AirBlock PolySim Fire-Rated Curtains

The Non-Outgassing, Permanently Static Dissipative Class 1 Fire-Rated Material

btn_contactWith fire safety, static electricity and molecular contamination growing as concerns in today’s advanced data centers, PolySim material from Simplex Isolation Systems is an ideal choice for softwall curtains. PolySim was the first clear, flexible softwall material to achieve a Class-1 fire rating. As a proprietary compound thermoplastic polyurethane (TPU) – not a PVC – PolySim is non-outgassing and non-blooming, allowing for minimal cleaning requirements. The PolySim™ formulation has permanent static dissipation properties, which do not wear off or diminish over time, like anti-static vinyls do.


  • ASTM E-84 Class 1 Fire-Rated
  • Exceeds NFPA 76 data center standard
  • No outgassing, no blooming
  • Permanently static dissipative
  • Does not require humidity
  • See-through clarity
  • No particulates
  • Available in clear, opaque black and opaque white


  • Cost effective alternative to hardwall panels
  • Minimal cleaning requirements
  • Fire safe
  • Superior durability
  • Environmentally friendly
  • Available in 48″ wide rolls, 12″ strips or 48″ curtains
  • Can be RF welded into custom widths to create solid walls

As with all Simplex materials, PolySim has been fully tested to certify performance.

To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:


Air Containment Systems

btn_contactPTS provides Air Containment Systems (ACS) for hot-aisle/cold-aisle containment. The solutions reduce data center cooling costs by directing cold air where it is needed most – through the computer racks.

Data center managers across the county are discovering that ACS or airlock systems consisting of clear panels, vinyl curtains, door enclosure solutions or strip doors are ideal for use in computer data centers where hot-aisle/cold-aisle containment is important. Hot-aisle/cold-aisle design is the data center best practice where server racks are lined up in alternating rows with cold-air intakes all facing one aisle and hot-air exhausts facing the other. Cool air is vented into the cold air aisles, directed through the computer racks, and into the warm air aisles.

Air Containment System

By further separating the hot and cold air aisles with an ACS, managers can effectively separate cold air aisles from warm air aisles, directing cool air where it is needed most in the data center: through the computer racks. Additionally, a study by the Lawrence Berkeley National Laboratory finds facilities that use curtains or partitions to direct airflow in data centers, “can save energy on both air conditioning and fan systems – 15% and 67%, respectively.”

PTS typically designs this solution & CFD models its application to guarantee the results, savings & performance prior to implementation.

The key design criteria parameters serve as a basis to monitor and properly manage the data center. Use of PTS ACS solutions provide clear return-on-investment as an integral component of the eleven-step computer room design and management process.

Features Benefits
Hot and cold aisle separation. Save energy on both air conditioning and fan systems – 15% and 67% respectively (according to a study by the Lawrence Berkeley National Laboratory)
Includes airlock panels, transparent curtains, vinyl curtains, door enclosure systems, strip doors, panels and patented hardware. Solutions available for a variety of applications.
Specially formulated solutions which are low-outgassing and anti-static. Fire retardant to meet ASTM and NFPA requirements.
Drop-away curtains. Curtains fall away in the case of fire, allowing fire sprinklers full operating range.
Airlocks raise the intake or ducts the intake of a CRAC to the plenum Improves the effectiveness of your HVAC system
(Click image to view full-size)
(Click image to view full-size)

To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:


Economizer Cooling Solutions

The data center cooling system is a primary target for energy efficiency improvements. Emerson Network Power analyzed data center energy usage and found that cooling systems — comprised of cooling and air movement equipment — account for 38 percent of energy consumption within this mission critical facility. Fortunately, cooling system technologies, such as Economizers, exist that can substantially slash costs from the data center electricity bill.

Economizer systems can have a significant impact on energy usage. In many locations, economizers can be used to allow outside cool air to complement data center cooling systems and provide “free cooling” during colder months. A study on building control systems conducted by Battelle Laboratories and reported by the National Building Controls Information Program, found that on average the normalized heating and cooling Energy Use Intensity (EUI) of buildings with economizers was approximately 13 percent lower than those without economizers1.

When an economizer system is operating, the use of an air conditioning system’s compressor(s) and related electro-mechanical components is reduced or eliminated. This reduces energy consumption.

This data center cooling system incorporates economizers in modular mixing boxes mounted on top of the computer room handling units.

Types of Economizers and How They Work (PDF Download)

The two basic types of economizer systems are air economizers and fluid economizers. While both have the ultimate goal of free cooling, they possess fundamental differences that impact the environments in which each is most appropriately used. The air economizer serves as a control mechanism to regulate the use of outside air for cooling in a room or building. It admits into the room the appropriate volume of outside air to satisfy cooling demands. Sensors on the air economizer measure the outside and inside air conditions. If outside conditions are suitable for the use of outside air for cooling, the economizer introduces the outside air for complete or partial cooling of the space. During the time these conditions exist, the need for the air conditioning system’s chiller(s)/compressor(s) is reduced or eliminated, which results in significant energy savings.

Liebert Economizer Solutions
Liebert Economizer Solutions

Air economizers are available in two types: a “dry air” system and an “evaporatively conditioned” air system. The former is the most common, but its use is restricted to a few geographic locations because of contamination issues and the high cost of energy required to add moisture to the room when the outside humidity is too low or too high. The evaporatively conditioned system is an economical method for conditioning the air before it comes into the data center, but reliability issues (mildew concerns and high maintenance requirements) have generally made this approach unattractive to most data center operators.

As its name would suggest, a fluid economizer system is typically incorporated into a chilled water or glycol-based cooling system. This type of economizer works in conjunction with a heat rejection loop consisting of a cooling tower or drycooler to satisfy cooling requirements. With the economizer operating, the fluid used in the cooling system passes through an additional heat exchanger/coil, minimizing the need for chiller/compressor operation.

During colder months, the glycol solution returning from the outdoor drycoolers or cooling tower feeding the CRAC units is routed to the second coil, which becomes the primary source of cooling for the room. As long as the “free cooling” fluid is 8 degrees Fahrenheit below the air temperature returning to the CRAC unit, there is some benefit for having the free cooling running, because it minimizes the load on the primary cooling method. Similarly in CRAH units, a secondary heat exchanger between the cooling tower fluid and the chilled water loop takes away part of the heat from the return water loop and reduces the load on the chiller.

To learn more about PTS recommended Economizer Cooling Solutions, contact us or visit (in alphabetical order):

To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:

Room-Based Cooling Solutions


Room-based-Cooling-SolutionsSmall Room

Room based Cooling ApproachLarge Room

Traditional data center, computer room, and server room cooling methodologies provide room-oriented cooling which provides an entire room with cold air from centralized units at one end of the room. This approach is acceptable when power densities are minimal and, therefore, there are few hot spots in a room.

Stulz CyberAiR Room Cooling Solution

Effective Room-Based Cooling approaches start with well understood Key Design Criteria to understand the total cooling requirement, areas of possible hot-spots, design elements (I.e. raised floor, ceiling mounted air ducts), room architecture, hot-aisle/cold-aisle containment strategies to name a few requirements and design considerations.

In large data centers Room-Based Cooling Solutions remain the most economical approach to cooling and, where appropriate and necessary, can be deployed in a hybrid environment with Row-Based Cooling Solutions and Rack-Based Cooling solutions. This approach is beneficial to data centers operating with a broad spectrum of rack power densities.

Floor layout utilizing room, row, and rack-oriented architectures

In this approach each of the types of cooling solutions approaches plays a role to provide cooling throughout the facility:

  • Room-Based: Supplying a room but primarily serving a low density area of mixed equipment such as communications equipment, low density servers, and storage.
  • Row-Based: Supplying a high density or ultra-high density area with blade servers or 1U servers.
  • Rack-Based: Supplying isolated high density racks or ultra-high density racks

Manufacturers provide small-room and large-room oriented cooling systems. In many cased small-room cooling can be efficiently deployed using Rack-Based cooling solutions and appropriate isolation solutions and heat rejection solutions. For large-room deployments designs may include the cooling systems deployed within the data center, computer room, or server room, heat rejection solutions, and economizers.

Liebert DS Upflow
Liebert DS Upflow

To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:

Row-Based Cooling Solutions


In-Row Cooling Approach

Traditional data center, computer room, and server room cooling methodologies provide room-oriented cooling which provides an entire room with cold air from centralized units at one end of the room. This approach is acceptable when power densities are minimal and, therefore, there are few hot spots in a room. However, room-oriented designs are affected by room constraints including ceiling height, room shape, obstructions above and below the floor, rack layout, CRAC location, power distribution, etc.

With a row-oriented architecture, the CRAC units are associated with a row and are assumed to be dedicated to a row for design purposes. The CRAC units may be mounted among the IT racks, they may be mounted overhead, or they may be mounted under the floor. Compared with the room-oriented architecture, the airflow paths are shorter and more clearly defined. In addition, airflows are much more predictable, all of the rated capacity of the CRAC can be utilized, and higher power density can be achieved.

Liebert CRV In Row Cooling SolutionThe row-oriented architecture has a number of side benefits other than cooling performance:

  • The reduction in the airflow path length reduces the CRAC fan power required, increasing efficiency.
  • A row-oriented design allows cooling capacity and redundancy to be targeted to specific rows.
  • Row-based cooling allows a data center, computer room, or server room to be implemented without a raised floor.
  • In-Row cooling allows for varied room designs and constraints. For example, load-bearing supports can be managed at the row level rather than trying to handle at the room level.

To learn more about PTS recommended In-Row Cooling Solutions, contact us or visit:

To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:

Cooling Optimization Solutions


Data Center Cooling Optimization Best Practices for Data Centers, Computer Rooms, and Server Rooms

To learn more about PTS recommended cooling optimization solutions, contact us or visit (in alphabetical order):

  • PermaFrost NMR™ Refrigeration Solutions Powertron Global offers PermaFrost NMR™ Refrigeration Solutions in synthetic and non-synthetic formulations. PermaFrost Nucleo Molecular Regenerative (NMR) technology was designed to improve the performance for any A/C, refrigeration system, or heat pump without modification or alterations. The NMR technology uses nanotechnology to increase SEER, COP, and Delta T through thermo-conductive metal enhancement.

To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:


Air Flow Management

One of the most common complaints design engineers hear from data center owners and operators is that they need additional cooling capacity because the existing system doesn’t maintain an acceptable temperature at the data equipment inlets. But in most cases, the problem isn’t one of insufficient capacity, but of poor air flow management. The good news is that adopting a strategy to improve data center air flow results in two positive changes. First, by reducing the amount of air that needs to be supplied, less energy is used for data center cooling. Second, temperature distribution across cabinets is improved.

The biggest culprits leading to poor air flow conditions in data centers are recirculation and bypass air flow. Bypass air flow is cold supply air that does not lead to productive cooling at the IT load. Both reduce the overall available airflow for cooling, but do so by two different mechanisms.

  • Recirculation is the mixing of the hot exhaust with the cold intake of the IT equipment
  • Bypass circumvents the cooling path by going around the IT equipment

The primary method for minimizing the impact of both recirculation and bypass is to separate the supply and return air streams using air flow management or containment. With containment, the rack density is only limited by the capacity of the cooling equipment to provide the proper airflow at an acceptable differential temperature (I.e. server inlet temperature to server outlet temperature).

Why don’t all data center managers use containment? Some don’t like that containment restricts access to the cabinets, cable trays, or aisles. However, a less obvious problem is containment requires a carefully planned control strategy to prevent excessive pressure differences between hot and cold aisles. If the pressurization control strategy is wrong, the server fans could starve for air, which could cause them to increase speed in order to maintain acceptable processor temperatures. Thus, to respond to pressure issues, the servers will increase energy consumption and operations costs will increase.

Data Center Air Flow Management Best Practices

  • Air Flow Management Hot Cold Aisle ContainmentHot Aisle / Cold Aisle Containment. Hot aisle containment encloses and captures the hot IT exhaust and ducts the hot air directly back to the computer room air conditioners/handlers.

    While hot aisle containment captures the return, cold aisle containment, as the name implies, contains the cold air supply.

    Both methodologies have the benefit of isolation of the hot air return from the supply air, allowing for increased CRAC/H efficiencies gained from higher return cooling coil temperatures. Additionally, both will reduce the need for humidification and dehumidification as the air is delivered directly back to the CRAC/H without mixing. The two differ in three areas—scalability, thermal mass and operator comfort.

  • Install blanking panels in all openings within each cabinet. Don’t forget bypass and recirculation can occur inside cabinets. An air flow management system cannot effectively cool the equipment in a cabinet without eliminating internal paths of bypass and recirculation. Blanking panels reduce these air flows and are considered a must for proper air flow inside a cabinet.

  • Deploy perforated tiles in cold aisles. Placing perforated tiles in any location but cold aisles increases bypass. There is never a justification for placing perforated tiles in hot aisles unless it’s a maintenance tile. During maintenance, if necessary, a perforated tile can be used in a hot aisle to support an IT technician. However, make sure not to leave it behind.

  • Polargy-obstructed-cutoutsSeal gaps between raised floors, walls, doors, cable cutouts, etc. Sealing the spaces between the raised floors and room walls is a no-brainer. Those gaps are easily identified by a simple visual inspection. A more subtle form of bypass can be found when column walls are not finished above the ceiling and below the floor. Often, the sheet rock used to enclose a column forms a chase for direct bypass of air into the return air stream. These chases must be sealed to reduce bypass air flow.
  • Use right type of floor tile. Many data center managers install high capacity grates at perceived hot spots (i.e. racks with blade servers) but this can actually be counter-intuitive. Rather, it is critical to perform a computational fluid dynamic analysis (CFD) above and below the floor of the hot spot to fully understand air flow and pressure changes which will drive the type of floor tile (I.e. high-capacity flow) to deploy.

  • Manage the placement of perforated tiles. Calculate the load for the cold aisle and place an appropriate number of perforated tiles or grates (but not both) to cool the load in that aisle. Placing too few tiles in the cold aisle will cause recirculation. Placing too many will increase the amount of bypass.

Air-Flow-Management-Top-Mount-Cooling-ConfigurationTo learn more about PTS recommended Air Flow Management Cooling Solutions, contact us or visit:


To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:


AirBlock Containment Curtains and Strip Doors

Slash Energy Costs with Better Air Flow Dynamics

btn_contactPTS’s data center cooling solutions help protect your critical operations while enabling you to reduce operating costs and increase capacity. With hot aisle cold aisle isolation you can depend on easy-to-deploy data center partitions with superior safety features and high quality.

AirBlock Data Center Curtains were developed with a singular goal: to provide the finest quality curtains for achieving hot-aisle/cold-aisle containment in the data center. AirBlock Data Center Curtains are engineered for performance, and exceed all fire and safety standards. Simplex products are made from virgin materials to provide extra clear transparency and protection against yellowing and cracking.

Choose from proprietary material options that include vinyls with ESD resistance and those that are free from outgassing. All AirBlock Data Center Curtains are tested to NFPA and ASTM E-84 Class 1 standards for flame and smoke generation, guaranteed to help maintain compliance with local fire codes.

AirBlock Data Center Curtains offer a selection of mounting systems that offer solutions to existing infrastructure in the legacy data center.  There are virtually limitless options for new installations. Modular design allows for easy installation and expansion in the event of a growing data center.

Features and Benefits

  • Cost Savings: increased capacity and stabilized temperatures will cut power costs and help take advantage of utility company rebates.
  • Modular designs: allows for easy expansion and reconfiguration to meet the changing needs of your evolving data center.
  • Integration: AirBlock data center containment curtains can be used in conjunction with end-of-aisle solutions, doors, hardwall partitions and ceiling modules for a complete data center approach.
  • Various Material Options: choose from a wide variety of materials to suit your needs, including proprietary materials that meet NFPA 76 data center standard, the ASTM E-84 standards and are Class 1 fire rated, with the lowest smoke and flame spread ratings available.
  • Sizing Options: specify full length ceiling-to-floor curtains, or custom lengths for above-the-rack installations.
  • Overlapping Design: vinyl panels are 40 mil thick and 48 inches wide, with four-inch overlaps to prevent leakage.
  • Data Center Strip Doors: end-of-aisle access is easy with strip doors, as the strips come back together easily to limit air loss from one area to another.
  • Molded Corner Design: molded, wraparound corners form superior seals in the data center.
  • Fire Safety: Hardware is designed so that curtains fall away in the case of a fire, allowing sprinklers full operating range.

Easy Mounting and Assembly

There is a unique array of strip door and curtain mountings that allow you to customize your enclosures and barriers. Mountings are extruded from 6063-T5 aluminum and come in standard anodized clear coat.

Data Center Hardwall Enclosures

AirBlock Data Center Hardwall Systems enable hot aisle and cold aisle regions in the data center that have the performance of hardwalls, but still retain the modular capabilities.

The AirBlock Data Center Hardwall System features Active Channel Technology. This technology is found in the two-piece extrusion frame and allows the end user to adjust the insert channel of the data center frame to accommodate different sizes of solid inserts—from 1/8″ to 3/8″. Choose from a wide variety of insert materials, including polycarbonate, polypropylene, ABS, aluminum composite, acrylic, or even tempered glass.

The Active Channel Technology design creates a snug interior mounting of the panel insert that is flush with the frame, keeping the assembled hardwall panel looking sleek and modern in appearance.

To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:


Stulz CyberCool XT Chiller Cooling Solutions


Stulz-CyberCool-XT-Chiller-Cooling-SolutionStulz CyberCool XT Chiller Cooling Solutions offer chilled water generator developed for maximum reliability in data centers. With cooling capacities from 4 kW to 1,700 kW, the product line boasts enormous ranges of versions and sizes to offer clients precisely what they need. For both indoor and outdoor use – every device is compact, read-to-connect, and can be started up quickly and easily.

  • Compact, ready-to-connect chillers for internal and external installation
  • Numerous precision-designed versions and different sizes
  • Straightforward, fast installation and start-up

Features & Benefits

Free Cooling Up to 40% more economical when free cooling is applied
Reliable and cost-efficient With excellent efficiency of up to 92%, EC fans noticeably lower energy consumption and the running and lifecycle costs of precision air conditions and chillers
Cost-efficient in partial load mode The design of chillers assumes maximum heat load – but during normal operation, this capacity is seldom used 100%; with speed-controlled components such as fans or compressors, a great deal of energy can be saved in partial load mode



Overview of CyberCool Chillers



Cooling capacity (in kW)

Free cooling available

Air-cooled outdoor CSO/CLO (A) 36 to 235 yes
CEO (A) 4 to 72 no
CFO (A) 86 to 965 yes
CGO (A) 365 to 1525 yes, up to 1200 kW
Air-cooled indoor CEI (A) 4 to 23 no
CHI (A) 25 to 144 no
CFI (A) 173 to 257 no
Air-cooled indoor, split CSI (A) 20 to 100 no
CHS (A) 5 to 138 no
CFS (A) 174 to 487 no
CGS (A) 380 to 1517 no
Liquid-cooled indoor CSI (G) 20 to 100 no
CEI (W) 6 to 35 no
CHI (W) 27 to 144 no
CFI (W) 197 to 511 no
CGI (W) 468 to 1537 no
Pump & Transfer CPI (CW) 20 to 100 no
CPI (CW2) 2×20 to 2×100 yes

Overview of CyberCool Pump Stations



Flow (in m3/h)


Pump stations CPP (CW) 10 to 50 CyberAir 2
CDI 4 to 7 CyberCool XT
CDO 4 to 108 CyberCool XT


To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:


Motivair Chiller Data Center Cooling Solutions


Motivair offers a wide range of packaged air cooled chillers for virtually every data center, computer room, sever room, or mission critical application: energy-saving free cooled, air cooled, water cooled heat recovery chillers.  All Motivair air cooled chillers feature optional integrated tanks, pumps and controls with remote interface via LON, Bacnet or Modbus. Motivair air cooled chillers can be customized to suit specific customer requirements.

Free Cooling Chillers

Air cooled chillers with integrated Free Cooling System.

Motivair-Free-Cooling-ChillersChiller standard features include:

  • Integrated Free Cooling system and coil with VFD fan speed control and Motivair Free Cooling software package. The Integrated Free Cooling system offers unmatched efficiencies using cold ambient air to pre-cool or completely cool the process load.
  • Single or Dual circulation pump(s) with TEFC motor and automatic pump rotation and change over
  • Reliable start-up and operation during low ambient conditions
  • Ideal for Process Cooling, IT Room/Data Center Cooling, MRI Cooling, CAT scan Cooling, Linear Accelerator Cooling, Surgery Suite Cooling & HVAC Cooling

Motivair MPC-FC Free Cooling Chillers: 1/2 – 50 Tons features include:

  • On board storage tank design for complete system volume holding capacity. Integral storage tank eliminates need for system tanks and allows the chiller to cycle off refrigeration compressors during reduced load operation
  • High efficiency Scroll compressors
  • Motivair MLC-FC Free Cooling Chillers: 60 – 350 Tons features include:
  • Rapid restart of refrigeration system in the event of building power failure. Free Cooling software with logical control sequence minimizes restart time if the chiller was operating at less than 100% load before power failure
  • High efficiency Screw compressors with stepped or variable capacity control. Standard R-134A refrigerant with alternatives available upon request

Air Cooled Heat Recovery Chillers

Chiller standard features include:

  • Ability to simultaneously provide heating and cooling for a process or building. Chiller heat recovery exchangers are installed in the refrigeration system allowing the reclaim of heat from the system before it is discharged from the chiller
  • Standard hot water available during standard chiller operation is 115°F. Hot water is available up to 140°F
  • Flexibility in the design allows design engineers or clients to reclaim 20-90% of the heat from the system
  • Chiller Heat Recovery System is available in Series or Parallel configuration
  • Available Single or Dual chilled water circulation pumps with automatic pump rotation and change over
  • Standard R-407C Refrigerant with R-134A as optional
  • High efficiency Screw compressors with stepped or variable capacity control
  • Ideal for LEED Projects, Education Buildings, Hotels, Hospitals & Process Cooling

Motivair Heat Recovery Chillers are also available in water-cooled formats.

Water Cooled Heat Recovery Chillers

MSC heat recovery chillers are available from 15 to 60 tons cooling capacity with 2 or 4 scroll compressors in 1 or 2 circuits. MHR heat recovery chillers from 75 to 450 tons feature 2 screw compressors in 2 circuits. All evaporators and condensers are shell and tube design for long life and easy maintenance. Noise suppression is available on all models and microprocessor or PLC controls are standard.

Heat Recovery System

Each MSC or MHR chiller can be supplied with a Motivair Heat Recovery System. This system incorporates a heat recovery exchanger piped in series with the standard water-cooled condenser. The Motivair heat recovery system allows the chiller to reclaim heat energy that is typically wasted and rejected via the chiller condenser. The heat recovery system can reclaim up to 90% of the system heat, allowing it to be redirected back into the building or process as a heat source. Standard hot water design is 115°F with optional hot water temperatures up to 140°F.

Dedicated Heat Recovery System

The MSC or MHR chillers range can also be applied as dedicated heat recovery systems. With this option, the primary goal of the chiller is to use the hot water leaving the condenser as a primary heating source while using the chilled water leaving the evaporator as a secondary chiller function. Heat Recovery exchangers as described above are no longer necessary as the standard chiller condensers are used for heating. Standard hot water temperatures can range from 115°F-140°F based on system design.

15-60 Ton Capacity Options

60-450 Ton Capacity Options

  • Single or Double on board pump system
  • Advanced PLC for LON or BacNET communication
  • Hot Gas Bypass System
  • Low Noise Package
  • Advanced PLC for LON or BacNET Communication
  • Low Noise Package

To learn more about PTS consulting services to support Air Conditioning Equipment & Systems deployments and support, contact us or visit:

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