Continuous operation: Traditional turnstiles, with a daily average power usage of 3–5 kWh per machine, utilize a fixed-speed design that maintains full-speed operation even in the absence of traffic demand.
Mechanical wear gets more prominent. Long-term full-load operation speeds up the wear of motors and reducers, therefore increasing the average annual maintenance cost by 40%.
Response time waste: Older mechanical limit devices have a response time of more than 200 ms, which leads to poor energy efficiency.
Effective emergency mode: Constant open state and power outage depend on continuous power supply from the battery, therefore reducing the lifetime of the battery.
Dynamic load matching is changing motor power in response to real-time traffic demand to save 30% to 45% of the energy consumed.
Predictive maintenance: Through motor condition monitoring, increase equipment lifetime by over 30% and lower spare part replacement frequency.
Optimization of systems at levels: Work with building automation systems to reach worldwide energy control.
Compliance enhancement: Discover the energy efficiency criteria set by LEED and BREEAM, among green construction certifications.
Systems of efficient motors:
By using a permanent magnet synchronous motor (PMSM), the efficiency increases to 92%, which is 15% higher than an asynchronous motor.
Integrated variable frequency drive (VFD), therefore providing 0.1–1500 rpm stepless speed control
Twin cooling air ducts reduce the motor's temperature rise by twenty-five degrees Celsius.
clever mechanism of transmission:
Harmonic reducer transmission ratio: 1:100; mechanical efficiency > 95%.
With a 16384P/R resolution, the magnetic encoder replaces the conventional photoelectric encoder.
Self-lubricating bearing design brings the friction coefficient down to 0.001.
Adaptive speed control based on fuzzy PID control; reaction time: 50 ms.
92% prediction accuracy for the model predicting traffic flow (LSTM neural network)
The multi-objective optimization method balances energy consumption and traffic efficiency.
Dynamic load matching is
dynamically changing output power through real-time motor current and torque monitoring.
Five-wattage idle standby power is reduced by ninety percent compared to conventional equipment.
25% increase in light load mode (<30% load) efficiency
Integration with building automation:
Support BACnet and Modbus as part of industrial protocols.
Connect with air conditioning systems and lighting to attain scenario-based energy savings.
Management on cloud platforms:
0.1 kWh precision remote energy consumption monitoring
Alert : abnormal energy consumption; equipment breakdown seen seventy-two hours ahead.
Reports on energy efficiency help enhance KPI evaluations. 3. Typical uses for energy-saving technologies
Technical answers:
Install equipment for monitoring pedestrian flow using millimeter wave radar to track passenger flow density in waiting areas in real time.
Using partition control, divide the gate group into high, middle, and low load zones.
Implementation effect:
From 4.2 kWh to 2.8 kWh, a single machine's daily average power consumption has dropped.
The extended motor lifespan was eight years, while the conventional motor lifespan was only five years.
Cut running and maintenance expenses by thirty-five percent.
Creatively Applied Practice:
Create a flight schedule link and start preheating or prechilling thirty minutes ahead of time.
Using a solar-aided power supply system, the yearly self-generating capability comes to 1200 kWh.
Operating information:
The PUE value of the fleet of international gates has reduced to 1.15.
The carbon emission intensity now runs at 0.08 kgCO₂/person-time.
The batteries for the emergency power supply ran for four hours.
Access Control Speed Gate Turnstile
WhatsApp : +8615999546575
Skype : cmolo.joy
Email : contact@cmolo.com
Tel : 0086-0755-83065161
CMOLO Industrial Park,NO. 144-1, Hengping Road,Henggang Street, Longgang District, Shenzhen City, China
