What makes our absorption chillers unique? Explore the innovative features and design elements that distinguish our products. From intelligent engineering to user-friendly interfaces, uncover how we are shaping the future of cooling technology.
A. Reliability
The Inline Falling Auto Purge System
Offers a comprehensive solution to ensure the continual vacuum integrity of chiller systems. With its innovative design and automated functionality, this system effectively maintains the necessary vacuum levels within the chiller, ensuring optimal performance and longevity. By seamlessly integrating into existing chiller setups, it provides a permanent guarantee of vacuum, mitigating the risk of any potential disruptions or malfunctions. This technology represents a significant advancement in chiller maintenance, offering peace of mind and reliability for industrial and commercial applications.
BROAD Advantages :
- BROAD’s unique technology excels in collecting non-condensable gas entirely, ensuring comprehensive gas management within chiller systems. This capability is pivotal for maintaining optimal performance and efficiency.
- Stable purging mechanisms are integral to BROAD’s technology, ensuring consistent and reliable operation. This stability minimizes the risk of system disruptions, contributing to uninterrupted chiller functionality.
- Chiller corrosion, often caused by the presence of non-condensable gas, is effectively mitigated by BROAD’s innovative approach. By eliminating gas-related corrosion, the technology enhances the longevity and durability of chiller systems.
- The automatic purging system implemented by BROAD eliminates the need for manual operation, streamlining maintenance processes and reducing labor costs. This automation enhances operational efficiency and frees up resources for other tasks.
Conventional :
- Complete collection of non-condensable gas remains a challenge within current chiller systems, leading to potential performance issues and operational concerns.
- Ejector-based auto-purge systems, while designed to address non-condensable gas, suffer from instability and low reliability, undermining their effectiveness in maintaining optimal chiller performance.
- Although palladium tube devices offer a solution for purging hydrogen generated in corrosion processes, they do not prevent the corrosion itself, leaving chiller systems vulnerable to damage.
- It’s important to recognize that non-condensable gas can result in a range of issues, including compromised vacuum levels, decreased cooling efficiency, corrosion, and erratic system operation, emphasizing the critical need for robust gas management solutions in chiller technology.
Upward Nozzle Spraying
Upward Nozzle Spraying is an innovative technique designed to counteract the decrease in cooling capacity often experienced in chiller systems. By directing the spray upward, this method effectively mitigates the factors contributing to reduced cooling efficiency. By preventing heat buildup and maintaining optimal operating conditions, Upward Nozzle Spraying ensures consistent and reliable cooling performance, enhancing the overall efficiency and effectiveness of chiller systems. This approach represents a proactive solution to address potential cooling capacity issues, ultimately optimizing the functionality and longevity of chiller systems in various applications.
BROAD Advantages :
Innovative solution utilizing upward spraying from nozzles, followed by a downward flow onto the tube cover and circulation within copper tubes. This method ensures that the upward nozzles remain free from clogging, thereby preventing any reduction in cooling capacity. Moreover, the uniform distribution of the solution throughout the system enhances the overall cooling efficiency, contributing to optimized performance and reliability in chiller operations.
Conventional :
The occurrence of nozzle clogging poses a significant challenge, leading to a reduction in cooling capacity. Additionally, uneven distribution of the solution exacerbates this issue, further diminishing the overall effectiveness of the cooling process. These challenges highlight the limitations of traditional methods in maintaining consistent and efficient cooling performance in chiller systems.
Auto Decrystalization
Auto Decrystallization is a groundbreaking feature designed to completely eliminate the risk of crystallization in chiller systems. Through automated processes and advanced technology, this system continuously monitors the conditions within the chiller, detecting any signs of crystallization before they can develop into significant issues. By promptly initiating decrystallization procedures as needed, this feature ensures that the chiller remains free from crystallization, thereby preventing potential damage and maintaining optimal performance. With Auto Decrystallization in place, operators can rest assured that their chiller systems are protected against the harmful effects of crystallization, reducing the need for manual intervention and minimizing downtime.
BROAD Advantages:
- The self-diagnose system implemented by BROAD eliminates the risk associated with auto-decrystallization. This advanced feature continuously monitors chiller conditions, ensuring prompt intervention if crystallization is detected.
- In the event of a power failure, the chiller automatically performs a self-check upon restart, ensuring that crystallization is prevented during operation.
Conventional:
- Conventional systems lack a diagnostic mechanism for auto-decrystallization. As a result, if crystallization occurs, the chiller must be shut off, requiring manual intervention to resolve the issue.
- Crystallization poses significant risks in conventional absorption chiller systems, potentially leading to severe problems, including physical damage to the chiller components.
Whole Chiller Filtration
Whole Chiller Filtration represents a comprehensive solution aimed at preventing the decrease in cooling capacity typically encountered in chiller systems. By implementing filtration mechanisms throughout the entire chiller system, this approach effectively removes contaminants and impurities that can obstruct the flow of coolant and hinder heat transfer. By ensuring a clean and unobstructed pathway for the coolant, Whole Chiller Filtration maintains optimal cooling efficiency, thereby safeguarding against any potential reduction in cooling capacity. This proactive measure enhances the reliability and longevity of chiller systems, ensuring consistent performance in various industrial and commercial applications.
BROAD presents several advantages in its chiller system design:
- All pump inlets feature auto backwash filters, effectively maintaining the cleanliness of the solution and providing protection for canned pumps.
- Stainless steel filters are integrated into cooling water inlets and chilled/heating water inlets, preventing clogging within the chiller and fan coils.
- The need for strainer dismantling for cleaning is eliminated, significantly reducing maintenance work and associated downtime.
Canned Pump Advantages:
- Equipped with screw graphite bearings, the canned pump can rotate at high speeds without sustaining damage, thus extending its lifespan.
- The canned pump is fully welded with the motor, ensuring tightness and preventing leakage.
- The completed canned design shields against external electromagnetic interference, resulting in stable operation and enhanced reliability.
Conventional:
pumps are prone to clogging, increasing the risk of motor damage and subsequent issues such as blocked spraying holes and fouling of copper tubes. This susceptibility to clogging not only compromises the efficiency of the system but also leads to frequent maintenance requirements and potential downtime. Overall, these challenges highlight the limitations of traditional pump designs and underscore the need for more robust and reliable solutions in chiller systems.
3 Level flow Switches in Evaporator
The incorporation of 3 Level Flow Switches in the evaporator represents a significant advancement in chiller technology, aimed at eliminating the occurrence of frozen tubes. By precisely monitoring the flow levels within the evaporator, these switches can detect any deviations from the optimal flow conditions. In the event of insufficient flow, the switches trigger appropriate actions to prevent the formation of ice and subsequent tube freezing. This proactive measure not only ensures uninterrupted chiller operation but also safeguards against potential damage and costly repairs associated with frozen tubes. Overall, the implementation of 3 Level Flow Switches enhances the reliability and efficiency of chiller systems, providing peace of mind for operators and reducing maintenance requirements.
BROAD Advantages:
- The 1st stage (B1) and 2nd stage (B1A) flow switches are intricately linked to the chiller’s Programmable Logic Controller (PLC), continuously monitoring chilled water flow. Should it drop below a predefined safety limit, the PLC takes immediate action, shutting off the heat source valve, refrigerant pump, cooling water pump, and cooling air fan to avert freezing.
- Additionally, the 3rd stage flow switch (B3) is directly connected to the cooling water pump. In the event of low or interrupted chilled water flow, this switch halts the cooling water pump instantly, thereby preventing freezing.
- Through this three-tier chilled water flow switch protection mechanism, BROAD ensures 100% prevention of freezing under any conceivable scenario, safeguarding the chiller system from potential damage and operational disruptions.
Conventional
- In conventional systems, the absence of chilled water flow switches leaves the system vulnerable to issues such as freezing. Without these safeguards in place, the occurrence of chilled water freezing becomes more likely, posing a significant risk to the integrity and functionality of the system.
- Furthermore, if a conventional system does incorporate a flow switch, it typically only includes a 1st stage switch. However, this setup often lacks reliability, and there’s a heightened risk of control failure. Such failures can lead to scenarios where chilled water freezing still occurs despite the presence of the flow switch, highlighting the limitations of conventional control mechanisms in ensuring system stability and preventing freezing-related issues.
Evaporator Water Box Filter
The inclusion of an Evaporator Water Box Filter serves as a proactive measure to prevent the occurrence of frozen tubes within the chiller system. By filtering the water within the evaporator, this component effectively removes impurities and debris that could otherwise contribute to blockages and disruptions in the flow of water. By maintaining a clean and unobstructed pathway, the Evaporator Water Box Filter helps to ensure consistent and reliable operation, safeguarding against the formation of ice and subsequent freezing of tubes. This preventative approach enhances the overall efficiency and longevity of the chiller system, reducing the risk of downtime and costly repairs associated with frozen tubes.
BROAD Advantages:
- The inclusion of filtration in BROAD systems effectively removes impurities from chilled water, safeguarding against tube clogging and potential damage.
- This filtration capability significantly reduces the risk of frozen tubes, ensuring uninterrupted operation and system reliability.
Conventional:
- In conventional systems, impurities present in the water circulation can lead to damage to fan coils.
- Lack of filtration means that these impurities can accumulate and clog copper tubes, posing a risk of tube freezing and subsequent system malfunction.
Temperature-control control room
The implementation of a temperature-controlled control room provides crucial protection for electronic components within the chiller system. By maintaining a stable and optimal temperature environment, this feature safeguards sensitive electronic parts from potential damage caused by extreme temperature fluctuations. This proactive measure ensures the reliability and longevity of electronic components, reducing the risk of malfunctions and downtime. Overall, the temperature-controlled control room enhances the operational efficiency and performance of the chiller system, providing peace of mind for operators and minimizing maintenance requirements.
BROAD Advantages:
BROAD’s technology includes temperature monitoring and control features, accompanied by cooling fans specifically designed to safeguard electronic parts. This comprehensive approach extends the lifespan of control components, ensuring long-term reliability and performance.
Conventional:
Conventional systems lack temperature monitoring and control capabilities and typically do not incorporate cooling fans to protect electronic parts. Constant ventilation in these systems can introduce heavy dust accumulation, leading to reduced reliability and shorter lifespans for control components.
Separate heating
Introducing Separate Heating functionality, BROAD’s chiller system revolutionizes efficiency by offering simultaneous cooling, heating, and hot water capabilities within a single unit. This innovative design optimizes space utilization and resource management, providing a versatile solution for diverse heating and cooling needs. By integrating separate heating functionalities, BROAD’s chiller streamlines operations, reduces energy consumption, and enhances overall system performance. This integrated approach represents a significant advancement in chiller technology, offering unparalleled convenience and flexibility for various applications.
BROAD Advantages:
- In BROAD’s design, the main shell is isolated during heating mode, resulting in increased reliability and stability.
- This innovative approach ensures the seamless provision of cooling, heating, and hot water functions within a single chiller unit.
- By preventing cooling capacity decrease, BROAD’s system maintains consistent performance over time, effectively doubling its lifespan.
Conventional:
- Conventional systems require the main shell to remain in operation during heating mode, limiting the ability to provide simultaneous cooling and heating functions.
- This setup often leads to lower reliability and poses a significant risk of decreased cooling capacity after years of operation, highlighting the limitations of traditional chiller designs.
Fire tube HTG structure
Introducing the Fire Tube HTG Structure, BROAD’s chiller system revolutionizes efficiency by offering simultaneous cooling, heating, and hot water capabilities within a single unit. This innovative design optimizes space utilization and resource management, providing a versatile solution for diverse heating and cooling needs. By integrating a fire tube structure for heating, BROAD’s chiller streamlines operations, reduces energy consumption, and enhances overall system performance. This integrated approach represents a significant advancement in chiller technology, offering unparalleled convenience and flexibility for various applications.
BROAD Advantages:
- The Fire Tube HTG Structure in BROAD’s chiller system is designed for easy cleaning of tube soot, ensuring optimal heat efficiency.
- By minimizing soot corrosion, BROAD’s design extends the lifespan of tubes, enhancing the longevity and reliability of the system.
- Additionally, the structure facilitates straightforward leakage checks and maintenance, further reducing downtime and operational disruptions.
Conventional:
- In conventional systems, the inability to clean soot leads to decreased heat transfer efficiency, compromising overall performance.
- The presence of serious soot corrosion in conventional designs often results in a shortened lifespan for the heating tubes, necessitating frequent replacements.
- Additionally, the difficulty in conducting leakage checks and the risk of complete HTG replacement in case of leakage further highlight the challenges and limitations of traditional chiller designs.
HTG 8-kind safety protection
The implementation of an 8-kind safety protection system for the HTG (Heating Tube Generator) in BROAD’s chiller technology represents a significant advancement in safety and risk mitigation. This comprehensive system is designed to eliminate the risk of HTG explosions by addressing potential hazards through multiple layers of protection. From precise temperature monitoring to pressure regulation and leak detection, each safety measure works in tandem to ensure the safe and reliable operation of the heating tubes. By proactively identifying and mitigating risks, BROAD’s 8-kind safety protection system enhances user confidence and peace of mind while maximizing the safety and efficiency of the chiller system.
Whole unit shot blasting
BROAD’s investment in the world’s largest whole unit shot-blasting facilities underscores its commitment to innovation and quality in chiller manufacturing. With these facilities, capable of shot-blasting chillers of all dimensions, including the largest units like the BE1000 (3,307RT), BROAD ensures thorough rust cleaning on chiller surfaces. This process not only enhances the aesthetic appearance of the chiller but also strengthens the adhesion of paint coatings, prolonging their lifespan. Moreover, by eliminating the risk of leakage caused by corrosion, BROAD’s shot-blasting facilities contribute to the durability and reliability of its chiller units, providing customers with high-quality, long-lasting solutions for their cooling needs.
Function of whole unit blasting:
- Whole unit shot-blasting also releases the residual stress, eliminates welding seam leakage and tube expansion caused by structure deformation. This is an essential process for chiller’s good performance and long life-span.
- Whole unit shot-blasting is a must treatment for the chiller to ensure chiller performance and life.
BROAD Testing Platforms
The testing facility at our building is a testament to our commitment to quality and performance. Designed to evaluate the complete functionality of our chillers in cooling, heating, and hot water operations, it stands as the largest and most advanced whole unit testing platform globally.
Every chiller undergoes rigorous testing in accordance with pre-defined specifications before shipment. We take pride in our transparency and invite our customers to witness the testing process firsthand, ensuring that the chillers meet their expectations and requirements.
This comprehensive testing approach not only validates the performance and reliability of our chillers but also instills confidence in our customers, reaffirming our dedication to delivering high-quality products that exceed industry standards.
Main testing and inspection devices
The Optical Emission Spectrometer is an indispensable tool in material analysis and product development. Capable of instantly analyzing metals in concentrations as low as one part per million by weight, this device provides invaluable insights into the composition of various materials.
Moreover, it can measure concentrations of more than 20 elements simultaneously, making it highly versatile for analyzing metals such as copper, steel, stainless steel, and welding materials.
This capability is essential for raw material examination, ensuring the quality and consistency of inputs, as well as for product development, enabling engineers to optimize formulations and meet performance specifications.
Overall, the Optical Emission Spectrometer plays a vital role in quality control and innovation across a wide range of industries.
Atomic absorption spectrometer:
The Atomic Absorption Spectrometer is a powerful tool for analyzing liquids with exceptional precision. Capable of instantaneously analyzing any liquid to a precision of one part per billion by weight, it provides invaluable insights into the composition of solutions and their constituent materials.
This device is particularly useful for detecting corrosion in chillers, as it can accurately identify trace elements indicative of corrosion processes. By monitoring these elements, maintenance intervals can be determined more effectively, and the lifespan of chillers can be forecasted with greater accuracy.
Overall, the Atomic Absorption Spectrometer plays a crucial role in ensuring the reliability and longevity of chiller systems, as well as in optimizing maintenance schedules to minimize downtime and maximize efficiency.
Auto material testing machine:
The Auto Material Testing Machine is a versatile and precise tool used for evaluating the mechanical properties of various materials. Capable of testing parameters such as tensile strength, deformation, elongation, and curvature, it provides valuable insights into the structural integrity and performance characteristics of materials.
Additionally, this machine can conduct fatigue and destructive tests on raw materials, helping to assess their durability and resilience under different conditions. Its high precision, with measurements accurate to one thousandth of a millimeter and a Newton in dynamics, enables detailed analysis of material behavior.
Remarkably sensitive, the Auto Material Testing Machine can even detect minute differences in tension, such as those between two individual hairs. This level of precision makes it an indispensable tool for quality control, research, and development across various industries.
BROAD Titanium Tube Material
Why Titanium?
| Copper | Stainless Steel | Titanium | |
| (Chlorine) Cl | Anti-corrosion only at low temp. and low concentration | Anti-corrosion level is different | No |
| Seawater scour | Less than 1.2m/s | 5-7m/s | No |
| Ammonia, Amine | Serious corrosion | No corrosion | No |
| Polluted air and water | Corrosion | Light corrosion, Chlorine corrosion | No |
Leackage Cause problem:
- Scale buildup, which can lead to electrochemical corrosion.
- Scour corrosion caused by abrasive particles in the fluid.
- Issues arising from unprofessional tube cleaning practices.
- Stainless steel (SS) tube cracking due to exposure to chlorine.
Conclusion:
- Vacuum: Leakage poses the primary risk to vacuum integrity, fundamentally impacting chiller efficiency and lifespan.
- Copper tube: While offering good thermal efficiency, copper tubes have low anti-corrosion performance, especially thin tubes. Non-timely and unprofessional water treatment can easily lead to leakage.
- Stainless steel (SS) tube crack due to chlorine exposure.
- Titanium: Considered the ultimate material for anti-corrosion and vacuum protection, titanium components can extend the chiller’s design lifespan to 60 years.
B. Energy Saving
The Whole Unit Factory-Mounted Heat/Cold Insulation feature offers comprehensive insulation for the entire chiller unit, providing effective thermal management for both heating and cooling operations. By integrating insulation directly onto the chiller during the manufacturing process, this feature ensures consistent and efficient temperature control, minimizing heat loss during heating and preventing heat gain during cooling. This factory-mounted insulation not only enhances the energy efficiency of the chiller but also simplifies installation and reduces the risk of insulation gaps or inconsistencies. Overall, it represents a practical and reliable solution for maintaining optimal operating conditions and maximizing performance in various industrial and commercial applications.
BROAD Advantages:
- Precise quality control and chiller factory performance testing guarantee the vacuum condition of the chiller, while factory-mounted insulation reflects our confidence in top-quality manufacturing.
- The insulation exhibits excellent heat insulation performance, maintaining stable temperatures within the chiller unit.
- Factory-mounted insulation ensures reliable quality, reducing the risk of insulation gaps or inconsistencies.
- Easy leak checks and maintenance procedures are facilitated by the integrated insulation design.
- Customers incur no additional costs for insulation, providing peace of mind and convenience.
- The insulation effectively protects the main shell, prolonging the chiller’s lifespan and enhancing durability.
- The aesthetic shape and simplified structure contribute to the overall appeal and functionality of the chiller unit.
Conventional:
- Insulation can only be applied after the chiller finishes commissioning on-site, often due to uncertainty about achieving chiller vacuum conditions. This delay in insulation can prolong the setup process and increase downtime.
- Poor insulation quality can lead to higher fuel consumption, as the chiller struggles to maintain desired temperatures efficiently.
- Maintenance becomes inconvenient without factory-mounted insulation, potentially leading to delays or difficulties in accessing critical components.
- The lack of insulation exposes the chiller to increased risk of damage and shortens its operational lifespan, impacting long-term reliability and efficiency.
Plate heat exchanger
The Plate Heat Exchanger represents a significant advancement in chiller technology, offering improved efficiency and capacity. With this innovation, the Coefficient of Performance (COP) can be enhanced by 6% to 8%, leading to greater energy efficiency and cost savings. Additionally, the capacity of the chiller can be increased by 8% to 15%, allowing for higher cooling/heating output without increasing the size or footprint of the unit. Overall, the Plate Heat Exchanger is a key technology in optimizing chiller performance and meeting the growing demands for energy-efficient cooling and heating solutions.
Plate Heat Exchanger Advantages:
- High heat exchanging efficiency, typically 3 to 5 times that of tube heat exchangers. This increased efficiency ensures optimal heat transfer and improved performance.
- Maintains a low differential temperature, typically ranging from 2℃ to 5℃. This tight temperature control ensures consistent performance and efficient operation.
- Compact and lightweight design, with a size that is only around 1/5 of tube-type heat exchangers. This smaller footprint allows for easier installation and space-saving solutions, making it ideal for various applications where space is limited.
Conventional Tube Heat Exchanger:
- Low heat exchanging efficiency, typically resulting in a significantly lower efficiency compared to plate heat exchangers. This inefficiency can lead to higher energy consumption and reduced performance.
- Maintains a high differential temperature, typically ranging from 20℃ to 30℃. This wide temperature difference can result in inconsistent performance and inefficiencies in heat transfer.
- Incompact and jumbo design, with a larger footprint compared to plate heat exchangers. This larger size can make installation more challenging and may require more space, limiting flexibility in placement and increasing overall costs.
Water buffle in evaporator
The Water Baffle in the evaporator serves as a crucial component to prevent a decrease in cooling capacity. By strategically directing the flow of water within the evaporator, the baffle helps to optimize heat transfer efficiency and maintain uniform temperature distribution across the cooling surface. This ensures that the evaporator operates at peak performance, maximizing cooling capacity and overall system efficiency. Additionally, the water baffle helps to minimize the risk of uneven cooling and hot spots, which can lead to decreased performance and potential system malfunctions. Overall, the inclusion of a water baffle in the evaporator contributes to reliable and consistent cooling performance, enhancing the functionality and longevity of the chiller system.
BROAD’s Advantages:
- Utilizes a W-shaped and double layers design to efficiently recycle sprayed refrigerant drops, directing them back to the refrigerant pan for repeat spraying. This prevents the loss of sprayed refrigerant, contributing to energy savings.
- The horizontal and vertical baffle design increases the gap between two baffles, allowing refrigerant vapor to flow smoothly through the evaporator.
Conventional:
- Without baffles in the evaporator, there is a higher risk of cooling capacity decrease and energy waste due to inefficient utilization of refrigerant and uneven distribution of cooling.
Refrigerant anti-overflow & refrigerant pump inverter
The Refrigerant Anti-Overflow system, coupled with a Refrigerant Pump Inverter, represents a significant advancement in energy conservation and precise temperature control in chiller systems. The Anti-Overflow system prevents the overfilling of refrigerant in the evaporator, ensuring optimal operating conditions and preventing energy wastage.
Meanwhile, the Pump Inverter allows for variable-speed operation of the refrigerant pump, enabling fine-tuned control of the chilled water outlet temperature. This not only enhances energy efficiency by matching pump speed to current cooling demands but also ensures consistent and precise temperature control. Overall, the combination of these technologies contributes to significant energy savings and improved performance in chiller systems.
BROAD Advantages:
- Utilizes three refrigerant level probes for enhanced safety and efficiency: two probes for refrigerant pump start-up/shut-off and one for anti-overflow measures, preventing the overfilling of refrigerant and ensuring optimal operating conditions.
- All chillers come equipped with a refrigerant pump inverter, allowing for precise adjustment of refrigerant spraying quantity and accurate control of chilled water outlet temperature. This ensures optimal performance and energy efficiency.
- Incorporates a high-level probe to prevent refrigerant water overflow and cooling capacity decrease during part-load operation, maintaining consistent performance.
- A low-level probe is implemented to automatically shut off the refrigerant pump in case of insufficient refrigerant water, protecting the pump from damage and ensuring system reliability.
Conventional:
In conventional chiller systems, when operating at partial load, the excess refrigerant water may overflow into the absorber. This overflow leads to a significant loss in cooling capacity and results in energy wastage. The inefficiency of managing refrigerant water levels during varying load conditions underscores the need for more advanced control mechanisms to optimize performance and energy efficiency in chiller operations.
Inverter controlled cooling water
Broad Advantages:
- Integration of control interfaces and/or inverters for cooling water pumps and cooling tower fans streamlines the operation of the cooling water system.
- Achieves significant electricity consumption savings of 40% to 60% in the cooling water system, enhancing overall energy efficiency.
- Enables precise regulation of the cooling water temperature, ensuring optimal performance and enhancing the reliability of the chiller system.
Conventional:
Control interfaces and inverters for cooling water pump and cooling tower fan are optional.
Real time COP indication
BROAD’s Advantages:
- Confidence in Chiller Performance: BROAD stands behind the performance of its chillers, ensuring reliability and efficiency in operation.
- Proactive Abnormality Detection and Resolution: BROAD’s monitoring systems enable the timely discovery and resolution of any abnormalities, preventing potential issues before they escalate.
- Ensuring Optimal Chiller Operation: By promptly addressing abnormalities and implementing preventive measures, BROAD ensures that its chillers operate under optimal conditions, maximizing performance and longevity.
Conventional:
- COP indication is not available
- The end users have no knowledge about huge energy waste
Water Quality Management System
Water Softener Upon Iron Exchange Colophony:
- Applies to all types of water quality.
- Decreases water hardness effectively.
- Minimizes scaling issues, preserving the integrity of the system and enhancing efficiency.
Auto Dosing System:
- Periodically charges antiscale and antiseptic substances to the cooling water system based on real-time electric conductance detection.
- Eliminates legionella bacteria, ensuring safety and cleanliness.
- Prevents scaling, guaranteeing consistent cooling output.
- Reduces corrosion, extending the lifespan of tubes and components.
Conventional:
- No integrated auto-dosing system
- Easily scaling which causes cooling capacity decrease
- Improper cleaning cause damage to tubes
Dry back rear flue chamber
BROAD Advantages:
- Ensures 100% complete combustion, maximizing the efficiency of the combustion process.
- Minimizes soot production, leading to higher efficiency and reduced emissions.
- Eliminates black smoke, enhancing environmental friendliness and compliance with emission regulations.
Conventional:
- Incomplete combustion often leads to fuel waste, reducing overall efficiency and increasing operating costs.
- Excessive soot production results in lower efficiency and poses a high risk of soot corrosion, potentially damaging components and reducing system lifespan.
HTG Condensate Recovery
BROAD Advantages:
- Achieves 700 kW of free cooling for every 1000 kW of hot water requirement, maximizing energy efficiency and reducing operating costs.
- Reduces cooling water flow by 21%, further enhancing energy savings and promoting sustainable operation.