmetry, and transient acceleration peaks. For slope-climbing AGVs, verify that the motor can sustain the higher torque without exceeding its thermal limit over the expected climb duration.

Voltage and Power Specifications

AGV motors operate on DC battery power, with 24V and 48V being the dominant voltage platforms. The choice of voltage affects motor current draw, wiring gauge, controller sizing, and battery configuration.

Voltage Platform Comparison

Paramètre24Système V48Système V
Typical payload50–300 kg300–2,000+ kg
Motor power range50–400W400W–2kW+
Current at rated power (example)~17A at 400W~17A at 800W
Wiring gauge10–12 AWG14–16 AWG
Battery configuration2S LiFePO₄ / 12S Li-ion4S LiFePO₄ / 24S Li-ion
Safety classificationSELV (Safe Extra Low Voltage)Approaching ELV limit
Idéal pourCompact AMRs, light AGCsForklift AGVs, heavy platform AGVs

Power Sizing by Load Class

Payload ClassRecommended Motor PowerTensionMotor Frame Size
Light (< 300 kg)150–400W24V42mm BLDC
Moyen (300–800 kg)400W–1kW48V56mm BLDC
Heavy (800–1,500 kg)1–1.5kW48V80mm BLDC or servo
Very heavy (> 1,500 kg)≥1.5kW servo48V / 72VServo with planetary gearbox

When sizing motor power, verify that the motor’s continuous torque rating (not just peak torque) exceeds the calculated RMS torque over the duty cycle. Peak torque covers acceleration transients; continuous torque determines whether the motor can sustain operation without thermal shutdown.

Gearbox Selection for AGV Motors

The gearbox multiplies motor torque and reduces output speed to match wheel RPM requirements. For a motor spinning at 3,000 RPM and a wheel needing 100 RPM, un 30:1 reduction ratio is required. The gearbox type directly affects torque density, contrecoup, bruit, et le coût.

Gearbox Type Comparison for AGV Applications

ParamètreRéducteur planétaireBoîte de vitesses droiteHarmonic Drive
Densité de coupleHautLow–MediumTrès élevé
Contrecoup5–15 arc-min15–30 arc-min< 1 arc-min
Niveau de bruitFaible (helical gears)Plus haut (straight teeth)Très faible
Efficacité90–95%92–96%80–85%
Coût (relative)0.5–0.8×4–6×
Durée de vie10,000–20,000 h5,000–10,000 h8,000–15,000 h
Typical ratio range3:1 – 100:13:1 – 50:150:1 – 300:1
Best AGV fitWheel drive (all payload classes)Low-cost AGC, light cartsPilotage, lift (rarely for traction)

For AGV wheel drive applications, planetary gearboxes provide the best balance of torque density, durabilité, et le coût. The 5–15 arc-min backlash is sufficient for traction — sub-arc-min precision is unnecessary when the wheel itself has tire deformation of several millimeters. For a deeper comparison of spur vs planetary gear motor characteristics, voir notre Spur Gear Motor vs Planetary Gear Motor analysis.

Common Gear Ratios for AGV Applications

AGV TypeWheel Speed (RPM)Motor Speed (RPM)Rapport de démultiplication
Compact AMR (1–2 m/s)120–2503,000–4,00015:1 – 25:1
Warehouse AGV (1.5–2 m/s)150–3003,00010:1 – 20:1
Forklift AGV (0.5–1.5 m/s)60–1802,500–3,00015:1 – 40:1
Heavy-duty AGV (0.3–0.8 m/s)40–1002,000–3,00020:1 – 50:1

For gearbox product options compatible with AGV drive systems, voir notre gearbox product page.

Motor Sizing by Payload Class

AGV motor specifications should be selected based on the total vehicle mass (chassis + batterie + maximum payload). The following matrix provides a starting point for motor selection, with specific configurations depending on drive layout (2WD vs 4WD), floor conditions, and slope requirements.

AGV Motor Selection Matrix

PayloadType de moteurTaille du cadreBoîte de vitessesTensionApprox. Torque/MotorVitesse typique
50–150 kgBLDC planetary42millimètrePlanétaire de précision (hélicoïdal)24V3–6 N·m1.0–2.0 m/s
100–300 kgBLDC planetary56millimètreHeavy-duty planetary24V / 48V6–15 N·m1.0–2.0 m/s
300–500 kgBLDC planetary56–80mmIndustrial planetary48V15–30 N·m0.8–1.5 m/s
500–1,000 kgBLDC or servo80mm+Industrial planetary48V30–60 N·m0.5–1.2 m/s
1,000–2,000 kgDC servoServo framePlanétaire + hub48V60–120 N·m0.3–1.0 m/s
> 2,000 kgDC servo (dual)Large servoHub gearbox48V / 72V>100 N·m0.3–0.8 m/s

Note: Payload ranges overlap because the correct selection depends on drive configuration (number of driven wheels), floor friction coefficient, maximum slope angle, et cycle de service. A 4WD configuration distributes torque across four motors, allowing smaller individual motor sizes for the same payload.

For custom motor configurations tailored to specific AGV platforms, voir notre custom electric motor services.

Environmental Protection and Noise

IP Rating Requirements

Note IPNiveau de protectionRecommended AGV Environment
IP44Solid objects > 1millimètre; no water protectionClean, dry indoor environments only (not recommended for production)
IP54Dust-protected; splash waterMinimum for indoor warehouse AGVs
IP65Dust-tight; water jetsRecommended for any AGV deployed > 12 months in real environments
IP66+Dust-tight; powerful water jetsWash-down environments (nourriture, pharma, outdoor)

Proper sealing addresses the two most common BLDC motor failure modes in AGV service: bearing contamination and winding corrosion. For AGVs operating in food processing or pharmaceutical environments, stainless steel housings and food-grade grease may be required in addition to IP66+ sealing.

Noise Requirements

Application EnvironmentMax Noise LevelGear Requirement
Hospital / office corridor< 55 db(UN) @ 1mHelical planetary + ground gear teeth
Warehouse / logistics center< 65 db(UN)Standard planetary (acceptable)
De plein air / heavy industrial< 75 db(UN)Noise rarely a limiting factor

The single most effective noise reduction method is using helical (angled) gear teeth instead of straight (éperon) teeth. Ground gear profiles further reduce noise by 3–5 dB compared to powder-metal gears.

Frein, Encodeur, and Controller Integration

The AGV motor does not operate in isolation — it must integrate with a brake (for safety holding), un encodeur (for feedback), and a motor controller (for commutation and motion control). Mismatches between these components are a common source of AGV performance issues.

Brake Requirements

Brake FunctionExigenceWhen Required
Parking holdHold vehicle stationary when powered offAll AGVs (safety requirement)
Emergency stopEngage within < 100ms of E-stop signalAll AGVs (safety standard)
Slope holdingMaintain position on incline without powerAGVs operating on ramps or slopes
Power-fail safetyFail-safe (brake engages on power loss)All AGVs with lifting or slope operation

Encoder and Feedback Options

Feedback TypeRésolutionAGV Use Case
Capteurs à effet Hall60–120 pulses/rev (commutation only)Basic speed control, low-cost AGCs
Incremental encoder1,000–10,000 pulses/revStandard AGV speed/position control
Absolute encoder (single-turn)17–23 bitPositionnement de précision, docking
Absolute encoder (multi-turn)17–23 bit + 12–16 turnsContinuous position tracking without homing

Controller Communication Protocols

AGV motor controllers must interface with the vehicle’s central control system. Common communication protocols include:

ProtocolCas d'utilisationAGV Suitability
CANopenMulti-axis coordination, fleet managementIndustry standard for AGV/AMR
Modbus RTUSimple speed/torque commandsBasic AGV platforms
RS485Point-to-point motor controlSmall AGV fleets
EtherCATHigh-speed synchronized multi-axisAdvanced AMR platforms
MLI / AnalogiqueDirect speed/voltage controlLegacy or simple systems

For motor controller products compatible with AGV drive systems, voir notre motor controller product page.

Drive Configurations: 2WD, 4WD, Differential, and Hub

The number and placement of drive motors affects torque distribution, steering method, and motor sizing. Each configuration has different implications for motor selection.

ConfigurationMotor CountSteering MethodMotor Torque per WheelIdéal pour
Differential drive (2WD + caster)2Speed differential between left/rightHaut (each carries ~50% of load)Compact AMRs, light AGVs
4WD skid-steer4Speed differential (skid steering)Faible (each carries ~25% of load)Outdoor AGVs, heavy platforms
4WD + pilotage4 conduire + 1 pilotageArticulated steering motorFaible (traction) + steering motorForklift AGVs, precision docking
Hub motor (direct in-wheel)2–4Differential or articulatedDirect wheel torque (no gearbox)Compact AGVs with space constraints

Motor Selection Impact by Configuration

In a differential drive configuration, each motor must provide approximately half the total required wheel torque. In a 4WD configuration, each motor provides roughly one-quarter, allowing smaller frame sizes. Cependant, 4WD systems require tighter speed synchronization between motors to prevent wheel slip during skid steering.

Hub motor configurations eliminate the external gearbox by integrating the gear reduction inside the wheel hub. This simplifies mechanical layout but makes motor replacement more complex. For a comparison of direct drive vs gearbox approaches, voir notre Direct Drive Motor vs Gear Motor guide.

Seven-Step AGV Motor Selection Framework

The following framework synthesizes best practices from AGV manufacturers and motor suppliers into a structured selection process:

Étape 1: Define Vehicle Parameters

Document total mass (chassis + batterie + max payload), wheel diameter, number of drive wheels, target speed, and maximum slope angle. These parameters are the inputs for all subsequent calculations.

Étape 2: Calculate Required Wheel Torque

Apply the torque formula: Twheel = (m × g × μ × r) + (m × a × r). Apply a safety factor of 1.5–2.0× to account for real-world conditions. Divide by the number of drive wheels to get per-motor torque.

Étape 3: Sélectionnez le type de moteur

Choose BLDC for most warehouse/logistics AGVs (50–500 kg). Select servo for heavy-load (>1 ton) or precision docking (±0.1 mm). Consider stepper for light AGCs (<100 kg) with moderate accuracy needs. See the motor types section above.

Étape 4: Determine Voltage Platform

Use 24V for payloads under 300 kg. Use 48V for payloads above 300 kg or when motor current at 24V would exceed 20A continuously. Verify battery configuration supports the selected voltage.

Étape 5: Select Gearbox and Ratio

Calculate required gear ratio: motor RPM ÷ required wheel RPM. Choose planetary gearbox for AGV traction (best torque density and noise). Verify gearbox continuous torque rating exceeds calculated wheel torque.

Étape 6: Specify Environmental Protection

Minimum IP54 for indoor warehouse. IP65 recommended for any AGV with >12 month deployment. IP66+ for wash-down environments. Select helical gears for noise-sensitive applications.

Étape 7: Integrate Brake, Encodeur, and Controller

Specify electromagnetic brake for parking/emergency/slope holding. Select encoder resolution based on positioning accuracy requirement. Match controller communication protocol to AGV central control system (CANopen, Modbus, EtherCAT).

ÉtapeKey OutputCommon Mistake
1. Vehicle parametersTotal mass, wheel size, vitesse, slopeForgetting battery weight in total mass
2. Torque calculationRequired N·m per motor (with safety factor)Using peak torque instead of RMS for continuous duty
3. Type de moteurBLDC / servomoteur / pas à pas / brosséOver-specifying servo for simple transport AGVs
4. Tension24V or 48VChoosing 24V for heavy payloads, causing excessive current
5. Boîte de vitessesTaper, rapport, couple nominalIgnoring gearbox efficiency in torque calculation
6. EnvironnementIndice IP, noise classSpecifying IP54 for environments with floor washing
7. IntégrationFrein, encodeur, controller specMismatched controller protocol to AGV system

Total Cost of Ownership Analysis

The lowest-priced motor is rarely the lowest-cost motor over an AGV’s deployment lifetime. A TCO analysis should consider four cost categories:

Catégorie de coûtMoteur de vitesse planétaire BLDCMoteur à courant continu brosséImpact
Initial procurementPlus haut (1.3–2× brushed)Lower baselineBLDC costs more upfront
Coût énergétique (battery charging)20% lower (90% contre 75% efficacité)Higher consumptionCompounds over multi-year deployment
Coût d'entretienNear zero (4–8 years single-shift)Brush replacement every 2,000–5,000 hLabor + downtime for brush service
Downtime costInférieur (longer MTBF)Plus haut (more frequent failures)Fleet of 50+ AGV: $200–$500/hour unplanned downtime

For a fleet of 50 AGVs operating 24/7, investing in higher-quality BLDC planetary gear motors typically reduces total cost of ownership by 30–50% over a 5-year deployment period compared to brushed DC alternatives. The energy savings alone — from 90% contre. 75% efficiency — can offset the higher initial procurement cost within the first 12–18 months.

For motor testing and quality validation processes that support long-life AGV deployment, voir notre electric motor testing standards page.

Application-Specific Motor Recommendations

Warehouse AMR (50–200 kg)

ParamètreRecommendation
Type de moteurBLDC with integrated planetary gearbox
Frame size42millimètre
Tension24V
Rapport de démultiplication15:1 – 25:1
FeedbackIncremental encoder + Capteurs à effet Hall
Indice IPIP65
FreinElectromagnetic, 24V
Noise target< 55 db(UN) @ 1m

Forklift AGV (500–1,500 kg)

ParamètreRecommendation
Type de moteurBLDC (traction) + servomoteur (lift/steering)
Frame size80mm+ (traction); servo frame (lift)
Tension48V
Rapport de démultiplication20:1 – 40:1 (traction); 50:1+ (lift)
FeedbackAbsolute encoder (multi-turn)
Indice IPIP65
FreinDual brake (holding + emergency)

Heavy-Duty Platform AGV (> 1,500 kg)

ParamètreRecommendation
Type de moteurDC servo with industrial planetary gearbox
Configuration4WD or dual hub motors
Tension48V / 72V
Rapport de démultiplication30:1 – 50:1
Feedback17-bit absolute encoder
Indice IPIP66
ManetteCANopen / EtherCAT

Light AGC / Cart (< 100 kg)

ParamètreRecommendation
Type de moteurStepper or small BLDC
Tension12V / 24V
Rapport de démultiplication10:1 – 20:1
FeedbackCapteurs à effet Hall (BLDC) or open-loop (pas à pas)
Indice IPIP44 (indoor clean environments)
FreinFacultatif (low slope only)

For light AGC applications using stepper motors, voir notre stepper motor product page. For motor comparison in the context of AGV vs AMR platform differences, voir notre AGV vs AMR guide.

Foire aux questions

What voltage motor is used in AGV?

The most common AGV motor voltages are 24V and 48V DC. 24V systems are used for compact AMRs and light AGVs (50–300 kg payload), while 48V systems are standard for medium to heavy AGVs (300–2,000+ kg). 12V is occasionally used for very light AGCs, and 72V for very heavy industrial AGVs. The voltage choice is driven by the battery platform and affects motor current draw, exigences de câblage, and controller sizing.

How much torque does an AGV motor need?

AGV motor torque depends on total vehicle mass, wheel radius, rolling friction, target acceleration, and slope angle. Pour un 150 kg AMR with 75mm wheel radius on smooth floor (μ=0.02) et 0.5 m/s² acceleration, the calculated wheel torque is approximately 7.8 N·m total (3.9 N·m per motor in dual drive). With a 1.5–2.0× safety factor, the design target is 5.9–7.8 N·m per motor. Heavy AGVs (>1 ton) may require 30–120 N·m per motor depending on configuration.

BLDC or servo motor for AGV — which is better?

BLDC motors are the preferred choice for most AGV and AMR applications in the 50–500 kg payload range due to their balance of efficiency, coût, and maintenance-free operation. Servo motors are better for heavy-load AGVs (>1 ton), applications requiring ±0.1 mm positioning accuracy, or scenarios with frequent high-dynamic maneuvers requiring 300% capacité de surcharge. For standard warehouse logistics, BLDC with planetary gearbox and encoder feedback provides sufficient performance at lower cost.

What gearbox ratio is used for AGV motors?

Common AGV gearbox ratios range from 10:1 pour 50:1, avec 15:1–25:1 being typical for warehouse AMRs. The ratio is calculated as motor RPM ÷ required wheel RPM. Par exemple, a motor running at 3,000 RPM with a wheel needing 150 RPM requires a 20:1 rapport. Planetary gearboxes are the standard choice for AGV traction due to their high torque density, faible jeu (5–15 arc-min), et faible bruit.

How long do AGV motors last?

A well-designed BLDC planetary gear motor with IP65 sealing and quality bearings typically lasts 10,000–20,000 hours before first maintenance. This equates to 4–8 years of single-shift operation or 2–4 years of 24/7 continuous operation. Brushed DC motors last 2,000–5,000 hours before requiring brush replacement. The most common failure modes for BLDC motors in AGV service are bearing contamination and winding corrosion — both addressable through proper sealing.

Can stepper motors be used for AGV?

Stepper motors can be used for light AGVs and AGCs (< 100 kg payload) where positioning accuracy requirements are moderate (±1–5 mm) and speed is low. They offer cost advantages and simple integration. Cependant, steppers lose torque at higher speeds, are susceptible to step loss under sudden load changes, and are not suitable for heavy payloads or continuous operation. Boucle fermée (hybride) steppers with encoder feedback address some of these limitations.

Références

  1. Moteur tourbillonnant. “How to Select the Right BLDC Gear Motor for AMR and AGV Robots.” Disponible à: https://www.twirlmotor.com/how-to-select-the-right-bldc-gear-motor-for-amr-and-agv-robots/
  2. DMK Motor (BeUDMKE). “High-Performance AGV Motor for AMR/AGV.” Disponible à: https://www.dmkmotor.com/agv-motor/
  3. X-TEAM Brushless DC Motor. “How to Choose a Suitable BLDC Motor for AGV?” Disponible à: https://www.x-teamrc.com/how-to-choose-a-suitable-bldc-motor-for-agv/
  4. HKT ROBOT (AGVMotor.com). “AGV Motor for AGV/AMR Applications.” Disponible à: https://agvmotor.com/blogs/knowledge/agv-motor-for-agv-amr-applications
  5. MyTen-Tech. “AGV’s Power Heart: Motor Selection Guide and Core Technology Analysis.” Disponible à: https://myten-tech.com/news/components-introduction-and-selection/agvs-power-heart-motor-selection-guide-and-core-technology-analysis/
  6. Moteur oriental. “AGV — Automatic Guided Vehicle Sizing Tool.” Disponible à: https://www.orientalmotor.com/motor-sizing/agv-sizing.html
  7. Sunrise Motor. “The Guide to BLDC Motors: From AGV Powerhouses to Medical Precision.” Disponible à: https://www.sunrisemotor-cn.com/The-Guide-to-BLDC-Motors:-From-AGV-Powerhouses-to-Medical-Precision.html
  8. Le moteur Dunker. “AGV/AMV/AMR Gear Motors.” Disponible à: https://www.dunkermotoren.com/en/industries/warehouse-automation/agv-gear-motor
  9. YIKONG (BiControls). “Torque Calculation and Optimization for AGV Drive Motors: Enabling Flexible Logistics in Automotive Manufacturing.” Disponible à: https://en.bicontrols.com/news_detail/50.html
  10. Nidec Motor Corporation. “AGV Motors — Reliable and Robust AGV/AMR Motor Platforms.” Disponible à: https://moen.nidec.com/automation/Products/AGV-Solutions/AGV-Motors

Tu pourrais aussi aimer

How to Choose a Motor for AGV Applications: Complete Selection Guide

Sortir de la grille

Envoyez votre demande aujourd'hui

Greensky alimente WeChat

Veuillez laisser votre email professionnel.

Parlez-nous de vos besoins