1. Product Overview

The Atlas Copco ZHC10000 cooler is a high-overall efficiency heat exchange unit specifically built for centrifugal air compressors, serving as the core module of the Atlas Copco ZH series compressor cooling system. This modular-designed cooler integrates with the compressor's aftercooler, oil cooler, and intercooler units, utilizing water cooling to achieve staged cooling of compressed air and lubricating oil. Its core functions include:

• Compressed Air Cooling: minimizes high-temperature compressed air from final-stage discharge temperature (typically 150-180°C) to within 10°C of surrounding temperature, meeting process air requirements
• Lubricating Oil Cooling: keep gearbox and bearing lubrication system setup oil temperature within 60-70°C range, ensuring mechanical module longevity
• system setup Stability Assurance: Utilizes three-stage cooling structure (primary intercooler, secondary intercooler, aftercooler) to progressively minimize thermal load, preventing equipment shutdowns due to overheating

This cooler is compatible with Atlas Copco ZH10000 series compressors, supporting pressure ranges of 7-10.4 bar with single-unit processing capacity up to 10,000 m³/h. It's widely used in industries with stringent compressed air quality requirements such as chemical processing, food production, and automotive manufacturing.

2. Technical Features and Data Specifications

2.1 Structural Design Innovations

• Dual-Flow Split Structure: The cooler features independent air flow channels and cooling water channels. The air-side channels employ spiral baffle technology to create turbulent flow between tube bundles, enhancing convective heat transfer overall efficiency. The water-side channels fine-tune tube diameter and spacing to keep water velocity at 1.5-2.5 m/s, reducing scaling risks.
• Material Upgrades: Air-side heat exchange tubes use 316L stainless steel with corrosion resistance 3 times better than traditional carbon steel, especially suitable for environments with sulfur or chlorine-containing gases. The water-side utilizes naval brass (C46500) for both high thermal conductivity and chlorine ion corrosion resistance.

2.2 Heat Exchange operational performance Metrics

2.3 Intelligent Control system setup

• Closed-Loop Temperature Control: Integrated temperature sensors with compressor PLC system setup monitor cooling water inlet/outlet and air outlet temperatures in real-time, dynamically adjusting cooling pump frequency for optimal overall efficiency
• Self-Diagnostic Function: Built-in pressure sensors and flow switches trigger alarms and shutdown when water flow falls below 80% of rated value or pressure differential exceeds 0.2 bar
• Data Recording & Analysis: Supports Modbus TCP/IP protocol for uploading operational data (water temperature, pressure, heat exchange) to factory SCADA system setups for remote monitoring and predictive maintenance

2.4 Environmental Adaptability

• Anti-Clogging Design: Water-side channels feature built-in backflush connections for online cleaning; air-side channels use large diameter (DN50) tubes and removable baffles for easy dust removal
• Wide Temperature Operation: Supports cooling water inlet temperatures from 5-45°C, with optional electric heater and cooling tower system setups for stable operation in -20°C to 50°C environments

3. use case Scenarios and Case Studies

3.1 Food & Beverage Industry

At a Coca-Cola bottling plant in Fuzhou, three ZR oil-free compressors equipped with ZHC10000 coolers utilize an ER heat recovery system setup to convert waste heat from compressed air cooling into 75°C hot water for bottle preheating. This implementation achieved annual energy savings of 430,000 kWh per production line with 320 tons of CO2 reduction.

3.2 Petrochemical Industry

At an ethylene cracking facility, ZHC10000 coolers replaced traditional shell-and-tube coolers, solving clogging issues caused by ethylene gas condensate formation. By optimizing water flow and temperature gradients, compressed air outlet temperature stabilized below 35°C, ensuring molecular sieve adsorption tower overall efficiency and reducing unplanned downtime by 120 hours annually.

3.3 Automotive Manufacturing

Tesla's Shanghai Gigafactory painting workshop uses ZHC10000 coolers to supply temperature-stabilized compressed air for painting robots. The built-in PID temperature control module keep air dew point below -40°C, eliminating paint runs and orange peel defects while increasing first-pass yield to 99.5%.

4. Maintenance Strategies

4.1 Routine Inspection Checklist

• Water Quality Monitoring: Weekly checks of pH (7.0-8.5), conductivity (≤1500μS/cm), and chloride concentration (≤50ppm) with immediate treatment if超标
• Pressure Testing: Monthly measurement of water-side and air-side pressure differentials - cleaning required if exceeding design values by 20%
• Leak Inspection: Daily pre-startup checks of flange connections, gaskets, and welds, particularly at water inlet/outlet ports

4.2 Annual Maintenance Plan

• Chemical Cleaning: Annual 2-hour circulation cleaning with 5% citric acid offering for descaling and passivation
• operational performance Testing: Biannual third-party heat exchange capacity verification to assess aging
• Parts Replacement: Gaskets, sensors, and probes every 3 years; air-side tube bundles every 5 years

4.3 Troubleshooting Guide

5. Conclusion

The Atlas Copco ZHC10000 cooler demonstrates exceptional operational performance in enhancing centrifugal compressor stability and energy overall efficiency through its innovative dual-flow design, precision manufacturing, and intelligent control system setups. Its modular architecture and standardized interfaces enable quick adaptation to various compressor models while supporting seamless integration with plant energy management system setups. Proven reliability across food & beverage, petrochemical, and automotive use cases under demanding conditions is complemented by extended service life through proper maintenance focusing on water quality, pressure monitoring, and operational performance evaluation. As Industry 4.0 and carbon neutrality goals advance, future iterations incorporating AI algorithms and edge computing promise dynamic energy optimization and autonomous fault correction, provide smarter cooling offerings for industrial use cases.