Bj42d15 26v10 Stepper Motor Datasheet «EXTENDED»

: 5mm diameter, typically with a D-shape for secure gear mounting. Practical Applications This motor is a standard "workhorse" for the following:

| Specification | Value | Notes | | :--- | :--- | :--- | | | Hybrid Stepper Motor | Permanent Magnet, 2-Phase | | Frame Size | NEMA 17 (42 x 42 mm) | Standard mounting holes | | Body Length | 15 mm | "Short" profile | | Step Angle | 1.8° | 200 steps per revolution | | Rated Voltage | 2.6V DC | See voltage note below | | Rated Current | 1.0A per phase | | | Coil Resistance | ~2.6 Ω per phase | Calculated: V/R = 2.6/2.6 = 1.0A | | Holding Torque | 0.16 - 0.20 N·m (22 - 28 oz-in)| Typical for 15mm length | | Rotor Inertia | ~18 g·cm² | | | Lead Wire | 4 wires | Standard bipolar connection | | Insulation Class | Class B (130°C) | Standard for budget motors | | Weight | ~150 grams | | bj42d15 26v10 stepper motor datasheet

1.8 degrees, meaning it takes 200 steps to complete a full 360° rotation. : 5mm diameter, typically with a D-shape for

If your driver is putting exactly 2.6V into this motor, . Stepper motors are current-driven, not voltage-driven. The "2.6V" is simply the voltage required to push 1.0 Amp of current through the 2.6-ohm coil when the motor is locked and stationary. Stepper motors are current-driven, not voltage-driven

"It doesn't move matter through space. It moves the observer through time. Each step is a Planck-length shift along a closed timelike curve. I’ve run it for 10 seconds at 26.10 kHz. I’ve seen the library’s east wing as it was in 1987. The problem is… I’m no longer sure which version of me wrote this entry. If you’re reading this, do not—"