var textForPages =["1\u000AHIGH\u000APERFORMANCE\u000ABUILDING\u000AMALAYSIA\u000AISSUE NO. 5, JUNE 2026","2\u000AEDITORIAL\u000AIn this issue of High-Performance Building Malaysia (HPBM #5), ASHRAE Malaysia is proud to\u000Ashowcase the ASHRAE Technology Award (2025) winning design of Bridge Data Centres (BDC)\u2019s\u000AMY06 Campus 1 data center in Sedenak, Johor. BDC is a Singapore-headquartered hyperscale data\u000Acentre provider delivering high-performance, next-ready infrastructure across Asia Pacific. Backed\u000Aby Bain Capital, BDC operates in Malaysia, Thailand, India and other high-growth markets, with the\u000Acapability to deliver up to 3 gigawatts (GW) of capacity globally by 2030 through partnerships with\u000Asister platforms in Europe and the United States.\u000ALike many of the data centers constructed, the BDC MY06 Campus 1 fulfills the Malaysian\u000Agovernment\u2019s aspiration to attract multi-national cloud and data center operators into the country,\u000AThe MY06 project received tremendous support and approval from various levels of government\u000Aagencies and ministries in moving the project ahead. The success of BDC\u2019s MY06 project serves as\u000Aan impetus to the growth of Malaysia\u2019s Digital Economy and the advancement of Malaysia as a\u000Aregional IT hub. 1\u000ATrend of data centers in Malaysia\u000AAs of March 2026, there are 44 data centers in Malaysia, of which Selangor and Johor have 23\u000A(52.3%) and 14 (31.8%) respectively 2. The trend of the market data in Malaysia is projected to grow\u000Arapidly at a CAGR of 19.55% from 2026 to 2031 3\u000A.\u000AMalaysia\u2019s data center sector has attracted RM184.7 billion (US$43.6 billion) in investments in\u000Arelated projects between 2021 and 2024. However, data center energy consumption in Malaysia\u000Ais projected to surge to over 5,000 MW by 2035, i.e., 40 per cent of Peninsular Malaysia\u2019s present\u000Apower capacity, or 11.1% of Malysia\u2019s projected power capacity in 2035 4. With such intense\u000Ademand for energy and water, it is imperative for new data centers to be designed and built\u000Asustainably with strong emphasis on high energy and water consumption efficiency.\u000A1 BDC, \u201CHow Bridge\u2019s MY06 is Rewriting the Rules of Data Centre Construction\u201D, retrieved on 9th April 2026 from:\u000Ahttps://www.bridgedatacentres.com/how-bridges-my06-is-rewriting-the-rules-of-data-centre-construction/\u000A2 PoiData.io, \u201CList of Data Centers in Malaysia\u201D, retrieved on 9th April 2026 from: https://www.poidata.io/report/data-\u000Acenter/malaysia\u000A3 Mordor Intelligence, \u201CMalaysia Data Center Market\u201D, retrieved on 9th April 2026 from:\u000Ahttps://www.mordorintelligence.com/industry-reports/malaysia-data-center-market\u000A4 ISEAS Yusof Ishak Institute, Perspective, \u201CData Centres, Energy Demand and Sustainability: Can Malaysia Strike the\u000ARight Balance?\u201D, Issue 2025, No. 43, 12 June 2025","3\u000ABridge Data Centres MY06 Campus 1 Building 1 (MY06C1B1) is a data center located at Sedenak\u000ATech Park (STeP). It is a purpose-built, modular-design data center custom-developed for hyperscale\u000Aclients with a Gross Floor Area (GFA) of 5,275 m\u00B2. It has a maximum IT capacity of up to 20MW and\u000Ais designed to TIA-942 Tier III standard which ensures concurrently maintainable infrastructure,\u000Aallowing planned maintenance without downtime. The facility is designed and constructed in\u000Aalignment with international best practices for energy efficiency and complies with the requirements\u000Aof ASHRAE Standard 90.1 standard for buildings.\u000ADesigned in December 2021 and completed in November 2022 during the COVID-19 pandemic,\u000Athe project exemplifies innovation in rapid deployment and showcases efficient, modular\u000Aconstruction using Prefabricated Prefinished Volumetric Construction (PPVC) to enable fast-track\u000Adelivery with sustainable outcomes. The project incorporates hybrid cooling strategies, including\u000Acold-plate liquid cooling and spray-assisted Indirect Evaporative Cooling (IDEC), which are\u000Aengineered to enhance efficiency in subtropical climate. This place it among the highest-performing\u000Aand environmentally responsible data centers in the region.\u000AFig. 1: View of the completed MY06 Campus 1 Building 1","4\u000AFig. 2: Floor layout of MY06C1B1\u000AEnergy efficiency\u000ABased on the most recent 12-month data trended from the building\u2019s Building Management System,\u000AMY06C1B1 achieved a low annualized Power Usage Effectiveness (PUE) of 1.295 (Table 1 & Fig. 3)\u000Awhich surpasses the Platinum baseline set by BCA-IMDA Green Mark for Data Centres (GMDC:\u000A2024). As of April 2025, the building was operating with an IT load of 11.2 MW, which is 56% of its\u000A20 MW total design capacity. (Fig. 4).\u000AThe IT Power Chain Efficiency was calculated to be at 94.55%, reflecting minimal energy losses\u000Aacross transformers, UPS, and distribution using integrated and compact electrical modules as high\u000Aenergy performance solution. (Fig. 5)","5\u000ATable 1: Overall Annual Energy Consumption Breakdown (May 2024 to April 2025)\u000ASystem/Equipment Energy Consumption (kWh)\u000AICT Equipment (at PDU) 98,385,162.06\u000ALiquid Cooling System (Closed Loop Cooling Tower & CDU) 2,445,602.03\u000AAir Cooling System (CRAC, AHU, Spray Pump, & Dehumidifier) 16,686,590.11\u000AMechanical Ventilation 97,111.52\u000ADomestic Water Systems 46,602.00\u000ALighting and small power 500,057.76\u000AFire Protection & ELV Systems 106,316.85\u000AReceptacle Equipment 178,358.27\u000AIT Power Chain Losses 5,362,241.02\u000AAncillary Power Chain Losses 3,596,543.86\u000ATotal Facility Energy 127,404,585.48\u000AFig. 3: Measured Energy Consumption (May 2024 to April 2025)","6\u000AFig. 4: PUE Benchmark with GMDC: 2024\u000AFig.5: High energy performance integrated electrical modules","7\u000AThe Air-conditioning & Mechanical Ventilation (ACMV) system\u000AMY06C1B1 adopts a hybrid cooling configuration with a liquid-to-air cooling ratio of 50:50. Based\u000Aon total annual cooling system (liquid cooling + air cooling) energy consumption of 19.2 GWh and\u000Atotal annual IT energy consumption of 98.4 GWh (Table 1), the overall system achieved an effective\u000ACOP exceeding 5.14. Track record with overall COP higher than 5.0 puts the project at good stead\u000Aand among the category of new cooling technology with excellent efficiency, according to the COP\u000Aclassification given by Hartman 5 (Fig. 6).\u000AFig.6: COP classification 5\u000AThe liquid-cooling solution achieves a COP of over 20. The liquid cooling system comprises a closed-\u000Aloop configuration, incorporating cooling towers, spray pumps, and Coolant Distribution Units\u000A(CDUs). Notably, the Technology Cooling System (TCS), which provides coolant fluid to the server\u000Aracks, operates at elevated water temperatures of 40/45\u00B0C, with the facility cooling water loop\u000Arunning at 35/40\u00B0C. These higher operating temperatures are achievable by using cooling towers\u000Aalone and negate the need for chillers, resulting in improved system efficiency and lower energy\u000Ademand. (Fig. 7)\u000A5. T. Hartman, \u201CAll-Variable Speed Centrifugal Chiller Plants\u201D, ASHRAE Journal, Vol. 43, No. 9, pp. 43-51, September\u000A2001.","8\u000AFig. 7: Schematic diagram of liquid cooling system\u000AAs for the air-cooling system, the COP of the air-cooling solution (Indirect Evaporative Cooling [IDEC]\u000Aand Computer Room Air-conditioning [CRAC]) is 2.95. The system integrates IDEC, DX AHUs, DX\u000ACRACs, and DX in-row units, each optimized for specific zones within the data halls. The IDEC serves\u000Aas the primary air-side strategy and is equipped with spray-assisted heat exchangers to enhance\u000Aperformance in high outdoor temperature conditions. DX CRACs and DX in-row units are used as\u000Asecondary air-cooling systems for smaller data halls with less rack density. Hot aisle containment\u000Ais implemented across all data halls to maximize airflow separation and ensure efficient heat\u000Aremoval (Fig. 8).","9\u000AFig. 8: Schematic of air-cooling system\u000A[MAU = Main Air Unit, DH = Data Hall]\u000AWater efficiency\u000AThe facility achieved a Water Usage Effectiveness (WUE) of 1.493 m\u00B3/MWh/year, demonstrating\u000Asustainable water management in support of sustainable operations (Fig. 9). The lower than\u000Aindustry average WUE of 2.0 m3/MWh/year is achieved through a combination of measures.\u000ACooling towers are operated at a high cycle of concentration of about 10, maintained by automatic\u000Achemical dosing, which significantly reduces blowdown and water demand.\u000AIndirect Evaporative Cooling (IDEC) system with water spray advanced technology achieves indirect\u000Aevaporative cooling with at least 25% higher water usage efficiency compared to wet media type\u000AIDEC and Direct Evaporative Cooling (DEC) in the following manner (Fig. 10):\u000A\u2022 IDEC prevents a humidity increase in the treated data center air stream by creating a\u000Aseparate wet channel to achieve latent heat of vaporization at lower water consumption compared\u000Ato DEC as it does not add moisture to the treated air stream.\u000A\u2022 IDEC uses an adiabatic humidifier technique to spray water into the airstream, creating small\u000Adroplets to achieve better heat absorption efficiency without a wet media. This technique bypasses\u000Athe need to maintain a large area of water-saturated surface / wetted fill material, resulting in lower\u000Awater consumption to achieve the same wet bulb cooling efficiency.","10\u000AFig. 9: WUE data trend (June 2024 to June 2025)\u000A\u2022 Water droplets which has not been evaporated will condensate and be collected at the\u000Abottom of water spray compartment. The salvaged water will be used for next sequence of water\u000Aspraying. This water recycling method reduces water consumption.\u000A\u2022 Adaptive water spray control reduces water consumption by leveraging real-time humidity\u000Aand temperature feedback from the outdoor air stream as well as the supply air stream. It will\u000Amodulate when outdoor condition is favorable to optimize both the water volume and water pump\u000Aenergy used for humidifying the air stream inside wet channel.\u000A\u2022 Air-Air heat exchanger design is optimized to achieve a higher water distribution evenness,\u000Aand higher thermal conductivity over the same surface area thus reducing the amount of water\u000Aconsumption for indirect evaporative cooling.\u000AIn addition, water-efficient fittings equivalent to PUB\u2019s WELS 3-tick rating are installed throughout\u000Athe facility, coupled with rainwater harvesting system for non-potable water, significantly minimizing\u000Awater consumption in non-critical areas.","11\u000AIDEC\u000AFig. 10: Schematic diagram of IDEC vs. DEC\u000AIndoor air quality & comfort\u000AThe facility maintains high indoor air quality through a combination of regular surveillance audits\u000Aconducted by accredited laboratories and robust air handling unit (AHU) filtration. AHUs are\u000Aequipped with MERV 7 primary filters and MERV 13 secondary filter, ensuring effective removal of\u000Aairborne particulates. In occupied spaces, portable air purifiers have been installed, each delivering\u000Aa Clean Air Delivery Rate (CADR) sufficient to achieve more than 5 air changes per hour (ACH).\u000AIndoor air quality (IAQ) assessments are carried out every three years by an accredited laboratory,\u000Aensuring that the facility consistently adheres to best practice standards.\u000ATemperature and relative humidity are displayed in real-time and trended in the Data Centre\u000AInfrastructure Management (DCIM) system (Fig. 11). These measurements ensure that the facility\u000Acomplies with ASHRAE Standard 62.1 for ventilation and indoor air quality, as well as ASHRAE\u000AStandard 55 for thermal environmental conditions and occupant comfort.","12\u000AFig. 11: Real-time display of temperature and humidity\u000AInnovation & green features\u000A\uF081 Coolant Distribution Unit (CDU)\u000AThe dramatic increase in chip power consumption \u2014 from 100W to exceeding 1,000W \u2014 has made\u000Aadvanced thermal management essential. Cooling density has also increased with more high-\u000Aperformance chips inside one IT rack. Given its superior thermal and hydraulic properties, liquid\u000Acooling has replaced air cooling to cater for this high cooling density demand. Water can transport\u000Aapproximately 4,000 times more heat per unit volume than air for a given temperature change,\u000Awhile the thermal conductivity of water is roughly 25 times greater than air.\u000AThe facility employs liquid cooling to manage high-density IT loads, with Coolant Distribution Units\u000A(CDUs) serving as the interface between server cold plates and the outdoor heat rejection\u000Aequipment. Heat absorbed by the liquid from the servers is circulated in the Technology Cooling\u000ASystem (TCS) loop at 40/45 \u00B0C to the CDU where heat is rejected to outdoor ambient at 35/40\u00B0C.\u000AThis configuration takes advantage of the average outdoor ambient wet bulb of lower than 30\u00B0C at\u000Athe project site which enables heat rejection through cooling towers alone, without the use of\u000Achillers and any refrigerant compression cycles (Fig. 12).","13\u000AThe CDU-based liquid cooling system improves heat transfer efficiency by circulating water at higher\u000Aoperating temperatures, which allows heat to be rejected through cooling towers while targeting\u000Adirect heat source removal at chip level. This eliminates traditional fan demand and enables precise\u000Aremoval of rack-level hotspots. At the same time, CDU pumps operate with lower head pressure\u000Athan conventional chilled-water systems and are equipped with variable-speed drives that modulate\u000Ato maintain a stable differential pressure to the rack manifolds, further lowering energy\u000Aconsumption. This allowed the CDU pumps to achieve an operational efficiency of 0.02 kW/RT,\u000Awhich is better than the BCA best-practice guideline for conventional chilled-water pumps of 0.03\u000AkW/RT. Collectively, these features deliver superior energy efficiency while supporting the high rack\u000Adensities required in hyperscale environments.\u000AFig. 12: Typical Cold Plate Liquid Cooling & CDU Schematic","14\u000A\uF082 Closed-circuit cooling tower\u000AOpen cooling tower systems are susceptible to fouling on the heat transfer surface due to the\u000Aprocess water being open to the atmosphere. A heat exchanger is added to isolate the process\u000Awater loop from the cooling tower\u2019s open water loop, protecting process equipment i.e. the coolant\u000Adistribution unit (CDU) from cooling tower water contaminants and avoiding extensive CDU\u000Amaintenance. Open tower is often over-sized to compensate for the efficiency loss due to this\u000Aadditional layer of heat exchanger between cooling tower and CDU. One additional pump is required\u000Ato circulate water in the process water loop. Both an oversized cooling tower (higher fan power) and\u000Aadditional process water loop pump add to system deficiency (Fig. 13).\u000ABy utilizing a closed-circuit cooling tower for heat rejection in cold plate liquid cooling, the process\u000Afluid is not in direct contact with the atmosphere, omitting the requirement of an additional heat\u000Aexchanger and process water pump. Table below shows a 6.3 % saving in annual power\u000Aconsumption in kWh (Table 2).\u000ATable 2: Lower annual power consumption for closed circuit cooling tower","15\u000AFig. 13: Open Cooling Tower vs. Closed-circuit Cooling Tower","16\u000A\uF083 Pioneer in water quality research to support liquid cooling technology\u000ABDC as one of the first adopters of cold plate liquid cooling technology has pioneered collaboration\u000Awith one of the industry-leading water quality laboratories to prolong the lifespan of heat transfer\u000Afluid and preserve heat transfer efficiency in liquid cooling applications. After one year of continuous\u000Aimprovement, the water refreshing rate is reduced from quarterly to half yearly which resulted in\u000Aclose to 50% of water consumption saving.\u000ABDC has also set an industry standard in this area and has\u000Apublished a water quality white paper for liquid cooling application\u000Ain 2025 [No. ODCC-2024-0500G]. The paper covers the technical\u000Astandards for liquid cooling water quality, standardized process\u000Aguidance for maintaining water quality in liquid cooling system and\u000Aresponse plan, and approach in WUE optimization through\u000Apreservation of water quality in the CDU secondary loop for a longer\u000Aperiod. This has helped to optimize the use of precious water\u000Aresources in community where the data center is located.\u000A\uF084 Indirect Evaporative Cooling (IDEC)\u000AIDEC cooling cools air by first using evaporation to cool a secondary air stream (wet channel), which\u000Athen cools a primary air stream (dry channel) through a heat exchanger, all without mixing the air\u000Astreams. This system delivers cool, dry air to an indoor space by separating the evaporated water\u000Afrom the conditioned air making it suitable for data center applications where humidity control is\u000Acrucial to prolong the lifespan of servers.\u000AIDEC cooling operates in two primary modes: Dry Mode, which cools air through conduction without\u000Adirect water contact, and Wet Mode, where water is sprayed to enhance cooling capacity. A\u000Amechanical vapor compression is included in subtropical climate to achieve the server intake\u000Atemperature. IDEC uses significantly less energy (up to 80%) compared to conventional refrigerated\u000Aair conditioning systems.","17\u000AIDEC forms the backbone of the air-side cooling system. The units incorporate spray-assisted heat\u000Aexchangers that are activated when the outdoor temperatures are high. The spray-assisted heat\u000Aexchanger lowers the return air temperature from 40\u00B0C to 35.9\u00B0C, enhancing evaporative\u000Aperformance in subtropical environments while reducing compressor load. The system\u000Aautomatically switches between dry mode, wet mode and mix mode (spray + DX cooling) based on\u000Aoutdoor conditions to maintain optimal indoor conditions (Fig. 14).\u000Aa) Dry mode\u000AWhen outdoor conditions are favorable (typically when air wet-bulb temperature Twb < 22.3\u00B0C), the\u000Asystem uses only the heat exchanger to cool the return air, without any need for water spray or\u000Acompressors. This provides free cooling at minimal energy and water use.\u000Ab) Wet mode\u000AWhen outdoor temperatures are higher (22.3oC < Twb < 23.5oC ), water spray is applied over the\u000Aheat exchanger surface to enhance evaporative cooling. This lowers the air temperature effectively\u000Awhile still avoiding the use of compressors.\u000Ac) Mix mode\u000AIf supply air conditions cannot be maintained through free or spray cooling alone, the system\u000Aactivates the direct expansion (DX) coils (typically when Twb > 23.5oC). This ensures cooling\u000Arequirements are always met, with the DX coils engaged only as a last-minute resort to minimize\u000Acompressor energy use.","18\u000A(water spray for indirect evaporative)\u000AFig. 14: Illustrative example of IDEC operating principles:\u000AThe black markers indicate the operating conditions of the system.","19\u000A\uF085 Rainwater harvesting\u000AThe facility incorporates a rainwater harvesting system to reduce potable water consumption by\u000Aaround 5%. Collected water is reused for non-critical applications, such as irrigation, supporting\u000Awater conservation goals.\u000AFig. 15: Detail of rainwater harvesting system\u000A\uF086 Environmental gas suppression system\u000AFor the gas suppression system of some server rooms, an inert gas\u000Afire suppression system (IG-541) is installed, offering effective fire\u000Aprotection with zero ozone depletion potential (ODP) and zero\u000Aglobal warming potential (GWP), ensuring environmental\u000Acompliance and equipment safety.\u000AThis clean agent is composed of three gases, i.e. Nitrogen, Argon\u000Aand Carbon dioxide with proportions of 52%, 40% and 8%\u000Arespectively. When discharged into a room, the composition still\u000Aallows a person to breathe in a reduced oxygen atmosphere. This\u000Aallows people to see and breathe, permitting them to leave the fire\u000Aarea safely.","20\u000A\uF087 Adaptive lighting controls\u000AThe facility uses energy-efficient lighting systems in compliance with MS 1525: Code of Practice on\u000AEnergy Efficiency. Moreover, the data halls are integrated with motion sensors and zoning strategies\u000Ato minimize energy consumption during off-peak periods.\u000A\uF088 Prefabricated Prefinished Volumetric Construction (PPVC)\u000APPVC was adopted to accelerate construction timelines during the COVID-19 pandemic. This\u000Amodular construction technique allows for off-site fabrication of entire volumetric units that are then\u000Aassembled on-site. This approach offers advantages such as improved quality control, reduced\u000Aconstruction time, lower on-site manpower requirements, and enhanced safety and productivity.\u000ABy incorporating modular designs and prefabricated structures, BDC has successfully reduced\u000Aconstruction waste and environmental impact. These initiatives laid the foundation for scalable,\u000Ahigh-performance facilities aligned with evolving ESG expectations.\u000AOperation and Maintenance\u000APrior to operation, the facility underwent a structured commissioning process in accordance with\u000AASHRAE Guideline 0-2019. This process was carried out by an independent third-party\u000Acommissioning specialist to verify design intent, system performance, and operational readiness.\u000Aa) Data center infrastructure management\u000ABDC has developed a Data Centre Information Monitoring (DCIM) system. It functions as a\u000Asupervisory monitoring platform that receives real-time site data from all operation-critical devices.\u000AThe platform provides an additional layer of monitoring that reduces the risk of oversight, and faster\u000Aescalation of emergencies to achieve high service availability. Most importantly, the platform trends\u000Aand collates energy consumption for the site to enable continuous effort to optimize sequence of\u000Aoperation and achieve higher energy efficiency.","21\u000AThe facility integrates DCIM (Data Centre Infrastructure Management) for real-time operational\u000Aoversight. This platform provides centralized monitoring of power, cooling, and environmental\u000Aparameters, enabling proactive maintenance, energy optimization, and improved fault detection\u000Aacross critical infrastructure. Its analytics and reporting capabilities also support continuous\u000Aperformance benchmarking, enabling data-driven decisions for system tuning and long-term\u000Aefficiency improvements (Fig. 16).\u000AFig. 16: DCIM interface","22\u000Ab) Design for maintainability\u000ADesigned for ease of maintenance and long-term resilience, MY06C1B1 is a single-storey structure\u000Awith full fa\u00E7ade accessibility for external servicing. All cooling towers and DX AHUs are mounted\u000Aexternally and equipped with dedicated gantries to facilitate safe and efficient maintenance. To\u000Amitigate the risk of water ingress, all electrical rooms housing switchboards and generators are\u000Acontained within elevated prefabricated structures at ground level. (Fig. 17)\u000AFig. 17: Maintenance gantry for equipment\u000ACost effectiveness\u000ACompleted in late 2022, the facility demonstrates exceptional cost efficiency, surpassing\u000Abenchmarks set under the BCA-IMDA Green Mark for Data Centres (GMDC: 2024) . With an IT load\u000Aof 98,385,162 kWh/year, the center achieved an actual PUE of 1.295, outperforming the\u000Ainterpolated Platinum benchmark of 1.313 at 56% IT load. This equates to an annual energy savings\u000Aof approximately 1,770,874 kWh. Using the prevailing ultra-high-voltage tariff effective July 2025\u000Aof RM 0.60/kWh, the facility realizes an estimated energy cost savings of RM 1,062,524 (~USD\u000A255,005) per year.","23\u000ACost for the energy efficiency features amounts to approximately RM 6.2 million during the\u000Aconstruction stage. With annual savings of RM 1,062,524, the estimated payback period is\u000Acomputed to be around 6 years. This payback period is expected to be shorter after considering of\u000Ahigher annual electricity tariff forecast of 10~15%.\u000ANoteworthy is the fact that MY06C1B1 far exceeded the 2024 benchmark which reflects the best\u000Apractice for modern day data centers with the building operating since 2022. These savings are\u000Aattributed to the energy efficient liquid cooling system, efficient power chain design, and intelligent\u000Aautomation.\u000AEnvironment impact\u000AThe energy savings achieved also translate into substantial environmental benefits. Using the same\u000Amethodology as the above section to obtain energy savings and referencing Malaysia\u2019s national grid\u000Aemission factor of 0.774 kg CO\u2082/kWh, the facility avoids approximately 1,370.6 metric tons of CO\u2082\u000Aemissions annually. This reduction is derived from savings of electricity energy alone and does not\u000Ainclude reduction due to other factors such as water savings, waste disposal and others.\u000AAwards\u000ABridge Data Centres MY06 Campus 1 Building 1 is a showcase of sustainable hyperscale\u000Adevelopment. Despite construction during the COVID-19 pandemic, it was completed in record time\u000Awith exceptional performance metrics. In recognition of the advanced sustainability features, the\u000Afacility was awarded the BCA Green Mark Platinum award under the GMDC:2024 framework in\u000AAugust 2025.\u000AThe building has also won the ASHRAE Malaysia Technology\u000AAward in October 2025 under the category of New Industrial\u000AFacilities/Processes. This award was presented during the\u000AASHRAE Malaysia Annual Dinner held on 24th October 2025\u000Ain Connexion Conference & Event Center (CCEC).","24\u000AMr. Zhang Binghua, Chief Technology Officer of Bridge Data Centres (International) Pte. Ltd,\u000Areceiving the ASHRAE Malaysia Technology Award from ASHRAE Malaysia President, Mr. Kozen\u000ALaw during the 2025 ASHRAE Malaysia Annual Dinner event."];