Nema 34 2-phase Stepper Motor, 6A, 1.8 degree, 4 wires

$108.31

Low cost Nema 34 bipolar stepper motor from ATO. This is 6A, 1.8 deg with holding torque of 2.8 Nm. Connection is made through 4-wires. Manufacturer direct sale.

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SKU: ATO-STEP-2603406

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Delivery date: 6-12 days

Overview
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Nema 34 Stepper motor bipolar, 2.8Nm in 60mm, 1.8 degree, 2 phase 4 wires, manufacturer direct sale.

Specification

Basics	Model	ATO260-6004A
	Matched Driver Model	ATODSP86(Click it to see more info)
	Holding torque	2.8Nm
	Current/phase	6A
	Resistance	0.3Ω
	Step angle	1.8°
	Rotor inertia	1000g.cm²
	Weight	1.7kg
	Length	60mm
	Motor leads	4
Technical parameters	Step Angle Accuracy	±5%(full step, no load)
	Resistance Accuracy	±10%
	Inductance Accuracy	±20%
	Temperature Rise	80℃ Max.(rated current, 2 phase on)
	Ambient Temperature	-10℃～+ 50℃
	Insulation Resistance	100MΩ Min 500V DC
	Dielectric Strength	500V AC for one minute
	Shaft Radial Play	0.06Max.(450g)
	Shaft Axial Play	0.08Max.(450g)

Dimensions

Motor Connection

/Motor connection

Details

Nema 34 Stepper Motor,1.1A-8A Details

Tips: Application of stepper motor in 3D printer

3D printer actually indicates a new-type way of printing, namely a technique for manufacturing through additive. The material falls down continuously and regularly so that one three-dimensional object is formed. Such process is academically called rapid prototyping, through which the physical product and prototype we need can be built. The printer scans the data from CAD design program, 3D image and animation software mutually and opens the final product to form a physical model.
There are high requirements for the precision of 3D printer and control accuracy. It is necessary to use the stepper motor. Due to its high control accuracy, the stepper motor can guarantee the accuracy in 3D stopping and rotation direction, thus the accuracy in rapid prototype design of the product is ultimately guaranteed.
After 3D computer file is read, through a series of scanning, the prototype is made to a series of cross-section slices, and 3D printer working with stepper motor creates 3D object by printing each slice of the prototype. Thus, the characteristics of fast shaping are guaranteed.

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In this video, 9 common problems that can occur with stepper motors are discussed, and expert advice is provided for diagnosing and effectively resolving these problems. If you have ever experienced problems with your stepper motor or want to be prepared for any future problems, this video is a must watch.

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In this video, we explore the step-by-step process of configuring an HMI and PLC to synchronize and manage specific cycle lengths of stepper motors, ensuring accurate power delivery.

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In this video we've guided you through how to do VFD control wiring with a self-lock push button switch to run the motor in forward direction. We've covered everything from wiring to programming and even a test run. So just watch it through and hope you'll find it informative and helpful.

1.8 degree stepper motor teardown & construction display

In the case of non-overload, the speed and stop position of the motor only depend on the frequency and pulse number of the pulse signal, and are not affected by the load change. That is, when a pulse signal is added to the motor, the motor rotates through a step angle. The existence of this linear relationship, coupled with the characteristics of the stepper motor having only periodic errors and no cumulative errors. This makes it very simple to use stepper motors to control the speed, position and other control fields.