Maximum Input Amps; Thermal; Acoustics; Shock And Vibration Specifications - Dell PowerEdge T110 II Technical Manual

Table 6 shows the shock and vibration specifications for the PowerEdge T110 II.
Maximum Vibration
Operating
Storage
Maximum Shock
Operating
Storage

5.5 Maximum Input Amps

Maximum input current (high-output power supply):

9A @ 90 VAC

4.5A @ 180 VAC

5.6 Thermal

The thermal design of the PowerEdge T110 II reflects the following:

Closed-loop thermal fan speed control: The closed-loop thermal control method uses
feedback temperatures to dynamically determine proper fan speeds.

Comprehensive thermal management: The PowerEdge T110 II controls system cooling fan
speed based on several different responses from critical component sensors, such as processor
temperature, inlet ambient temperature, and system configurations. The thermal
management adjusts proper cooling for the system according to what the system really needs.

Optimized Ventilation: The T110 II chassis has a custom ventilation design for optimized air
flow path. Each component and peripheral is ensured sufficient air for cooling.

Environmental Specifications: The optimized thermal management makes the T110 II
reliable under a wide range of operating environments.

5.7 Acoustics

The acoustical design of the PowerEdge T110 II reflects the following:

Adherence to Dell's high standards for sound quality: Sound quality is different from sound
power level and sound pressure level in that it describes how humans respond to annoyances
in sound, like whistles and hums. One of the sound quality metrics in the Dell specification is
prominence ratio of a tone, which is listed in Table 7.
PowerEdge T110 II Technical Guide
Table 6.

Shock and Vibration Specifications

0.26Grms at 5–350Hz for 15 minutes
1.88Grms at 10–500Hz for 15 minutes
One shock pulse in the positive z axis (one pulse
on each side of the system) of 31G for 2.6ms in
the operational orientation
Six consecutively executed shock pulses in the
positive and negative x, y, and z axes (one pulse
on each side of the system) of 71G for up to
2ms.
Six consecutively executed shock pulses in the
positive and negative x, y, and z axes (one pulse
on each side of the system) of Half-sine shock
71G for up to 2ms and square-wave shock 32G,
270 in/sec.
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