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4 Lead 35mm 1.8 Degree Stepper Motor With Reduction Gearbox 2.2 nm 3 nm 4 nm
Place of Origin | China |
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Brand Name | TB-Motor |
Certification | CE ROHS ISO |
Model Number | 35BYGX |
Minimum Order Quantity | 50 |
Price | USD |
Packaging Details | Carton with Inner Foam Box, Pallet |
Delivery Time | 25 DAYS |
Payment Terms | L/C, D/P, T/T, Western Union, MoneyGram |
Supply Ability | 10000 PCS/MONTH |
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Product Details
Product Name | Stepping Gearbox Motor | Lead Wire Number | 4 |
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Step Angle | 1.8 ° | Step Accuracy | ± 5% |
Temperature Rise | 80 ℃ Max | Insulation Resistance | 100MΩ Min.500VC DC |
Ambient Temperature | -20℃~+50℃ | Dielectric Strength | 500VAC 1 Minute |
Radial Load(10mm From Flange)N | ≤120 | Shaft Axial Load(N) | ≤80 |
Thrust Play Of Shaft Mm | ≤0.1 | Backlash At No-load (°) | ≤1.5 |
High Light | 2.2nm stepper motor,35mm stepper motor 3nm,1.8 stepper motor 4nm |
Product Description
35BYGX micro 4 leads electric hybrid stepper motor with reduction gearbox
*Products can match gearbox 32, 36mm
32 & 36mm Gearbox tolerance torque
Stage 1: Rated tolerance torque 0.3 N.m, max 1 N.m
Stage 2: Rated tolerance torque 1.2 N.m, max 3.5 N.m
Stage 3: Rated tolerance torque 2.5 N.m. max 7.5 N.m
32mm gearbox material: Powder metallurgy
36mm gearbox material: Powder metallurgy & Zinc alloy
MOTOR PART Electrical Specification:
MODEL | STEP ANGLE (°/STEP) | LEAD WIRE (NO.) | VOLTAGE (V) | CURRENT (A/PHASE) | RESISTANCE (Ω/PHASE) | INDUCTANCE (MH/PHASE) | HOLDING TORQUE (G.CM) | MOTOR HEIGHT L(MM) | MOTOR WEIGHT (KG) |
---|---|---|---|---|---|---|---|---|---|
35BYGX001A | 1.8 | 4 | 10.4 | 0.4 | 26 | 17 | 500 | 23 | 0.12 |
35BYGX200A | 1.8 | 4 | 4.2 | 1 | 4.2 | 5.5 | 1250 | 29 | 0.12 |
35BYGX201A | 1.8 | 4 | 1.45 | 0.5 | 2.9 | 2.6 | 500 | 29 | 0.13 |
35BYGX401A | 1.8 | 4 | 3.20 | 1 | 3.2 | 3.8 | 1400 | 34 | 0.16 |
*Products can be customized by special request.
Wiring Diagram
Out diameter 32mm Powder metallurgy
Housing material | Bearing at output | Radial load(10mm from flange)N | Shaft axial load(N) | Shaft press-fit force max(N) | Radial play of shaft(mm) | Thrust play of shaft(mm) | Backlash at no-load (°) |
Powder metallurgy | sleeve bearings | ≤120 | ≤80 | ≤500 | ≤0.03 | ≤0.1 | ≤1.5 |
Reduction ratio | Rated tolerance torque (Nm) | Max momentary tolerance torque (Nm) | Efficiency% | Length (mm) | Weight(g) | Number of gear trains |
1/4 | 0.3 | 1.0 | 81% | 29.1 | 150 | 1 |
1/5 | ||||||
1/16 | 1.2
| 3.5
| 72% | 38.1 | 185 | 2 |
1/23 | ||||||
1/33 | ||||||
1/67 | 2.5
| 7.5 | 65% | 47.1 | 220 | 3 |
1/94 | ||||||
1/133 | ||||||
1/188 |
Mechanical Dimension
Out diameter 36mm Powder metallurgy
Housing material | Bearing at output | Radial load(10mm from flange)N | Shaft axial load(N) | Shaft press-fit force max(N) | Radial play of shaft(mm) | Thrust play of shaft(mm) | Backlash at no-load (°) |
Powder metallurgy | sleeve bearings | ≤120 | ≤80 | ≤500 | ≤0.03 | ≤0.1 | ≤1.5 |
Reduction ratio | Rated tolerance torque (Nm) | Max momentary tolerance torque (Nm) | Efficiency% | Length (mm) | Weight(g) | Number of gear trains |
1/4 | 0.3 | 1.0 | 81% | 24.8 | 145 | 1 |
1/5 | ||||||
1/16 | 1.2
| 3.5
| 72% | 32.4 | 173 | 2 |
1/20 | ||||||
1/25 | ||||||
1/53 | 2.5 | 7.5 | 65% | 41.9 | 213 | 3 |
1/62 | ||||||
1/76 | ||||||
1/94 | ||||||
1/117 |
Mechanical Dimension
Out diameter 36mm Zinc alloy
Housing material | Bearing at output | Radial load(10mm from flange)N | Shaft axial load(N) | Shaft press-fit force max(N) | Radial play of shaft(mm) | Thrust play of shaft(mm) | Backlash at no-load (°) |
Zinc alloy | Porous bearings | ≤45 | ≤25 | ≤100 | ≤0.08 | ≤0.4 | ≤1.5 |
Reduction ratio | Rated tolerance torque (Nm) | Max momentary tolerance torque (Nm) | Efficiency% | Length (mm) | Weight(g) | Number of gear trains |
1/12 | 0.3 | 1.0 | 81% | 26.8 | 100 | 1 |
Mechanical Dimension
Planetary Gearbox Applications
As well as uses for transmissions in vehicles, planetary gearboxes are used in various industries for different applications. They offer high precision and high torque-to-volume ratio making them well suited to applications that involve; increasing torque, reducing speed, precise positioning, and controlling reproducible machinery.