Evaluating UPS system efficiency
Many modern uninterruptible power supply (UPS) systems have an energy-saving operating mode. Data show that very few data centers put it to use because of the potential risks.
- Learn about the energy-saving options of uninterruptible power supply (UPS) systems.
- Know how to save energy by running the UPS system in eco mode.
- Understand the impacts of operating the UPS system in eco mode.
“Eco mode” is a term used with many different pieces of equipment to define a state of operation in which less energy is consumed, which is a more economical operation. When the term is used in reference to a smartphone or car, it generally means some sort of toned-down operation where not all the functions are available and the system runs certain functions at slower speeds to consume less energy. Whether this affects the overall operation of the equipment depends on what task the equipment is performing.
The main function of an uninterruptible power supply (UPS) is to protect the critical load during an outage by supplying backup power from a stored-energy device, and by providing stable voltage and frequency. Similar to other equipment, the intent of running the UPS system in eco mode is to increase efficiency by reducing the amount of energy consumed by the UPS. The Green Grid defines eco mode as “one of several UPS modes of operation that can improve efficiency (conserve energy) but, depending on the UPS technology, can come with possible tradeoffs in performance.”
Does running the UPS in eco mode affect the operation of the UPS, making the overall system less reliable and potentially putting the critical load at greater risk? Is there a way to use eco mode to improve efficiency without compromising performance or reliability? These are questions that must be reviewed when considering designing and operating a critical facility with eco mode. The goal of this article is to take a closer look at the different UPS operating modes and how they impact data centers and other mission critical facilities.
Although there are different metrics used to measure efficiency in data centers, the one most commonly used is power usage effectiveness (PUE), created by the Green Grid. It compares the total data center facility’s power to the power used to operate the IT equipment. The optimum data center would have a PUE value of 1.0, where all the power going into the data center is being directly used to power the IT equipment. Any value above 1.0 means that a portion of the total facility power is being diverted to support systems, such as cooling, lighting, and the power system. The higher the PUE number, the larger portion of the power is consumed by the support systems relative to the IT equipment itself, resulting in a less efficient data center.
When designing a data center, most engineers, owners, and operators focus on the mechanical system and the ability to use free cooling to lower the PUE and increase efficiency. The electrical system, however, also wastes energy in the form of losses due to inefficiencies in the electrical equipment and distribution system. On average, electrical distribution system losses can account for 10% to 12% of the total energy consumed by the data center. That means a data center with 2 MW of IT load and a yearly average PUE of 1.45 (2.9 MW of total load) has 348 kW in electrical losses and will spend approximately $300,000 a year on wasted electrical energy. That wasted electrical energy cost in conjunction with tighter operational budgets and commitment to sustainability have forced engineers and owners to take a stronger look at electrical systems to find ways to eliminate electrical losses.
Legacy electrical distribution
In a typical legacy data center electrical distribution system, there are four components that contribute to the majority of the losses:
- Substation transformers: transformer no-load and core losses
- UPS: rectifier and inverter losses
- Power distribution units (PDUs): transformer no-load and core losses
- IT power supply: rectifier and transformer losses.
One method of reducing losses that does not affect the operation of the data center is using or replacing equipment like substation and PDU transformers with more efficient equipment. In 2005, the NEMA TP-1: Guide for Determining Energy Efficiency for Distribution Transformers was adopted, which increased minimum transformer efficiencies from about 97% to 99%, depending on the type and size of the transformer. In 2016, that minimum transformer efficiency requirement will increase by about 8% to 12% to further reduce energy consumption. Ultra-high-efficiency transformers are also available that have efficiency ratings above 99.5%.
Another method of increasing efficiency is to eliminate the equipment with the most losses. This method requires different power strategies, such as implementing higher-voltage ac and dc distribution to eliminate equipment like PDU transformers, UPS invertors, and IT power supply rectifiers. Each of these power strategies has advantages and challenges that impact the operation of the data center, so they must be evaluated when planning a data center.
A third method that manufacturers are recently promoting, and some facilities are starting to implement, involves the operation of the UPS system in some type of economical or eco mode. This mode of operation increases efficiency by eliminating the rectifier and inverter losses in the UPS.
The International Electrotechnical Commission (IEC) classifies UPS systems into the following performance categories:
- Voltage/frequency dependent (VFD): A UPS shall protect the load from power outages. The output voltage and frequency depend on the input ac source. It is not intended to provide additional corrective functions.
- Voltage independent: A UPS shall protect the load from power outages and provide stable voltage. The output frequency depends on the input ac source. The output voltage shall remain within prescribed voltage limits (provided by additional corrective voltage functions).
- Voltage/frequency independent (VFI): A UPS shall protect the load from power outages and provide stable voltage and stable frequency. The output voltage and frequency are independent of the input ac source.
VFD topology is commonly referred to as “offline” UPS, where the rectifier/inverter circuits are offline and not part of the normal power path. Because the losses associated with the rectifier/inverter are removed during normal operation, this mode is similar to the effect of operating a double-conversion in eco mode. In normal mode, the load on a VFD-type system is exposed to the raw utility power. These are traditionally smaller, single-phase-type UPS systems.
The VFI topology is more commonly known as double-conversion or “online” UPS, where in normal operation, the rectifier/inverter circuits are online and engaged (see Figure 1). Power is converted from ac to dc in the rectifier and then from dc back to ac in the inverter. Additionally, dc power is used to charge the stored-energy medium under normal operation, and draw power from the stored-energy medium during a power outage. Different technologies can be used for the stored-energy medium including batteries and flywheels. Double-conversion UPS systems are also equipped with a static bypass path that bypasses the rectifier/inverter circuit during a fault condition. For the purpose of this article, the focus will be on the double-conversion (VFI) static UPS topology.
Traditional eco mode
In the traditional or classic eco mode, the load is normally powered through the bypass path, exposing the critical load to the raw utility power without conditioning, similar to the VFD topology (see Figure 2). The inverter is in standby and only engaged when the utility fails. Because of this, the losses in the rectifier and inverter are eliminated, making the UPS system more efficient.
The average static double-conversion UPS system operates between 90% efficient at 30% load to about 94% efficient at 100% load. The efficiency percentage can go up or down a little depending on the technology used, and whether the UPS contains an input isolation transformer. With the elimination of the rectifier and inverter losses, the efficiency of the UPS system in eco mode can increase to 98% or 99%. In a 2N redundant-type (system + system) configuration, where the system is typically operating each UPS below 40%, that equates to about a 4% to 8% increase in efficiency. The increase in efficiency also means less heat, which reduces cooling requirements. The Green Grid estimates an average improvement of approximately 0.06 in PUE when going from double-conversion to eco mode.
Traditional eco-mode challenges
When operating in traditional eco mode, challenges to consider include:
- Unconditioned power: Critical load is exposed to raw utility power. Fluctuations in voltage or frequency are seen by the critical load.
- Transfer time: In eco mode, there is time required for the UPS system to detect the failure, turn on the inverter, transfer to a battery, and open the static bypass switch. Even though the transfer time may be within the Information Technology Industry Council (ITIC) curve for server devices, it could affect other components in the distribution system. PDU transformers can saturate, causing a large inrush of current when the voltage is restored and resulting in breakers tripping. Also, static transfer switches can change state.
- Harmonics: Double-conversion UPS systems isolate the electrical mains and generators from the harmonic content of the load. While operating in eco mode, the filtering function is defeated and the load harmonics are allowed to be passed directly back into the system.
- Thermal shock: During an outage event, the system will transfer the load (large, applied step load) to the inverter, which results in a thermal shock to the system. This thermal shock can cause failure to the electronics at a time when the UPS is needed most.
- Fault discrimination: Under normal operation, during a fault the UPS transfers to bypass for extra fault-clearing capacity to trip downstream protection devices. While in eco mode, it can be difficult for the UPS to determine if the drop in voltage was the result of a fault and loss of input power, and whether the fault was upstream or downstream. This can cause the system to transfer to inverter during a fault, extending the fault-clearing time and putting personnel and equipment at risk.
Some manufacturers claim there is an added benefit to using eco mode. When the system is operating in eco mode there is less heat so the fans can be switched off, which reduces the wear and tear on certain components and thereby extends their life expectancy.
Advanced eco mode
Due to advances in firmware control schemes, many manufacturers have upgraded their electrical designs and created what is becoming known as advanced eco mode (see Figure 3). Each manufacturer has a slightly different name and different method for how the system operates in this mode, but the net result is that the inverter stays on or engaged in the circuit, operating in parallel with the bypass without actually handling the load current.
With the inverter engaged under normal operation, many of the challenges of the traditional eco mode are eliminated or reduced.
- Transfer time: With the inverter already energized and engaged, there is no time required to turn on the inverter. The load can be seamlessly transferred to the stored-energy device when the utility fails, or to double-conversion mode when power conditions fall outside the predetermined limits.
- Unconditioned power: Because the inverter is engaged, the load can be seamlessly transferred to the inverter. Any fluctuation in power that falls outside the predetermined limits will cause the load to be transferred to double-conversion conditioned power.
- Harmonics: Double-conversion UPS systems isolate the electrical mains and generators from the harmonic content of the load. Because the inverter is connected and engaged in the system during advanced eco mode, it can be controlled to absorb and filter the harmonic current even though it is not carrying load.
It should be noted that because the inverter circuit is engaged, there are some losses associated with that. Therefore, overall efficiency of advanced eco mode may be slightly lower than that of traditional eco mode.
Traditional eco mode has many negative effects that reduce reliability. Because of that, data center operators and other mission critical type operations previously were not willing to put the critical load at greater risk just to save money on operating costs.
As operating budgets get tighter and operating costs continue to rise, more operators are looking toward eco mode as a means to reduce cost. Manufacturers have responded with more advanced eco-mode systems that eliminate many of the reliability issues associated with traditional eco mode. However, there are still some issues like thermal shock and fault discrimination that exist and must be reviewed when implementing and operating in eco mode. Also, because not all advanced eco-mode or high-efficiency-mode systems are the same, careful consideration must be made when selecting a system.
Situations where data center operators tend to be more willing to use eco mode is a UPS system supporting continuous cooling, and a 2N UPS system where only one of the UPS systems (either A or B) is running in eco mode.
The number of transfers from eco to double-conversion should be minimized. Make sure the power quality is excellent before engaging eco mode so you don’t have those transfer events that add risk to the load. Most manufacturers provide the ability to transfer the UPS into different modes of operation without requiring tech support. If there is a storm coming or an event that can affect the power quality of the system, recommend taking the system out of eco mode and putting it back into double-conversion until that event passes.
Modifications can be made and different modes of operation can be used to make the mechanical and electrical systems more efficient to save energy. The key to a good mission critical design and operation of a facility is to not degrade the reliability of the facility in the process.
About the author
Kenneth Kutsmeda is the engineering manager for mission critical at Jacobs. For 20 years, he has been responsible for engineering, designing, and commissioning power distribution systems for mission critical facilities. He is a member of the Consulting-Specifying Engineer editorial advisory board.
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