Crown ct-1610 Guía De Referencia

Page 45

Com-Tech Power Amplifiers

Reference Manual

7 AC Power Draw and
Thermal Dissipation

“““““Soft-Start” inrush current limiting, protects the house
circuit breaker when several amps are turned on simul-
taneously.

This section provides detailed information about the
amount of power and current drawn from the AC mains
by Com-Tech amplifiers and the amount of heat pro-
duced under various conditions. The calculations pre-
sented here are intended to provide a realistic and
reliable depiction of the amplifiers. The following as-
sumptions or approximations were made:

• The amplifier’s available channels are loaded, and full

power is being delivered.

• Amplifier efficiency at standard 1 kHz power is estimated

to be 65%.

• In 8/4 ohm mode, typical quiescent power draw is 20

watts for the Com-Tech 210, 30 watts for the Com-Tech
410, 55 watts for the Com-Tech 810 and 70 watts for the
Com-Tech 1610.

• In 70 volt mode, typical quiescent power draw is

30 watts for the Com-Tech 210, 35 watts for the
Com-Tech 410, and 90 watts for the Com-Tech 810 and
1610.

• When running at full speed, typical power draw for the

internal fan is 11 watts for the Com-Tech 210, 410 and
810, and 17 watts for the Com-Tech 1610 (the fan is an
option for the Com-Tech 210).

• Quiescent thermal dissipation is related .

• The estimated duty cycles take into account the typical

crest factor for each type of source material.

• Duty cycle of pink noise is 50%.

• Duty cycle of highly compressed rock ‘n’ roll midrange

is 40%.

• Duty cycle of rock ‘n’ roll is 30%.

• Duty cycle of background music is 20%.

• Duty cycle of continuous speech is 10%.

• Duty cycle of infrequent paging is 1%.

Here are the equations used to calculate the data pre-
sented in Figures 7.1 through 7.4:

AC Mains Power

Draw (watts)

Total output power with all

channels driven (watts)

x Duty

Cycle

Amplifier Efficiency (.65)

+ Quiescent Power

Draw (watts)

The value used for quiescent power draw includes both
the amplifier’s quiescent power draw for the selected
output mode and the power drawn by the fan if one is
installed (these values are listed in the previous col-
umn). The following equation converts power draw in
watts to current draw in amperes:

Current Draw

(amperes)

AC Mains Power

Draw (watts)

AC Mains

Voltage

Power

Factor (.83)

The power factor of 0.83 is needed to compensate for
the difference in phase between the AC mains voltage
and current. The following equation is used to calculate
thermal dissipation:

Total output power with all

channels driven (watts)

Thermal

Dissipation

(btu/hr)

Quiescent Power

Draw (watts)

.35

Duty

Cycle

Amplifier Efficiency (.65)

(

)

x 3.415

The constant 0.35 is inefficiency (1.00–0.65) and the
factor 3.415 converts watts to btu/hr. Thermal dissipa-
tion in btu is divided by the constant 3.968 to get kcal. If
you plan to measure output power under real-world con-
ditions, the following equation may also be helpful:

Total measured output power

from all channels (watts)

Thermal

Dissipation

(btu/hr)

Quiescent Power

Draw (watts)

.35

Amplifier Efficiency (.65)

(

)

x 3.415

8 Ohm Dual / 16 Ohm Bridge-Mono / 4 Ohm Parallel-Mono

L O A D

50%

40%

30%

20%

10%

200

165

135

100

305

265

225

185

145

265

215

170

125

210

175

145

110

340

300

260

220

180

2.4

2.0

1.6

1.2

0.8

3.1

2.6

2.0

1.5

0.9

2.5

2.1

1.7

1.3

0.9

Duty

Cycle

AC Mains

Power

Draw

(Watts)

btu/hr

Current Draw (Amps)

1.1

0.9

0.7

0.5

0.3

1.4

1.2

0.9

0.7

0.4

1.1

1.0

0.8

0.6

0.4

4 Ohm Dual / 8 Ohm Bridge-Mono / 2 Ohm Parallel-Mono

70 V

Com-Tech 210

kcal/hr

380

325

270

215

160

100-120 V 220-240 V

Thermal Dissipation

btu/hr

Current Draw (Amps)

kcal/hr

100-120 V 220-240 V

Thermal Dissipation

btu/hr

Current Draw (Amps)

kcal/hr

100-120 V 220-240 V

Thermal Dissipation

AC Mains

Power

Draw

(Watts)

AC Mains

Power

Draw

(Watts)

Fig. 7.1 Com-Tech 210 Power Draw, Current Draw and Thermal Dissipation at Various Duty Cycles