Control Speed & Reduce Noise with Core Chip! JXIN ADP32F036 Unlocks New Blender Experience

With rising public awareness of healthy eating, blenders have become a must-have in modern kitchens thanks to their ability to deeply extract nutrients from ingredients.However, traditional blenders commonly suffer from startup vibration, low speed regulation accuracy, limited functions, and high operating noise, failing to meet consumer demand for efficient, quiet, and multi‑functional performance. Product upgrades are urgently needed.

In response to market demand and industry pain points, JINXIN TECHNOLOGY launches a sensorless FOC control solution for blenders based on the ADP32F036 chip.Centered on the domestically developed high-performance DSP chip ADP32F036 and equipped with proprietary sensorless FOC control algorithm, the solution accurately observes motor speed and torque, enabling smooth shock‑free startup, high torque at low speed, quiet high‑speed operation, and multi‑scenario compatibility, helping customers develop high‑end blenders.

Hardcore Configuration, Solid Performance Foundation

Core Highlights: Three Technologies Redefine the Blender Performance Ceiling

Sensorless FOC Vector Control: Optimal Balance of Quietness & Efficiency

Adopting a position-sensorless design with position estimation accuracy of 1/100, the solution supports a wide speed range from 200 rpm to 24,000 rpm and speed stability accuracy of ±0.5 Hz.Smooth current waveforms reduce motor losses. Combined with an independent low‑noise cooling system, the overall operating noise is controlled below 75 dB, completely eliminating noise disturbance.

▲Block Diagram of Sensorless FOC Algorithm

High-Frequency Injection + Flux-Weakening Control: Smooth & Powerful Performance

Millisecond-level IPD high-frequency injection for initial positioning ensures zero motor rotation before startup. It accurately detects rotor position to achieve zero-shock startup, eliminating reverse rotation and vibration.The dual-algorithm fused flux-weakening control guarantees energy efficiency and low noise during high-speed blending while delivering high torque, providing core support for multi-function expansion.

▲High-Frequency Injection Startup

Dead-Time Compensation + Precision Sampling: Further Improved Control Accuracy

Dead-time compensation is realized through precise current zero-crossing detection, effectively reducing harmonic interference and enhancing motor stability.Sampling timing is intelligently selected based on the SVPWM output interval to reconstruct current waveforms, ensuring accurate speed control across the full power range.

▲Without Dead-Time Compensation

 ▲With Dead-Time Compensation

Solution Advantages: All-in-One Machine, Unlocking New Blender Possibilities

Supported by core technologies, the solution integrates high-speed blending, low-speed dough mixing, and high-performance ice crushing in one device, greatly enhancing product added value:

High-speed blending + ice crushing：1000W high power output, accelerating from 0 to 21,000 rpm in only 3 seconds. It easily handles high-load blending and directly crushes ice with stable speed for smooth sorbets and iced drinks.

Low-speed dough mixing: Delivers 1.8 Nm high torque at a low speed of 100 rpm, running smoothly without step-out. The kneaded dough is elastic and non-sticky, with no flour residue on the cup wall.

Energy saving & reliability: Supports wide voltage input from 120 Vac to 264 Vac, compatible with power grids worldwide; standby power consumption ≤ 0.2 W, meeting EU ErP energy-saving standards; comprehensive abnormal protection ensures long-term stable operation.

Main Control Chip ADP32F036: The "Intelligent Brain" of Blenders

JINXIN ADP32F036 is a high-performance 32-bit fixed-point DSP chip designed specifically for precise motor control, featuring high reliability and cost-effectiveness.

JINXIN’s blender solution based on the ADP32F036 chip empowers product upgrades through technological breakthroughs and provides customers with one-stop support from hardware to algorithms.