1.4 kW Hertz Spindle Motor ER20 24000 RPM
Detailed Product Review
The Hertz HMB90 series 1.4 kW spindle motor is a critical electromechanical component that ensures the high-speed and precise rotation of the cutting tool in industrial CNC machining applications. This motor features a three-phase alternating current (AC) driven asynchronous or synchronous motor structure, typically controlled by a Variable Frequency Drive (VFD). Its primary function is to convert electrical energy into mechanical rotational energy, enabling cutting, engraving, drilling, and milling operations. The maximum speed of 24000 RPM allows for high cutting speeds (Vc), especially when working with small diameter tools, thereby achieving superior surface smoothness and detail accuracy on machined parts. Internally, the motor utilizes specially designed ceramic ball or hybrid angular contact bearings to ensure stability at high speeds; these bearings are preloaded to handle both radial and axial loads with high precision. Dynamic balancing minimizes vibration at high speeds, extending tool life and improving machining quality.
The structural components of this spindle motor are designed to withstand the demanding conditions of industrial environments. The housing is typically made from high-strength aluminum alloys that optimize heat dissipation and enhance structural rigidity. The shaft is precision-machined from high-alloy steel with tight tolerances, forming the tool-holding interface with the ER20 collet system. The integrated air-cooling system effectively dissipates heat generated during continuous high-speed operation, reducing thermal stress on the windings and bearings, which prolongs the motor’s lifespan and ensures performance stability. For system integration, this motor features standard industrial interfaces and can be easily connected to CNC control systems via a suitable VFD. The VFD controls the motor’s speed, torque, and direction, while the CNC controller sends commands to the VFD using analog (e.g., 0-10V) or digital signals (e.g., Modbus, Profibus). This motor is widely used for processing various materials such as wood, plastic, composite materials, plexiglass, and light metals (like aluminum, brass). It offers an ideal solution for applications requiring high speed and precision, such as CNC routers, engraving machines, and PCB processing equipment.
Advantages of the 1.4 kW Hertz Spindle Motor ER20 24000 RPM
High-Frequency Machining Capability and Surface Quality: The maximum rotation speed of 24000 RPM allows for high cutting speeds (Vc) when using small diameter cutting tools. This minimizes the chip load per tooth (fz), enabling micron-level surface smoothness. High RPM also helps reduce thermal stress and vibration on the material, resulting in sharper edges and less burring, especially in applications like engraving, fine detail work, and PCB prototyping. Furthermore, high RPM facilitates efficient material removal and potentially longer tool life even in thin cuts of harder materials.
Wide Tool Compatibility and Machining Flexibility (ER20 Collet System): The integrated ER20 collet system, designed according to DIN 6499 standards, can precisely and securely hold tools with diameters ranging from 1 mm to 13 mm. The conical structure and multi-slit design of ER collets ensure high concentricity (low run-out) of the tool relative to the spindle axis. This feature allows for the use of various cutting tools, including milling bits, drills, and engraving tools, on a single spindle, increasing application flexibility and optimizing tool change times. High clamping force and low run-out directly impact vibration reduction, machining quality, and tool life.
Industrial Durability and Thermal Management: The Hertz HMB90 series spindle motor boasts a robust construction designed for the continuous and intensive operating conditions of industrial production environments. The motor housing is manufactured from high-strength, thermally conductive materials. The integrated air-cooling system effectively dissipates heat from the motor’s stator windings and bearings via a fan and specially designed radial fins. This thermal management strategy prevents overheating, protects winding insulation, and maintains stable operating temperatures even at high speeds. This extends the life of bearings and other critical components, contributing to sustained nominal power and precision during prolonged operations, thereby minimizing maintenance costs and unplanned downtime.
Technical Specifications and Capacity
Specification
Value/Description
Motor Power
1.4 kW (Continuous nominal power output for high-performance machining processes)
Maximum Speed
24000 RPM (Ideal high-frequency rotation speed for fine and detailed machining processes)
Collet Type
ER20 (Precision collet system compliant with DIN 6499 standard, supporting a wide range of tools)
Series
Hertz HMB90 (High-performance series optimized for industrial automation and CNC machining applications)
Cooling Type
Air-Cooled (Effective system providing thermal management through an integrated fan and radial fins)
Application Areas
CNC Router, Engraving Machines, PCB Processing (Wood, plastic, composite, and light metal machining)
Technical Frequently Asked Questions (FAQ)
What technical parameters should be prioritized when selecting this spindle motor?
When selecting a spindle motor, the type of material to be machined, the diameter of the cutting tool, and the desired machining quality should be primarily considered. The 1.4 kW power rating determines the motor’s continuous torque capacity, while the 24000 RPM maximum speed indicates its capability for high cutting speeds with small diameter tools. Bearing type and preload are critical for vibration damping at high speeds and for axial/radial load-bearing capacity. The cooling method (air-cooled) affects the motor’s thermal management and stability during prolonged operation. Additionally, the ER20 collet type determines the applicable tool diameter range and clamping precision. These parameters should be optimized according to the application’s required torque-speed characteristics, machining accuracy, and efficiency expectations.
What are the technical requirements for the correct integration of this Hertz HMB90 series spindle motor with a VFD (Variable Frequency Drive)?
For correct integration with a VFD, it is essential that the VFD matches the spindle motor’s nominal power (1.4 kW) and operating voltage. The VFD’s output frequency range must be sufficient to achieve the spindle motor’s maximum speed of 24000 RPM (typically 400 Hz and above). The motor’s pole count (usually 2 or 4 poles) must be correctly entered into the VFD parameters. The VFD’s acceleration and deceleration ramps should be adjusted to manage dynamic loads on the tool and workpiece. Furthermore, the VFD’s sensorless vector control or encoder feedback control capability can provide precise torque and speed control even at low speeds. An installation compliant with Electromagnetic Compatibility (EMC) standards and the use of shielded cables are critical for maintaining signal integrity and minimizing ambient electromagnetic interference.
What are the periodic maintenance requirements and technical considerations for the long-term, efficient operation of a high-speed spindle motor?
Regular maintenance is critical for the long-term, efficient operation of high-speed spindle motors. In air-cooled systems, the cooling fan and air intake/exhaust channels must be periodically cleared of dust and debris to maintain effective thermal management. Bearing life depends on operating conditions and load; adherence to the manufacturer’s specified bearing replacement intervals is important. The cleanliness of the collet and collet nut directly affects tool clamping accuracy and run-out; these components should be regularly inspected and cleaned. Tool balancing is vital for minimizing vibration at high speeds and reducing load on the bearings. Additionally, periodic inspection of the motor’s electrical connections for looseness or corrosion is necessary to prevent electrical failures. Abnormal noises or vibrations can be early indicators of potential issues and require immediate technical inspection.
What are the technical impacts of the ER20 collet system on tool clamping accuracy and repeatability, and how can the advantages of this system be maximized?
The ER20 collet system, with its conical structure and flexible segments, ensures high concentricity (low run-out) of the tool relative to the spindle axis. This allows for uniform contact between the tool’s cutting edges and the workpiece, resulting in more homogeneous chip removal, better surface quality, and longer tool life. Repeatability in the system means achieving similar run-out values even when the same tool is removed and reinserted, which is critical for quality consistency in mass production. To maximize the advantages of the ER20 system, ensure collets and collet nuts are clean, tighten the collet nut to the manufacturer’s specified torque, and use only collets of the correct size. Using worn or damaged collets will increase run-out, degrade machining quality, and shorten tool life. Proper insertion depth of the tool into the collet (typically at least 3 times the tool diameter) and ensuring the collet is fully seated in the spindle are also important for accuracy.



































































































































































































