The Data Center Builder's Bible - Book 1

1. Defining Data Center Requirements Is Crucial for Success

Few components of the Data Center requirements and eventual design will impact your long-term cost, systems availability and overall success than how you defined your power requirements and designed the power distribution scheme.

Requirements drive design. Proper definition of data center requirements is the foundation of a successful project. This process involves understanding your current and future needs in terms of power, cooling, space, and network connectivity.

Key areas to focus on:

• Power consumption and distribution
• Cooling capacity and efficiency
• Space requirements for equipment and growth
• Network connectivity and carrier diversity
• Redundancy and availability goals

By clearly defining these requirements upfront, you can avoid costly mistakes and ensure that your data center meets your organization's needs both now and in the future.

2. Understanding Data Center Types and Functions

Every year more and more infrastructure teams are finding themselves needing to build a new Data Center and migrate their environment.

Data centers come in various types. Understanding the different types of data centers and their functions is essential for making informed decisions about your infrastructure needs.

Main types of data centers:

• Primary Data Centers: Main operational facilities
• Disaster Recovery (DR) Data Centers: Backup facilities for business continuity
• Colocation Data Centers: Shared facilities for multiple organizations
• Enterprise Data Centers: Purpose-built for a single organization

Each type has its own advantages and considerations in terms of cost, control, and scalability. Choosing the right type depends on your organization's specific needs, budget, and risk tolerance.

3. Power Distribution: The Backbone of Data Center Operations

The bottom line of this discussion is to decide what Tier Classification Level is required for your environment.

Power is critical infrastructure. A reliable and efficient power distribution system is essential for data center operations. Understanding power requirements and distribution methods is crucial for ensuring uptime and optimizing costs.

Key power distribution concepts:

• Utility feeds and redundancy levels
• UPS systems and battery backup
• Power distribution units (PDUs)
• Tiered classification system for reliability

Proper power distribution design ensures that your data center can handle current loads and accommodate future growth while maintaining the required level of reliability and efficiency.

4. Cooling Systems: Balancing Efficiency and Reliability

Cooling is also improved by adding redundant cooling units that can take over for units that have failed or have been taken out of service temporarily for maintenance.

Efficient cooling is essential. Cooling systems are crucial for maintaining optimal operating conditions for IT equipment. Balancing cooling efficiency with reliability is key to controlling costs and ensuring uptime.

Cooling system considerations:

• Air distribution methods (raised floor vs. hard floor)
• Hot aisle/cold aisle configurations
• Containment strategies for high-density environments
• ASHRAE guidelines for temperature and humidity

Implementing the right cooling strategy can significantly impact energy consumption and overall data center efficiency while maintaining the required environmental conditions for equipment operation.

5. Space Requirements: More Than Just Square Footage

Calculating the White Space Room Size

Space planning is multidimensional. Determining space requirements involves more than just calculating square footage for equipment. It requires careful consideration of layout, growth potential, and supporting infrastructure.

Space planning factors:

• Equipment footprint and rack space
• Aisle widths and clearances
• Support areas (storage, staging, offices)
• Future expansion capabilities

Proper space planning ensures efficient use of the data center floor while allowing for growth and maintaining proper airflow and accessibility for maintenance.

6. Redundancy and Availability: Ensuring Uninterrupted Service

A Data Center design must preserve the dual-feed arrangement for as much of the design/deployment as possible.

Redundancy enables availability. Implementing redundant systems and diverse paths for critical infrastructure is essential for achieving high availability and minimizing downtime risks.

Redundancy considerations:

• N+1, 2N, and 2N+1 configurations
• Dual power feeds and distribution paths
• Multiple network carriers and entry points
• Redundant cooling systems

The level of redundancy should align with your organization's uptime requirements and risk tolerance, balancing the need for availability with cost considerations.

7. Network Infrastructure: The Lifeline of Data Centers

One of my foundational philosophies of building and relocating Data Centers is that your greatest challenge will always be moving the network.

Network planning is critical. A robust and flexible network infrastructure is essential for data center operations and connectivity. Proper planning and design of network systems can significantly impact performance and scalability.

Network infrastructure components:

• External connectivity (carriers and diverse paths)
• Internal networking (LAN and SAN)
• Meet-me rooms and cross-connect facilities
• Network redundancy and diversity

Careful consideration of network requirements and carrier relationships is crucial for ensuring reliable connectivity and supporting future growth.

8. Fire Suppression: Protecting Your Critical Assets

While gaseous fire suppression is preferable to water-based systems, it is typically not available in larger colocation sites.

Fire protection is non-negotiable. Implementing appropriate fire detection and suppression systems is crucial for protecting valuable assets and ensuring business continuity.

Fire suppression considerations:

• Detection systems (smoke and heat)
• Suppression methods (water-based vs. gaseous)
• Zoning and containment strategies
• Compliance with local codes and regulations

The choice of fire suppression system should balance effectiveness, minimal damage to equipment, and safety for personnel.

9. Cabinets and Racks: Maximizing Space and Efficiency

The absolute "Standard" computer cabinet is 24 inches wide. Basically, only the extra width needed for side panels is added to the 19-inch rack width to produce a horizontally tight design.

Cabinet design impacts efficiency. Proper selection and configuration of cabinets and racks can significantly impact space utilization, cooling efficiency, and ease of maintenance.

Cabinet and rack considerations:

• Dimensions (width, depth, height)
• Power distribution integration
• Cable management features
• Airflow optimization

Customized cabinet designs can offer significant advantages in terms of space utilization, cooling efficiency, and ease of maintenance compared to standard options.

10. Data Center Efficiency: Measuring and Improving Performance

Data center infrastructure efficiency (DCIE), is a performance metric used to calculate the energy efficiency of a data center.

Efficiency drives performance. Measuring and improving data center efficiency is crucial for controlling costs and reducing environmental impact. Key metrics like Power Usage Effectiveness (PUE) provide insights into overall efficiency.

Efficiency improvement strategies:

• Optimizing cooling systems
• Implementing containment solutions
• Utilizing energy-efficient equipment
• Monitoring and adjusting operations

Continuously monitoring and improving efficiency metrics can lead to significant cost savings and improved performance over the life of the data center.

Last updated: July 30, 2024