Analysis of the Swinging Frequency and Distance Parameters of an Intelligent Moxibustion Robot

The degree to which an intelligent moxibustion robot simulates traditional hanging moxibustion techniques ("hanging moxibustion simulation") directly impacts treatment effectiveness and user experience. This article focuses on its quantification method, centered on the precise measurement and optimization of two key parameters: motion frequency (the speed of the moxa stick's oscillation) and moxibustion height (the distance between the moxa stick and the skin). By analyzing how these parameters influence simulation effectiveness and developing optimization paths, the goal is to improve the accuracy and comfort of moxibustion treatment.

Quantifying the Basis for Hanging Moxibustion Simulation

The key to scientifically quantifying the hanging moxibustion simulation of an intelligent moxibustion robot lies in the precise measurement of two core motion parameters:

• Moxibustion frequency: The number of oscillations of the moxa stick head per unit time.

• Moxibustion height: The vertical distance between the end of the moxa stick and the skin surface.

By using high-precision sensors to collect and analyze the changes in these two parameters in real time, we can objectively assess the degree to which the machine's operation aligns with the techniques of professional moxibustion practitioners. This quantitative result forms the basis for evaluating the authenticity of hanging moxibustion simulation and provides a basis for optimizing core experience indicators such as comfort and efficacy.

Optimization Strategy for Movement Frequency

Motion frequency is a key factor influencing the realism of suspended moxibustion simulation:

• Mechanism of Action: Adjusts the swing speed of the moxa tip to simulate the dynamic rhythm of suspended moxibustion.

• Optimization Goal: Determine the optimal frequency range through experiments to ensure natural, smooth movements and effective treatment. Excessively high frequencies may cause discomfort; excessively low frequencies affect the depth and effectiveness of thermal penetration.

Core Value: Optimized movement frequencies significantly improve treatment accuracy and user comfort, making machine operation more authentic to real-life techniques.

Precise Control of Moxibustion Height

Precise control of moxibustion height is another key factor in ensuring safe and effective simulation:

• Core Impact: Moxibustion height directly determines thermal penetration depth and body surface temperature.

• Risk Avoidance: Too low a height can increase the risk of local overheating and burns, causing discomfort or pain. Too high a height prevents the heat from effectively penetrating deep tissue, reducing the therapeutic effect.

Technical Implementation: The device requires precise height control within a small range (e.g., 1-3 mm). The intelligent system dynamically fine-tunes the moxibustion height by monitoring skin temperature and environmental parameters in real time. Core Value: Precise height control is fundamental to achieving even heat distribution, avoiding burn risks, and ensuring the effectiveness of moxibustion therapy, directly enhancing treatment safety and comfort.

Synergistic Improvement of Core Experience Indicators

Precisely optimizing movement frequency and moxibustion height synergistically improves core experience indicators:

• Improved Comfort: Optimizing frequency reduces stiffness; precise height control avoids overheating and discomfort.

• Enhanced Safety: Dynamic height control effectively prevents burns.

• Improved Treatment Precision: The combination of these two ensures that heat penetrates the target tissue as needed.

• Effective Verification: User feedback and clinical observations show that parameter optimization improves the overall treatment experience (satisfaction, safety, and perceived effectiveness).

Through the precise quantification, continuous monitoring, and coordinated optimization of two core parameters, movement frequency and moxibustion height, the intelligent moxibustion robot more realistically replicates the traditional suspended moxibustion technique. The optimized frequency simulates the dynamic rhythm of suspended moxibustion, while precise height control ensures safe and effective heat transfer. The combined effect of these two significantly enhances the accuracy, safety and comfort of moxibustion treatment, providing users with a more reliable and traditional intelligent moxibustion experience.