Practical Power Guidelines for VoIP and
Internet Telephony Applications
by David Slotten
WHITE
PAPER
95-2914
Cisco, Cisco Systems, the Cisco Systems logo, and the Cisco Square Bridge logo
are registered trademarks or trademarks of Cisco Systems, Inc. and/or its affiliates
in the U.S. and certain other countries.
Consider the Diverse Needs of VoIP Network Equipment
Before selecting a UPS System to ensure 100% availability of IP telephony
systems, it's important to consider the unique requirements of VoIP network
equipment. Network designs hosting VoIP applications will vary widely from
business to business due to a number of variables, including the scale of
the network and the variety of legacy equipment involved. However, three
devices are common to all networks:
Client Devices (phones, PC-based soft phones, etc.)
During the transition to IP telephony, these devices will either (a) derive
their power from the network cable via a Power over Ethernet (PoE)
connection scheme, or (b) plug into a local AC source.
If they plug into a local AC source, they must be protected by a UPS
System. Often a desktop UPS not only safeguards phone service, but also
guarantees file integrity for associated PC users.
Typical VoIP
Network Design
Networking Devices (switches, routers, etc.)
During the transition to IP telephony, port capacity on the network and in
wiring closets will increase to accommodate additional devices (phones)
connected to the network. Increased port capacity will increase the power
requirements placed on your UPS System, either reducing runtime or
overloading the UPS. Note that if a networking device also supplies Power
over Ethernet, the aggregate load of all client devices will also be borne by
the networking device's UPS System.
Generally, an existing UPS will be inadequate to (a) power the increased
load [watts] and (b) power the load for an acceptable length of time. Five to
fifteen minutes of runtime provided to gracefully shut down the typical data
network is inadequate for IP telephony users who expect phone service to
continue for HOURS, not minutes.
Source: Cisco Systems white paper
“Power and Cooling for VoIP and IP
Telephony Applications”.
us/guest/netsol/ns412/c654/cdccont_
0900aecd801a2c5f.pdf
Call Processing Devices (servers and related storage systems)
During the transition to IP telephony, dedicated servers are typically added
to drive voice and messaging applications, while storage systems are
required for voicemail and other messaging applications. Similar to the
increased burden placed on networking devices, call processing devices will
experience increased loads and will require increased runtime.
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Select a UPS System which Provides the Highest Availability, Resiliency
and Manageability
When selecting a UPS System, the most obvious criterion to consider is
whether a UPS System has enough capacity (VA/watts) to power equipment
while having enough battery capacity to operate during a power outage for
your required duration. Specific Tripp Lite UPS System recommendations are
listed at the end of this document. Often overlooked during the selection
process, however, are more subtle, yet critical, criteria that should be
considered, including availability, resiliency to power anomalies and
manageability.
1. Availability
Availability hinges on three considerations: the VoIP equipment's power
supply configuration, the UPS System's battery configuration and the UPS
System's power electronics topology.
A. VoIP Equipment Power Supply Configuration
Many switches and routers are equipped with redundant power supply
capability. If one power supply fails, a second power supply steps in
and powers the device. Redundant power supply configurations are
strongly recommended to ensure continuous system availability.
Whether one or two power supplies are deployed, the equipment can
draw power from one of three sources: directly from facility power alone
(for simplicity's sake we will use the term “wall” to describe this
source), from a single UPS System or from multiple UPS Systems.
The following tables detail a switch's operational status, from a power
perspective, in both redundant and combined (non-redundant) modes.
The tables detail switch status under a variety of operational scenarios,
including power supply failure, utility failure and UPS System failure.
Note: Larger switches often have the capability to be alternatively configured to operate in
a combined (non-redundant) configuration. In combined mode, two power supplies'
capacities will be summed. A true doubling is not generally achieved. A factor of 1.67x is
typical. In combined mode, there is no redundancy. Should a power supply fail, the
available power is generally reduced to the capacity of a single power supply.
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Single Power Supply, or Multiple Power Supplies Operating in Redundant Mode
STEP 1: Determine Configuration
Configuration
Power Supply
Power Source
1
PS1
Wall
2
3
4
5
PS1
Wall
PS2
Wall
PS1
UPS1
PS2
Wall
PS1 & PS2
UPS1
PS1
UPS1
PS2
UPS2
STEP 3: Consider System Status
Utility Status UPS Status System Status System Status System Status
STEP 2: Consider Failure Scenarios
PS1 Status
System Status
System Status
OK
Failure
OK
OK
OK
OK
OK
OK
OK
OK
OK
OK
OK
Crash
OK
OK
OK
OK
OK
Crash
Crash
Crash
Blackout
Blackout
OK
Crash
Crash
OK
Crash
OK
UPS1 Battery
Fails
Crash
OK
OK
Blackout
OK
UPS1 Internal
Fault
UPS1 Battery
Fails
Crash
—
Crash
—
Crash
Crash
OK
OK
OK
OK
Hot swap battery
Hot swap battery
Hot swap battery
Line-Interactive UPS Systems
OK
OK
UPS1 Internal
Fault
—
—
OK
Crash
OK
Replace UPS.
System on PS2/Wall.
Vulnerable to outage
during UPS
Replace UPS.
Replace UPS.
System on PS2/UPS2.
Services OK during
UPS replacement
replacement
On-Line UPS Systems
OK
UPS on bypass,
OK
OK
UPS on bypass.
UPS on bypass,
System on PS2/Wall. System on Wall. System on PS2/UPS2.
Replace UPS1.
Vulnerable to
outage during UPS
replacement
Services down*
while replacing
UPS1
Replace UPS1.
Services OK during
UPS replacement
*SmartOnline Hot-Swappable Modular 5-16KVA UPS system hardware can be hot swapped without service outage.
Multiple Power Supplies Operating in Dual (Combined, Non-Redundant) Mode
STEP 1: Determine Configuration
Configuration
Power Supply
Power Source
1
2
3
PS1
Wall
PS2
Wall
PS1
PS2
PS1
UPS1
PS2
UPS2
UPS1
STEP 3: Consider System Status
STEP 2: Consider Failure Scenarios
PS1 Status
Utility Status UPS Status
System Status
OK
Reduced Output
Crash
System Status
System Status
OK
Failure
OK
OK
OK
OK
OK
OK
OK
OK
OK
OK
OK
Blackout
Blackout
OK
OK
UPS1 Battery
Crash
Crash
Reduced Output
Fails
Replace UPS1.
Output reduced during UPS
Replace UPS1.
Output reduced during UPS
replacement
replacement
OK
OK
OK
Blackout
OK
UPS1 Internal
Fault
—
—
—
Crash
Replace UPS1
Reduced Output
Replace UPS1. Output reduced
until UPS1 replacement
OK
UPS1 Battery
Fails
OK
Hot swap battery
Line-Interactive UPS Systems
Hot swap battery
OK
UPS1 Internal
Fault
Crash
Reduced Output
Replace UPS. Plug into wall until
UPS replacement
Replace UPS1. Plug PS1 into wall
to restore full power until UPS1
replacement. Output reduced
until UPS1 replacement
On-Line UPS Systems
OK
OK
Replace UPS1.
Replace UPS1.
Both PS on UPS Bypass.
Services down* while replacing
UPS1
PS1 on UPS1 Bypass circuit,
vulnerable to outage. Reduced
power during UPS1 replacement
*SmartOnline Hot-Swappable Modular 5-16KVA UPS system hardware can be hot swapped without service outage.
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B. UPS System Battery Configuration
UPS System availability, and therefore VoIP system availability, is most
critically dependent upon the capacity of the UPS System's battery
configuration. The number of UPS System batteries, both internal and
external, determines the amount of runtime that is provided during a
power outage. As mentioned previously, the runtime must fit the
application. Most existing data networks are unlikely to provide reserve
runtime power comparable to the public switched phone network. One
has to determine a runtime estimate of what is adequate or desirable
specifically for a VoIP application. Most users conclude that hours, not
minutes, of backup runtime are required to maintain voice operations.
Like any estimate, a runtime estimate will be imperfect and will also be
impacted by future capacity requirements (such as the addition of more
phones). Therefore, it is critical that the selected UPS System can
accommodate external battery packs to increase runtime as needs
increase, or maintain runtime in a growing phone environment.
Runtime scalability with external battery packs also yields the ability to
hot swap battery packs at the end of their useful life without a service
interruption. Similar hot swap battery replacement is also the norm for
the UPS System's internal batteries.
C. UPS System Power Electronics
If a UPS System's power electronics fail during a utility power outage,
the supported IP telephony system will obviously crash. If the UPS
System failure occurs while utility power is present, however, different
UPS power electronics topologies can impact IP telephony system
availability in different ways.
On-Line UPS System with Internal Bypass
With power present, an internal power electronics fault in an on-line
UPS System will result in the load automatically being powered by a
bypass path inside the UPS. As long as utility power remains present,
the UPS will continue to power the connected IP telephony system
without interruption and will continue to condition the power against
basic power anomalies. In the event of a power outage, the system
will crash.
Upon development of a bypass condition, a service interruption needs
to be planned to replace the UPS System.
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With power present, a battery system failure will not cause a system
interruption. As long as utility power remains present, the UPS
System will continue to power the connected IP telephony system
without interruption and will continue to condition the power against
most power anomalies. In the event of a power outage, the system
will crash.
In the event of a battery system failure, the internal batteries of the
UPS System and/or the external battery packs can be replaced
without a service interruption.
On-Line UPS System with Internal Bypass and External
Maintenance Bypass
With power present, an internal power electronics fault will result in
the load automatically being powered by a bypass path inside the
UPS. As long as utility power remains present, the UPS will continue
to power the connected VoIP system without interruption and will
continue to condition the power against basic power anomalies. In
the event of a power outage, the system will crash.
In the event of a bypass condition, the power electronics module of
the UPS should be replaced. This can be performed while the system
remains in service, as the input and output power connections are
physically and electrically separated from the power module itself.
This functionality is available presently in Tripp Lite's 5-16KVA
SmartOnline™ Hot-Swappable Modular UPS Systems.
With power present, a battery system failure will not cause a system
interruption. As long as utility power remains present, the UPS
System will continue to power the connected IP telephony system
without interruption and will continue to condition the power against
most power anomalies. In the event of a power outage, the system
will crash.
In the event of a battery system failure, the internal batteries of the
UPS System and/or the external battery packs can be replaced
without a service interruption.
Line-Interactive UPS System
With power present, an internal power electronics fault can result in
the load crashing. As the operational requirements of a line-interactive
UPS System are very simple when power is present, this is extremely
rare. Line-interactive power electronics failures are normally only
detected when the power fails and the UPS attempts to power the load
from its battery-driven inverter.
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In the event of a power electronics failure, a service interruption
needs to be planned to replace the UPS System.
With power present, a battery system failure will not cause a system
interruption. As long as utility power remains present, the UPS
System will continue to power the connected IP telephony system
without interruption and will continue to condition the power against
many power anomalies. In the event of a power outage, the system
will crash.
In the event of a battery system failure, the internal batteries of the
UPS System and/or the external battery packs can be replaced
without a service interruption.
2. Resiliency to Power Anomalies
The fundamental outcome one hopes for in adding UPS System support to
a network is to enhance system availability. But an additional concept—
resiliency—is very important as well. UPS System resiliency reflects the
ability to respond positively to a number of operating variables.
A. Voltage Variation
Currently, one of the most popular UPS System topologies for VoIP is
provided by on-line UPS Systems. An on-line UPS System can deliver
perfect power even if it encounters a very wide range of input voltages.
The on-line UPS does this without relying on its battery reserves, leaving it
well prepared to respond to a power outage. Because of its continuous
AC-DC-AC conversion process, during an outage an on-line UPS System
will also exhibit zero transfer time between power failure detection and
power delivery to your equipment. On-line UPS Systems are widely
acknowledged to be compatible with all types of VoIP devices.
In many networks with distributed UPS Systems, line-interactive UPS
Systems are widely deployed. If input voltage levels are below the line-
interactive UPS System's automatic correction capability, the UPS will
switch to battery to maintain acceptable output voltage. In areas with
chronic extreme brownouts, this frequent switching to battery can reduce
reserve power as well as shorten battery service life—putting critical
systems at risk in an outage.
While the transfer time of a line-interactive UPS System (several
milliseconds) is extremely fast, this short delay has been theorized as the
cause of packet losses, or even system shutdown in some applications.
Depending on your power environment and the sensitivity of your IP
telephony components, a line-interactive UPS System may or may not be
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adequate. Generally, line-interactive UPS Systems do not pose a problem.
This is the subject of some debate and is generally presented as a major
issue by vendors biased towards selling online UPS Systems.
Line-interactive UPS Systems do tend to cost less than on-line UPS
Systems and operate with higher efficiency, reducing electrical costs.
In theory, an on-line UPS System battery should be used less frequently
due to input voltage variation, and will therefore last longer. This advantage
will manifest itself more as the frequency of input voltage variation
increases.
B. Harmonic Distortion
Only an on-line UPS System will address input harmonic distortion.
Because an on-line UPS System deconstructs and reconstructs the input
power, it can deliver distortion-free power. A line-interactive UPS System
will pass through input waveform distortions. Harmonic distortion tends to
be an elusive “gremlin” issue when it affects connected loads.
C. Transient Spikes (or “Surges”)
Both line-interactive and on-line UPS Systems address sudden increases in
voltage.
D. Electromagnetic Interference
While both line-interactive and on-line UPS Systems address these
phenomena, an on-line UPS typically offers far superior filtering capability.
3. Manageability
VoIP system availability is closely tied to UPS System manageability. To
ensure continuous availability, UPS Systems must be incorporated as an
integral part of a sound hardware management scheme. UPS Systems are
extremely manageable and responsive, communicating their status
automatically and triggering application shutdowns prior to battery
exhaustion in the event of a power outage or extreme voltage variation.
There are various methods to communicate with UPS systems, including
SNMP, Web, network software and direct connection. While most users
choose SNMP/Web accessory cards installed inside UPS Systems for
communication, the most essential requirement is to deploy and use some
method of communication. Without a management application running for
your UPS Systems, the day will come when the UPS batteries fail and your
system fails as your power fails. Simple management steps taken at
installation can save significant problems later.
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Alerts available from most UPS Systems and network cards include:
• Voltage levels
• Current levels
• Temperature levels
• Humidity levels
• Dry contacts for fire, water, security, etc.
• Battery capacity
• Battery failure
Commands from the administrator to most UPS Systems include:
• Reboot system
• Reboot outlet(s)
• Shut down system
• Shut down outlet(s)
• Run inverter/battery test
Tripp Lite presents a uniquely simple management scheme for VoIP
UPS System hardware. Whether management is through an IP-addressed
SNMP/Web accessory card or PowerAlert Software, Tripp Lite provides
administrators with a single JAVA-based user interface. The commonality
within this design approach makes it ideal for managing VoIP applications
of all scales across multiple OS platforms.
During a power failure, Tripp Lite's PowerAlert Software ensures a smooth
and customizable shutdown of call processing and voice messaging
applications as well as the underlying operating system.
As a unique feature, Tripp Lite's PowerAlert Software and network accessory
card (SNMPWEBCARD) are designed to accommodate multiple power
supply and UPS System hardware deployments. With a single IP address
assigned to the SNMPWEBCARD (or a single PC/Server running PowerAlert)
users can manage multiple redundant UPS Systems working in tandem to
provide optimal power to the IP telephony system's single or multiple power
supplies.
Alternative UPS System manufacturers require each UPS to be managed
individually. With these UPS Systems, there is no easy way to manage their
redundant operation without expensive and space-consuming external
power-switching accessories.
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Tripp Lite's PowerAlert Software, version 12.5—which is part of an
integrated VoIP power solution that includes a Tripp Lite UPS System—has
met the Cisco Technology Developer Partner Program test criteria for
interoperability with Media Convergence Servers running CallManager,
versions 3.3(4) and 4.0(2). Through participation in the Cisco Technology
Developer Partner Program, Tripp Lite's integrated VoIP solution provides
continuous IP telephony availability to enterprise customers.
As an additional management tool, PowerAlert also offers centralized
management within a NMS-style, management tool.
Another unique manageability product provided by Tripp Lite is its Watchdog
Service Monitoring/Rebooting Software. Tripp Lite's Watchdog Software
ensures maximum availability, eliminating call processing server downtime
by automatically rebooting locked-up or poorly performing system service
applications. If a locked service cannot be rebooted, Watchdog Software
will automatically direct PowerAlert Software to reboot the server. If the
server is non-responsive, the UPS System will power down and then restart
the attached devices.
Recommended Tripp Lite UPS Systems for VoIP Applications
Establishing an adequate power protection infrastructure is essential. Again, three
areas of demand must be addressed: Client, Network and Call Processing.
Client Devices (phones, PC-based soft phones, etc.)
• IP Phones
If the phone is powered by Ethernet (PoE), it is switch supported
and no client UPS System is required. (Backup will be provided
at the switch.)
If the phone plugs into the utility wall outlet, a UPS System is required.
– Up to 4 hours - Tripp Lite UPS model: INTERNET750U
• Soft Phones (PC based)
Typically, a UPS System is required:
– Up to 1 hour - Tripp Lite UPS model: OMNIVS1500XL
– Up to 3 hours - Tripp Lite UPS model: OMNIVS1500XL
(Plus Tripp Lite battery pack model: BP24V28-2U
• Soft Phones (Notebook PC based)
– Up to 2 hours - internal notebook battery support
– Up to 4 hours - Tripp Lite UPS model: INTERNET750U
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Networking Devices (switches, routers, etc.)
Networking hardware will typically drive the most significant changes to your
existing power infrastructure. With requirements spanning buildings and
remote wiring closets, existing facility-wide backup plans are often
impractical or unable to address the requirements of mid-size and large
switches. Focused UPS System additions with extended runtime battery
configurations more efficiently add the high level of availability that VoIP
users demand.
Tripp Lite maintains interactive sizing and configuration resources at
technical staff via [email protected] or (773) 869-1234.
Basic sizing is as simple as…
1. Determining the power consumption of your equipment:
Volts x Amps = VA.
2. Ensuring that the UPS System has enough power and outlets to
accommodate your equipment.
Many larger routers and switches accommodate multiple power supplies.
Once you have identified your power supply type and quantity, use the
following details to find a specific UPS System solution for your needs:
1. Identify power supply configuration
a. Single power supply or two supplies operating in redundant mode
b. Dual (combined) mode
2. Determine UPS System protection scheme
a. Single UPS System for both power supplies
b. Single UPS System per power supply (higher availability)
3. Estimate desired runtime during power outage
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Call Processing Devices (servers and related storage systems)
Typically, additional server and storage resources are added to handle call
processing, voice messaging and other telephony applications. Such
systems tend to reside within the data center and are multi-vendor in origin.
For configuration assistance specific to your rollout, please contact
Tripp Lite. Tripp Lite maintains interactive sizing and configuration resources
technical staff via [email protected] or (773) 869-1234.
Common Tripp Lite UPS Systems Recommended for VoIP Networking
Device Applications (Specifications & Runtime Charts)
UPS System Specifications
Input
Voltage
Range
Nominal
Output
Voltage
Capacity
(VA/Watts)
Outlet
Quantity
Outlet
Type
Input Plug
Type
Model
RU
Depth
Bypass
SmartOnline On-Line UPS Systems
SU2200RTXL2Ua
65-138
120
2200/1600
3000/2400
7
9
6 (5-20R)
5-20P
5-20P
2U
3U
19 in.
26 in.
Internal
Internal
(110/120)
1 (L5-20R)
SU3000RTXL3U
65-138
120
(110/120)
4 (5-15R)
4 (5-20R)
1 (L5-30R)
SU3000RTXL3UHV
SU5000RT3U
160-275
156-276
208/240
3000/2400
5000/3500
8
6 (6-20R)
L6-20P
L6-30P
3U
7U
21 in.
21 in.
Internal
Internal
2 (L6-20R)
208 & 120
16
2 (L6-20R)
2 (L6-30R)
12 (5-20R)
SU5000RT3UHV
SU5000RT4U
156-276
208/240
5000/3500
5000/3800
4
2 (L6-20R)
L6-30P
5U
21 in.
Internal
2 (L6-30R)
65-140
(L-N)
208/240
& 120
12
8 (5-15/20R)
2 (L6-20R)
2 (L6-30R)
L14-30P
4U 30.75 in.
Internal/External
SU6000RT3U
SU6000RT4U
156-276
208/240
& 120
208/240
& 120
6000/4200
6000/4200
Hardwire*
12
Hardwire*
Hardwire*
L14-30P
9U
26 in.
Internal/External
Internal/External
65-140
(L-N)
8 (5-15/20R)
2 (L6-20R)
2 (L6-30R)
4U 30.75 in.
SU8000RT3U
156-276
156-276
208/240
8000/6400
7500/6000
6
4 (L6-20R)
Hardwire
Hardwire
6U
8U
31.5 in.
31.5 in.
Internal/External
Internal/External
2 (L6-30R)
SU8000RT3U1TF
208 & 120
18
12 (5-15/20R)
4 (L6-20R)
2 (L6-30R)
SU8000RT4U
65-140
(L-N)
208/240
& 120
8000/5600
8
Hardwire
4 (5-15/20R)
2 (L6-20R)
2 (L6-30R)
Hardwire
4U
34 in.
Internal/External
SU10000RT3U
156-276
156-276
208/240
10000/8000
6
4 (L6-20R)
Hardwire
Hardwire
6U
31.5 in.
Internal/External
Internal/External
2 (L6-30R)
SU10000RT3U2TF
208 & 120 10000/8000
30
24 (5-15/20R)
4 (L6-20R)
2 (L6-30R)
10U 31.5 in.
SU10KRT3U
156-276
208/240
& 120
208/240
& 120
10000/8000
Hardwire
+13
Hardwire
Hardwire
Hardwire
9U
8U
31.5 in.
40.5 in.
Internal/External
Internal/External
SU16000RT4U
65-140
(L-N)
16000/11200
Hardwire
5 (5-15/20R)
2 (L6-30R)
6 (C19)
* SU6000RT3U can provide outlets when used with optional back panel accessory (SUPDM12) which provides two L6-20R, one L6-30R and ten 5-20R outlets and
a cord with a L6-30P input plug.
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SmartPro® Line-Interactive UPS Systems
Input
Voltage
Range
83-145
120
Nominal
Output
Capacity
Outlet
Outlet
Type
8 (5-15R)
4 (5-15R)
4 (5-20R)
Input Plug
Type
5-15P
5-20P
Model
SMART1500CRMXL
SMART2200RMXL2U
Voltage
120
120
(VA/Watts)
Quantity
RU
2U
2U
Depth
19 in.
17 in.
Bypass
Internal
None
1500/1440
2200/1600
8
8
SMART2200CRMXL
SMART3000RM2U
83-145
120
120
120
2200/1900
3000/2250
8
9
4 (5-15R)
5-20P
L5-30P
4U 16.75 in.
2U 17 in.
Internal
None
4 (5-15R)
4 (5-20R)
1 (L5-30R)
SMART3000CRMXL
SMART5000XFMRXL
83-145
208
120
3000/2880
5000/3750
9
8 (5-15R)
1 (L5-30R)
8 (5-20R)
2 (L6-20R)
1 (L6-30R)
L5-30P
L6-30P
4U 16.75 in.
3U 23 in.
Internal
None
208 & 120
11
UPS System Extended Runtime
SmartOnline On-Line UPS Systems
Half load (Watts)
Runtime (minutes)
Non-Expandable Battery Pack
Expandable Battery Pack*
Full Load (Watts) with included batteries
1
2
3
4
BP48V24-2U
(Non-Expandable)
BP48V60RT-3U
(Expandable)
378
186
SU2200RTXL2Ua Extended Runtime
800
1600
14
4.5
56
23
117
50
266
122
530
246
BP72V15-2U
BP72V28RT-3U
(Expandable)
158
69
SU3000RTXL3UHV & SU3000RTXL3U Extended Runtime (Non-Expandable)
1200
2400
17
6
41
17
78
33
252
108
327
150
BP240V10RT-3U
(Expandable)
SU5000RT3UHV & SU5000RT3U Extended Runtime
1750
3500
20
8
N/A
N/A
73
31
161.6
70
225.8
100
291
131
SU5000RT4U Extended Runtime
1900
3800
14
6
N/A
N/A
97.4
42.5
158.4
70.7
221.5
100.7
285.5
131.7
BP240V10RT-3U
(Expandable)
131
SU6000RT3U Extended Runtime
2100
4200
37
15
N/A
N/A
79
37
174
79
222
104
58
SU6000RT4U Extended Runtime
2100
4200
24
9
N/A
N/A
86.6
36.8
141.4
61.5
198.2
87.8
256
115.2
BP240V10RT-3U
(Expandable)
SU8000RT3U Extended Runtime
3200
6400
15
6
N/A
N/A
46
18
76
32
109
46
142
60
SU8000RT3U1TF Extended Runtime
3200
6400
15
6
N/A
N/A
46
18.6
76.4
31.6
108.7
45.6
142
60.4
BP192V12-3U
(Expandable)
SU8000RT4U Extended Runtime
2800
5600
12
5
N/A
N/A
47
19
100
42.8
141.1
61.5
183.8
81.1
BP240V10RT-3U
(Expandable)
58.6
23.5
SU10KRT3U, SU10000RT3U, & SU10000RT3U2TF Extended Runtime
4000
8000
10
4
N/A
N/A
35.1
13.7
83.8
34.1
110
45.3
BP192V18-4U
(Expandable)
70.2
29.2
SU16000RT4U Extended Runtime
5600
12
5
N/A
N/A
42.2
17.1
100
42.2
130.9
55.9
11200
* Included batteries are contained either internally within the UPS system or are included as an external module, depending on model. ** Battery packs
which are expandable can be connected together for increased runtime. Call Tripp Lite's Application Specialists at (773) 869-1236 for additional extended
runtime solutions to fit your specific load requirements.
© 2008 TRIPP LITE. ALL RIGHTS RESERVED. THE POLICY OF TRIPP LITE IS ONE OF CONTINUOUS IMPROVEMENT.
14
SPECIFICATIONS ARE SUBJECT TO CHANGE WITHOUT NOTICE.
ALL TRADEMARKS ARE THE PROPERTY OF THEIR RESPECTIVE OWNERS.
SmartPro Line-Interactive UPS Systems
Half load (Watts)
Runtime (minutes)
Non-Expandable Battery Pack
Expandable Battery Pack*
Full Load (Watts) with included batteries
1
2
3
4
BP48V24-2U
(Non-Expandable)
BP48V48RT4U
(Expandable)
SMART1500CRMXL Extended Runtime
720
1440
28.5
11
70.6
28.1
195.5
82.1
349.2
152
504.2
225
658.8
299.3
BP48V24-2U
(Non-Expandable)
BP48V60RT-3U
(Expandable)
SMART2200RMXL2U Extended Runtime
800
1540
16
6
62
24.5
128
52.6
264.3
113
403.4
177.3
542.9
243.5
BP48V24-2U
(Non-Expandable)
BP48V48RT4U
(Expandable)
SMART2200CRMXL Extended Runtime
950
1900
28.5
11
68.8
27.7
154
64.5
265.4
114.8
378.7
167.7
492.5
222
BP48V24-2U
(Non-Expandable)
BP48V60RT-3U
(Expandable)
SMART3000RM2U Extended Runtime
1120
1600
21.2
8.5
59.9
24.9
124.3
53.4
256.2
114.5
391.5
179.7
527.2
246.6
BP48V24-2U
(Non-Expandable)
BP48V48RT4U
(Expandable)
SMART3000CRMXL Extended Runtime
1440
2880
19
7.5
35.4
14.7
81.7
35.2
144.3
63.8
209.5
94.5
276
126.4
BP48V60RT-3U
(Expandable)
SMART5000XFMRXL Extended Runtime
1875
3750
27
10
N/A
N/A
63
24.4
117.9
47
175.8
71.7
235.2
97.6
* Battery packs which are "expandable" can be connected together for increased runtime. Call Tripp Lite's Application Specialists at (773) 869-1236 for additional extended runtime solutions to
fit your specific load requirements.
About the author: David Slotten is Director of Product Management
at Tripp Lite. Mr. Slotten joined Tripp Lite in 1990 and has extensive
experience in the sale, marketing, engineering and development of power
protection systems. Mr. Slotten has an MBA from Lake Forest Graduate
School of Management and a bachelor’s degree from the University of
Wisconsin.
For Additional VoIP and Internet Telephony
Application Assistance Call Tripp Lite's
Application Specialists at (773) 869-1236
Tripp Lite World Headquarters • 1111 W. 35th Street • Chicago, IL 60609 USA
Tripp Lite's PowerAlert Software, version 12.5, has tested compatible with Cisco CallManager, versions 4.0 and 4.1, Cisco 7600 Series Routers, 7500 Series Routers and Catalyst 65XX Layer 3 Switch. Tripp Lite
PowerAlert Software, version 12, has tested compatible with Cisco CallManager, versions 3.3(4)-MCS and 4.0(2)-MCS. The Cisco Compatible logo signifies that Tripp Lite's product has undergone interoperability
testing by Tripp Lite together with Cisco and a third-party test house based on testing criteria set by Cisco. Tripp Lite is solely responsible for the support and warranty of its product. Cisco makes no warranties,
express or implied, with respect to Tripp Lite's product or its inter-operation with the listed Cisco product(s) and disclaims any implied warranties of merchantability, fitness for a particular use or against infringement.
Tripp Lite is a Cisco Technology Developer Partner in the Cisco Technology Developer Program.
Cisco, Cisco Systems, the Cisco Systems logo, and the Cisco Square Bridge logo are registered trademarks or trademarks of Cisco Systems, Inc. and/or its affiliates in the U.S. and certain other countries.
© 2008 TRIPP LITE. ALL RIGHTS RESERVED. THE POLICY OF TRIPP LITE IS ONE OF CONTINUOUS IMPROVEMENT.
15
SPECIFICATIONS ARE SUBJECT TO CHANGE WITHOUT NOTICE.
ALL TRADEMARKS ARE THE PROPERTY OF THEIR RESPECTIVE OWNERS.
200801210 95-2914
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