In today’s industrial and refrigeration sectors, where efficiency, energy conservation and environmental protection are paramount, the SPL series evaporative condensers stand out as the preferred choice for numerous enterprises. This heat exchange equipment integrates cutting-edge technology with exquisite craftsmanship, dedicated to resolving condensation challenges across diverse complex operating conditions. The SPL series evaporative condenser integrates advanced heat exchange principles, ingeniously combining technologies such as latent heat utilisation from water evaporation and forced air convection heat transfer to create a high-performance condensing unit. Whether deployed in large-scale industrial refrigeration systems or commercial central air conditioning projects, it adapts precisely to deliver stable, reliable operation, providing sustained, efficient condensation assurance for the entire system.

In today’s industrial and refrigeration sectors, where efficiency, energy conservation and environmental sustainability are paramount, the SPL Series evaporative condensers stand out as the preferred choice for numerous enterprises. This heat exchange equipment integrates cutting-edge technology with exquisite craftsmanship, dedicated to resolving condensation challenges across diverse complex operating conditions. The SPL series evaporative condenser integrates advanced heat exchange principles, ingeniously combining technologies such as latent heat utilisation from water evaporation and forced air convection heat transfer to create a high-performance condensing unit. Whether deployed in large-scale industrial refrigeration systems or commercial central air conditioning projects, it adapts precisely, operates reliably and consistently, providing sustained, efficient condensation assurance for the system.

The BTC series closed cooling tower utilises water and air as cooling media, exchanging heat with the high-temperature working fluid within the coil. The high-temperature working fluid releases heat and transforms into ambient-temperature fluid. Internally equipped with a water distribution system, cooling coils, and water separators, externally fitted with a circulating water pump and electronic water treatment, with an axial fan mounted at the top. During operation, the axial fan creates a negative pressure environment inside. Cooling water is distributed uniformly across the coil surface via the water distribution system, enabling heat exchange between the high-temperature working fluid and the water and air surrounding the coils. This enhances the cooling effect significantly. After absorbing heat from the coil walls, the cooling water temperature rises sharply. Part of the cooling water vaporises into steam, while the non-vaporised portion returns to the sump tank. The sump pump then recirculates this water back into the water distribution system for continued operation. Water lost to the atmosphere is replenished promptly via a float valve in the sump tank, which regulates the water level.

In today’s industrial and refrigeration sectors, where efficiency, energy conservation and environmental protection are paramount, the T-type cross-flow evaporative cooler has distinguished itself as the preferred choice for numerous enterprises. This heat exchange equipment, integrating cutting-edge technology with exquisite craftsmanship, is dedicated to resolving condensation challenges across diverse complex operating conditions. The T-Type Cross-Flow Evaporative Cooler integrates advanced heat exchange principles, ingeniously combining technologies such as latent heat utilisation from water evaporation and forced convective air heat transfer. This creates a high-performance condensing unit. Whether deployed in large-scale industrial refrigeration systems or commercial central air conditioning projects, it adapts precisely, operates reliably and consistently, providing sustained, efficient condensation assurance for the system.

The BTC series closed cooling tower utilises water and air as cooling media, exchanging heat with the high-temperature working fluid within the coil. The high-temperature working fluid releases heat and transforms into ambient-temperature fluid. Internally fitted with a water distribution system, cooling coils, and water separators, externally equipped with a circulating water pump and electronic water treatment, with an axial fan mounted at the top. During operation, the axial fan creates a negative pressure environment inside. Cooling water is distributed uniformly across the coil surface via the water distribution system, enabling heat exchange between the high-temperature working fluid and the water and air surrounding the coils. This enhances the cooling effect significantly. After absorbing heat from the coil walls, the cooling water temperature rises sharply. Part of the cooling water vaporises into steam, while the non-vaporised portion returns to the sump tank. The sump pump then recirculates this water back into the water distribution system for continued operation. Water lost to the atmosphere is replenished promptly via a float valve in the sump tank, which regulates the water level.

Dry air coolers comprise finned tube bundles, fans, louvers, maintenance platforms, frames, and other user-specified components. During operation, the medium to be cooled flows through the tubes while the fan drives ambient air over the external fins. Utilising the temperature differential between the tube interior and exterior, coupled with the enhanced heat transfer surface provided by the fins, the system achieves condensation and cooling of the internal medium. This process conserves 100% of water resources. Employing ambient air as the cooling medium, this equipment finds extensive application across chemical processing, petrochemicals, refining, power generation, waste-to-energy plants, and steelworks.   The forced-draft air cooler features a bottom-mounted fan design, directing airflow uniformly upwards over the heat exchange tube bundle for stable heat transfer. The equipment boasts a compact structure with a small footprint, featuring a rational tube bundle layout that ensures stable heat exchange efficiency. Additionally, the fan operates with low noise levels and offers convenient maintenance. It is suitable for industrial refrigeration, chemical process cooling, and power system heat dissipation applications, particularly in scenarios with limited space or requirements for uniform airflow distribution. Combining energy efficiency with reliability, it assists enterprises in controlling operational costs.

Dry air coolers comprise finned tube bundles, fans, louvers, maintenance platforms, frames, and other user-specified components. During operation, the medium to be cooled flows through the tubes while fans drive ambient air over the external fins. Utilising the temperature differential between the tube interior and exterior, coupled with the enhanced heat transfer surface provided by the fins, the system achieves condensation and cooling of the internal medium, thereby conserving 100% of water resources. This equipment utilises ambient air as the cooling medium and finds extensive application across chemical processing, petrochemicals, refining, power stations, waste-to-energy plants, and steelworks.   The induced-draft air cooler employs an overhead fan configuration, directing air vertically downward through the heat exchange tube bundle for thorough heat transfer. Featuring a high heat transfer coefficient, it effectively lowers medium condensation temperatures, accommodates high-load and high-temperature conditions, exhibits strong resistance to wind interference, and ensures stable operation. The tube bundle employs corrosion-resistant materials combined with high-efficiency fin design, extending service life while ensuring optimal heat transfer performance. Widely deployed in large-scale chemical plants, refrigeration units, and petroleum refining facilities, it serves as a practical industrial-grade cooling solution.

Dry air coolers comprise finned tube bundles, fans, louvers, maintenance platforms, frames, and other user-specified components. During operation, the medium to be cooled flows through the tubes while fans drive ambient air over the external fins. Utilising the temperature differential between the tube interior and exterior, coupled with the enhanced heat transfer surface provided by the fins, the system achieves condensation and cooling of the internal medium, thereby conserving 100% of water resources. This equipment utilises ambient air as the cooling medium and finds extensive application across chemical processing, petrochemicals, refining, power generation, waste-to-energy plants, and steelworks. The sloping roof design employs a unique inclined structure to minimise airflow resistance while facilitating rainwater drainage, thereby preventing corrosion from accumulated surface water. Suitable for specialised installations such as rooftop mounting and confined spaces, the inclined tube bundle optimises airflow pathways for stable heat transfer efficiency. Its compact structure and flexible installation are complemented by premium heat exchange materials and precision manufacturing, delivering corrosion resistance, low energy consumption, and straightforward maintenance. Ideal for commercial building air conditioning, small-to-medium industrial cooling systems, and district cooling applications, it balances spatial efficiency with robust heat transfer performance.

The composite air cooler, with its innovative structural design and reliable performance, has become the preferred equipment in industrial cooling applications. The unit employs a composite structure combining counterflow full-coil fins with serpentine smooth tubes, significantly expanding the heat exchange surface area and establishing a robust foundation for efficient heat transfer. Concurrently, the integration of counter-flow air-water design and a four-sided air intake pattern maximises the air intake cross-sectional area, ensuring thorough contact between the airflow and the medium, thereby markedly enhancing heat exchange efficiency.   Regarding structural flexibility, the product builds upon a standard serpentine heat exchange configuration. It can be customised to accommodate multi-pass structures such as D-tube bundles, square tube bundles, or circular tube bundles, adapting to diverse operational heat exchange requirements. The outer casing employs galvanised aluminium-zinc sheet as standard, offering excellent corrosion resistance. Alternative materials including stainless steel and galvanised sheet are available, further enhancing the unit’s adaptability in challenging environments.   Furthermore, through optimised airflow and heat exchange design, the equipment effectively mitigates white mist phenomena, balancing practical performance with environmental friendliness. Its core advantages render it particularly suitable for applications involving large temperature differentials and regions with poor water quality. By ensuring stable heat exchange while reducing maintenance costs, it delivers efficient and durable cooling solutions for enterprises.

KTC cooling towers utilise a water distribution system to spray hot water into droplets or a water film. Water flows downward through the fill material while air moves upward or horizontally through the fill. This process harnesses water evaporation and heat transfer between cool air and hot water to dissipate waste heat from the water, enabling the reuse of circulating water in industrial applications. Operating Process: High-temperature water is conveyed to the top of the open cooling tower, where it is uniformly sprayed onto the fill layer via nozzles. Within the fill, the water forms a thin film. Concurrently, air enters the tower through inlets at the base, passing through the fill to ensure thorough contact between water and air. During this interaction, the water evaporates, lowering its temperature while simultaneously humidifying the air. The cooled water then flows back to the pump via the sump at the tower base, ready for recirculation.

• The ice storage coil is formed by continuously roll-welding high-quality steel strips using high-frequency welding technology, with no butt welds in the coil centre to minimise potential leakage points. • The entire ice storage coil undergoes hot-dip galvanisation for corrosion protection, ensuring enhanced product reliability. • Serpentine structure facilitates uniform ice melting and high heat transfer efficiency per unit area. • High cold storage capacity ensures superior system safety. • Long service life with low maintenance costs. • Primarily suited for district cooling systems, power generation projects, commercial and residential construction, office buildings, hotels, hospitals, and other high-power-load facilities.  

High Purity Mirror finish/electropolishing, precision up to Ra 0.2 μm Strict control of dissimilar metal contamination High Efficiency Convenient transfer, straightforward filling Easy cleaning, residue-free Stability GB/T 24511-2017 standard plates Plasma welding Precision-pressed heads Intelligent Remote transmission of pressure, temperature, and liquid level data GPS positioning Barrel ID management