Meyer Sound Portable Speaker MSL 6 User Manual

Operating Instructions  
MSL-6  
Self-Powered Loudspeaker System  
Copyright © 1997 Meyer Sound Laboratories, Inc.  
All rights reserved  
Part # 05.053.026.01 Rev A  
 
Introduction  
AC Power  
The MSL-6, Meyer Sounds largest self-powered speaker,  
is ideally suited for large-scale vocal public address  
applications as a stand-alone system, and for musical  
sound reinforcement in combination with Meyer self-  
powered subwoofers and/ or the DS-2P mid-bass speaker.  
The MSL-6 features a 25° vertical coverage angle,  
permitting long-throw arrays with up to three vertical  
rows with minimal overlap between coverage areas.  
When AC power is applied to the MSL-6, the Intelligent  
AC™ supply automatically selects the correct operating  
voltage, allowing the MSL-6 to be used internationally  
without manually setting voltage switches. The Intelligent  
AC supply performs the following protective functions  
to compensate for hostile conditions on the AC mains:  
suppresses high voltage transients up to several  
kilovolts  
The center and outer high frequency horns utilize  
separate amplifier and control electronics to achieve a  
30° horizontal coverage angle for a single MSL-6. Tight-  
packing two units together yields a 60° coverage angle.  
Since the MSL-6 is intended for tight-packing only, array  
design is simple and modular: each additional unit  
increases the horizontal coverage by 30°. The maximum  
horizontal array size is twelve units, resulting in a  
circular array with 360° coverage.  
filters common mode and deference mode radio  
frequencies (EMI)  
sustains operation during low voltage periods  
provides soft-start power-up, which eliminates  
high inrush current  
The MSL-6 can withstand continuous voltages up to  
275 V and allows any combination of voltage to GND  
(i.e. Neutral-Hot-GND, Hot-Hot-GND). Continuous  
voltages higher than 275 V may damage the unit.  
The MSL-6 contains amplifier and control electronics  
for two 12” low frequency cone drivers and three high  
frequency horn drivers (2” throat, 4” diaphragm) in a  
compact trapezoidal cabinet. Each 12” driver is inde-  
pendently amplified and contained in a horn-loaded  
vented enclosure. This integrated design improves  
perform ance, d urability, and reliability, elim inates  
am plifier racks, and simplifies setup and installation.  
The MSL-6 uses a NEMA L6-20P or IEC 309 male power  
inlet and satisfies UL, CSA, and EC safety standards.  
Voltage Requirements  
The MSL-6 operates safely and without audio disconti-  
nuity if theAC voltage stays within either of two operating  
windows: 85–134 V or 165–264 V, at 50 or 60 Hz. After  
applying AC power, the proper operating voltage is  
automatically selected, but the system is muted. During  
the next three seconds, the primary fans turn on, the  
main power supply slowly ramps on, the green Active  
LED on the user panel illuminates, and the system is  
enabled to pass audio signals.  
The MSL-6 can be equipped to operate with the Remote  
Monitoring System (RMS™) network and software  
application. RMSdisplays signaland power levels, driver  
and cooling fan status, limiter activity, and amplifier  
temperature for allspeakers in the network on a Windows-  
based PC. Contact Meyer Sound for more information  
about RMS.  
TROUBLESHOOTING NOTE: If the Active LED does  
not illuminate or the system does not respond to audio  
input after ten seconds, remove AC power. Electronics  
technicians with access to a test bench can contact  
Meyer Sound to receive The Meyer Sound Self-Powered  
Series MP-2 and MP-4 Field Verification Procedure  
(part # 17.022.066.01). This service document contains  
a series of tests to verify that the power supply and  
amplifier are functioning properly. Other users should  
contact Meyer Sound or an authorized service center.  
3
 
If the voltage decreases below the lower bound of either Use the table below as a guide to select cables and circuit  
operating range (brown-out), the supply uses stored breakers with appropriate ratings for your operating  
energy to continue functioning briefly. The unit turns off voltage.  
if the voltage does not increase above the threshold  
before the storage circuits are depleted. The time that the  
MSL-6 continues to operate during brown-out depends  
MSL-6 Current Ratings  
on how low the voltage drops and the audio source level  
during this period.  
115 V 230 V 100 V  
14 ARMS 7 ARMS 16 ARMS  
26 ARMS 13 ARMS 30 ARMS  
38 APEAK 18 APEAK 42 APEAK  
Max. Continuous RMS  
Max. Burst RMS  
If the voltage fluctuates within either operating range,  
automatic tap selection stabilizes the internal operating  
voltage. This tap selection is instantaneous and there are  
no audible artifacts. If the voltage increases above the  
upper bound of either range, the power supply turns off  
rapidly, preventing damage to the unit.  
Max. Peak During Burst  
The minimum electrical service amperage required by a  
system of MSL-6s is the sum of their m axim u m  
con tin u ou s RMS current. We recommend allowing an  
additional 30% above the minimum amperage to prevent  
peak voltage drops at the service entry.  
If the MSL-6 shuts down due to either low or high  
voltage, the power supply automatically turns on after  
three seconds if the voltage has returned to either normal  
operating range. If the MSL-6 does not turn back on after  
ten seconds, removeAC power and refer to the TROUBLE-  
SHOOTING NOTE above.  
TROUBLESHOOTING NOTE: In the unlikely case that  
the circuit breakers trip (the white center buttons pop  
out), do not reset the breakers! Contact Meyer Sound for  
repair information.  
NOTE: We recommend that the supply be operated at  
least a few volts away from either window’s upper and  
lower bounds so that small AC voltage variations do not  
cause the supply to cycle on and off.  
Power Connector Wiring Conventions  
Current Requirements  
Use the following AC cable wiring diagram to create  
international or special-purpose power connectors:  
The MSL-6 presents a dynamic load to the AC mains  
which causes the amount of current to fluctuate between  
quiet and loud operating levels. Since different types of  
cables and circuit breakers heat up at varying rates, it is  
essential to understand the types of current ratings  
and how they correspond to circuit breaker and cable  
specifications.  
brown = hot  
blue =  
neutral  
yellow/green =  
earth ground  
(chassis)  
The maximum continuous RMS current is the maximum  
RMS current in a period of at least 10 seconds. It is used  
to calculate the temperature increase in cables, which is  
used to select cables that conform to electrical code  
standards. It is also used to select the rating for slow-  
reacting thermal breakers.  
AC cable color code  
If the colors referred to in the diagram don't correspond to  
the terminals in your plug, use the following guidelines:  
Connect the blue wire to the terminal marked  
with an N or colored black.  
The maximum burst RMS current is the maximum RMS  
current in a period of approximately 1 second. It is used  
to select the rating for most magnetic breakers.  
Connect the brown wire to the terminal marked  
with an L or colored red.  
Connect the green and yellow wire to the terminal  
The maximum instantaneous peak current during burst  
is used to select the rating for fast-reacting magnetic  
breakers and to calculate the peak voltage drop in long  
AC cables according to the formula  
marked with an E (or  
) or colored green (or  
green and yellow).  
Vpkdrop = Ip k x Rtotal cable  
4
 
Safety Issues  
Audio Input  
Pay close attention to these important electrical and  
safety issues.  
The MSL-6 presents a 10 kbalanced input impedance to  
a three-pin XLR connector wired with the following  
convention:  
Pin 1 — 220 kto chassis and earth ground (ESD clamped)  
Use a power cord adapter to drive the MSL-6  
from a standard 3-prong outlet  
(NEMA 5-15R;125 V max).  
Pin 2 — Signal  
Differential Inputs  
Pin 3 — Signal  
Case — Earth (AC) ground and chassis  
Pins 2 and 3 carry the input as a differential signal; their  
polarity can be reversed with the input polarity switch  
on the user panel. If the switch is in the up position,  
pin 2 is hot relative to pin 3, resulting in a positive  
pressure wave when a positive signal is applied to pin 2.  
Use standard audio cables with XLR connectors for  
balanced signal sources.  
earth  
ground  
chassis  
ground  
The MSL-6 requires a grounded outlet. Always  
use a grounding adapter when connecting to  
ungrounded outlets.  
TROUBLESHOOTINGNOTE:Shortinganinputconnector  
pin to the case can form a ground loop and cause hum.  
If other abnormal noises (hiss, popping) are produced  
from the loudspeaker, disconnect the audio source from  
the speaker. If the noise stops, then the problem is not  
within the loudspeaker; check the audio input and AC  
power.  
A single source can drive multiple MSL-6s with a paral-  
leled input loop, creating an unbuffered hardwired loop  
connection. Make certain that the source device can  
drive the total load impedance presented by the paral-  
leled input circuit. For example, since the input imped-  
ance of a single MSL-6 is 10 k, cascading 20 units  
produces a balanced input impedance of 500 . If a 150 Ω  
source is used, the 500 load results in a 2.28 dB loss.  
Do not use a ground-lifting adapter or cut the AC  
cable ground pin.  
Keep all liquids away from the MSL-6 to avoid hazards  
from electrical shock.  
Do not operate the unit if the power cables are frayed or  
broken.  
Tie-wrap anchors on the amplifier chassis provide strain  
relief for the power and signal cables. Insert the plastic  
tie-wraps through the anchors and wrap them around  
the cables.  
5
 
The MSL-6 performs within its acoustical specifications  
and operates at a normal temperature if the limit LEDs  
are on for no longer than two seconds, and off for at least  
one second. If either LED remains on for longer than  
three seconds, that channel is hard limiting with the  
following negative consequences:  
Amplification and Protection  
Circuitry  
The MSL-6 is powered by the Meyer MP-4, a four-  
channel 2480 W amplifier (620 W/ ch) utilizing comple-  
mentary power MOSFET output stages (class AB/ H).  
The following sections discuss the MP-4s limiting circuitry  
and four-fan cooling system.  
Increasing the input level will not increase the  
volume.  
The system distorts due to clipping and nonlinear  
driver operation.  
Unequal limiting between the low and high  
channels alters the frequency response.  
The TruPower™ Limiting System  
The life-span of the drivers is reduced because  
they are subjected to excessive heat.  
Conventional limiters assume that the resistance of a  
speaker remains constant and set the limiting threshold  
by measuring voltage only. This method is inaccurate The TPLLEDs can indicate an imbalance in a configuration  
because the speakers resistance changes in response to of speakers by functioning like a spectrum analyzer. If  
the frequency content of the source material and thermal the speakers in a subwoofer, mid-bass, or mid-hi sub-  
variations in the speakers voice coil and magnet. Con- system begin to limit before reaching the required  
ventional limiters begin limiting prematurely, which operating level for the entire system, then that subsystem  
under-utilizes system headroom and deprives the speaker needs to be supplemented with additional speakers.  
of its full dynamic range.  
NOTE: Although the TPL limiters exhibit smooth sonic  
The TruPower Limiting (TPL) system accounts for varying  
speaker impedance by measuring current, in addition to  
voltage, to compute the actual power dissipation in the  
voice coil. TPL  
characteristics, we do not recommend using them for  
intentional compression effects. Use an outboard  
compressor/limiter to compress a mixed signal.  
improves performance before and during limiting  
by allowing each driver to produce its maximum  
SPL across its entire frequency range;  
VHF Limiting  
At normal operating levels, the outer two horns receive  
a high frequency boost (centered at 11 kHz) to blend with  
the center horn to achieve smooth horizontal coverage.  
At high operating levels, however, this boost can cause  
distortion and premature TPL limiting.  
protects the drivers by controlling the temperature  
of the voice coil;  
eliminates long-term power compression when  
the system is operated at high levels for extended  
periods.  
To preserve headroom and maintain smooth high fre-  
quency response at high operating levels, the channel  
for the outer two horns has a fast-acting VHF (very high  
frequency) limiter that reduces the amplitude of fre-  
quencies around 11 kHz. Increased acoustical HF  
harmonic content generated at high signal levels  
compensates for the effects of the VHF limiter, rendering  
its operation almost imperceptible. VHF limiting is  
indicated by the VHF Limit LED on the user panel; the  
same on/ off cycle discussed for the TPL limiters applies  
to the VHF limiter.  
The true power is monitored for each of the four amplifier  
channels, which are controlled by two limiters. The  
outer two and center high frequency drivers are driven  
by separate amplifier channels but are routed to one  
limiter: the HI Limit LED on the user panel indicates  
TPLactivity for the horns. The two low frequency drivers  
are driven by separate amplifier channels but are routed  
to one limiter: the LO Limit LED indicates TPL activity  
for the low drivers.  
When any channel exceeds the safe continuous power  
level, its limiter engages, affecting both channels equally.  
For example, if the channel for the outer two horns  
exceeds the safe power level, the high limiter engages,  
limiting the center, as well as the outer two horns. The  
high and low limiters function independently and do not  
affect the signal when the LEDs are inactive.  
6
 
Fans and Cooling System  
Rigging  
The MSL-6 uses a forced-air cooling system with four  
fans to prevent the amplifiers from overheating. The fans  
draw air in through ducts on the front of the cabinet,  
over the heatsinks, and out the rear of the cabinet. Since  
dust does not accumulate in the amplifier circuitry, its  
life-span is increased significantly.  
A single MSL-6 weighs 510 lb (282 kg) and has twelve  
pivoting lift rings (six on top, six on bottom), each with  
a maximum working load capacity of 1500 lb (5:1  
safety factor). The rigging hardware is depicted on page  
12 in the Dimensions section.  
The front grill surface acts as an air filter for the cooling  
system and should always be in place during operation.  
Despite the filtering, extensive use or a dusty operating  
environment can allow dust to accumulate along the  
path of the airflow, preventing normal cooling. We  
recommend periodically removing the grill and amplifier  
module and using a vacuum cleaner to clear dust from  
the grill, fans, and heatsinks. Make sure that the air ducts  
are clear and that there is at least six inches clearance  
for exhaust behind the cabinet.  
Rigging load ratings assume a straight tensile pull and  
that the cabinet is in new condition. If these conditions  
are not met, the load ratings can be reduced significantly.  
Load ratings can also be reduced by age, wear, and  
damage. It is important to inspect the rigging hardware  
regularly and replace worn or damaged components  
immediately.  
The cabinet, exposed electronic circuitry, and drivers can  
receive protective treatment that permits safe use in wet  
conditions. Additionally, a rain hood can be fitted to  
shield cables and electronics. Do not install a unit outdoors  
without weather protection!Contact Meyer Sound for more  
information.  
amplifier  
NOTE: All Meyer Sound products must be used in  
accordance with local, state, federal, and industry regu-  
lations. It is the owner’s and/or user’s responsibility to  
evaluate the reliability of any rigging method for their  
application. Rigging should be done only by experienced  
professionals.  
heatsinks  
fans  
air  
intake  
Two variable-speed primary fans run continuously with  
an inaudible operating noise of 22 dBA at 1 m at their  
slowest speed. The primary fans begin increasing speed  
when either of the two heatsinks reaches 42°C. The fans  
reach full speed at 62°C and are barely audible near the  
cabinet, even without an audio signal.  
In the unusual event that the heatsink temperature  
reaches 74°C, the secondary fans turn on and are clearly  
audible. The secondary fans turn on in response to  
primary fan failure (check status immediately);  
high source levels for a prolonged period in hot  
temperatures or direct sunlight;  
accumulation of dust along the cooling path;  
driver failure.  
The secondary fans turn off when the temperature  
decreases to 68°C.  
TROUBLESHOOTING NOTE:In the highly unlikely event  
that the secondary fans do not keep the temperature  
below 85°C, the MSL-6 automatically shuts down until  
AC power is removed and reapplied. If the MSL-6 shuts  
down again after cooling and reapplying AC power,  
contact Meyer Sound for repair information.  
7
 
Measurement and System Complete Systems  
Integration  
Meyer Speaker Types  
Measurement and correction tools are required to  
The following Meyer speakers are mentioned in the  
example applications.  
assemble a complete sound system, particularly when  
the venue requires precise array design, delay systems,  
or compensation for significant reverberation. We  
recommend using the Meyer SIM® System II Sound  
Analyzer and CP-10 Parametric Equalizer to  
MSL-4 Self-powered mid-hi speaker  
DS-2P Self-powered mid-bass speaker  
PSW-2 Self-powered subwoofer  
assist the process of choosing and configuring  
speakers;  
650-P  
Self-powered subwoofer  
The Meyer self-powered speakers listed above have a  
loop connection to send the input signal to another  
speaker. Full-range signals can be applied to all Meyer  
self-powered subwoofers because they have built-in  
active crossovers that filter mid-hi frequencies.  
measure propagation delays between subsystems  
to set the correct polarity and delay times;  
measure and equalize variations in frequency  
response caused by the acoustical environment  
and the placement and interaction of speakers.  
We recommend using the Meyer LD-1A Line Driver to  
integrate different types of Meyer self-powered speakers  
into a complete system. The LD-1A has two channels  
equipped to control a main system and six auxiliary  
channels for down-fill, front-fill, and delay systems.  
The LD-1A maintains signal integrity for long cable  
paths and provides the following useful functions:  
Flown MSL-6 and MSL-4;  
650-P on the Floor  
This example shows a large concert system controlled by  
the LD-1A consisting of two rows of two MSL-6s (lower  
row at 10° to the top row), one row of two MSL-4s with  
a 30° horizontal splay angle (hung below lower MSL-6 at  
20°), and 650-Ps on the floor. The diagram on the next  
page displays connections for half of a complete system;  
channels 2, 4, and 6 can be used with identical connections  
to create the other half.  
The Lo Cut switch activates a high-pass filter  
(160 Hz, –12 dB/ oct, Q = 0.8) that performs a  
crossover function for the Mid-Hi output.  
The Array EQ switch activates a filter (6 dB cut  
at 220 Hz, 0.6 octave bandwidth) to equalize  
horizontal arrays of 3 to 5 MSL-4s.  
The CH 1 Mid-Hi and CH 3 outputs drive the upper and  
lower MSL-6 arrays, respectively. Since the coverage  
areas of the upper and lower MSL-6 arrays intersect to  
some degree, CH 3 is delayed to phase align the upper  
and lower systems. The Lo Cut switches for the CH 1  
Mid-Hi and CH 3 outputs should be in. The number of  
MSL-6s for each row depends on the horizontal coverage  
required by the system; each tight-packed unit adds  
30°. Refer to the MSL-4 and 650-P Operating Instructions  
to design arrays for those speakers.  
The DS-2 & Sub Crossover switch (channels 1 and  
2 only) activates a crossover network optimized  
for the DS-2P when used with the 650-P. With the  
switch in, frequencies below 80 Hz are sent to the  
Sub output (for the 650-P), and above 80 Hz to the  
DS-2 output. When the 650-P is used without the  
DS-2P, the switch should be out, which sends a  
full-range signal to both the DS-2 and Sub outputs.  
The DS-2 φ and Sub φ switches (channels 1 and 2  
only) toggle the polarity for the DS-2 and Sub  
outputs.  
The Mid-Hi, DS-2, and Sub outputs (channels 1  
and 2 only) each have their own gain control and  
mute switch.  
POLARITY NOTE: The polarity for Meyer self-powered  
speakers may be reversed using the input polarity switch  
on the user panel. The LD-1A also allows polarity reversal  
with the DS-2 φ and Sub φ switches for speakers  
connected to the DS-2 and Sub outputs. When making  
polarity decisions in applications that include the LD-1A,  
check the state of all polarity switches.  
8
 
LD-1A  
CH 1  
LD-1A  
CH 1  
Ch A  
CP-10 EQ  
Ch B  
Input  
Mid-Hi  
Output  
MSL-6 Upper  
MSL-6 Lower  
DS-2  
MSL-6 Upper  
MSL-6 Lower  
Ch A  
CP-10 EQ  
Ch B  
Input  
Mid-Hi  
Output  
Output  
A
B
Sub  
Delay  
Output  
A
B
Sub  
Output  
Input  
Output  
Delay  
CH 3  
Input  
Output  
Input  
Output  
CP-10 EQ  
CH 3  
CH 5  
Input  
Output  
CP-10 EQ  
CH 5  
MSL-4 Down-fills  
650-P Subwoofers  
DS-2P  
MSL-4 Down-fills  
650-P Subwoofers  
CH 5 controls the MSL-4 down-fill system. Since the  
main system is more powerful than the down-fill system  
to project farther into the venue, the main system is  
audible in the down-fills coverage area. To insure that  
the systems combine properly in this area:  
The connections for this system are the same as the  
previous example except that the CH1 DS-2 output  
drives the DS-2P system with the DS-2 & Sub Crossover  
switch in. The lower MSL-6 system should be delayed to  
align with the upper MSL-6 system in the area in which  
their coverage overlaps. The MSL-4 should also be de-  
layed to align with the lower MSL-6 system.  
Set the MSL-4 to the same polarity as the MSL-6 to  
phase align the mid-hi frequencies.  
Use the CH 5Array EQ filter to minimize the low-  
mid rise caused by the MSL-4 array.  
Delay the down-fill to align it with the lower  
MSL-6 system in their intersecting coverage area.  
Refer to the Operating Instructions for the MSL-4, 650-P,  
and DS-2P (or PSW-2) to design arrays for those speakers.  
The polarity for the 650-P depends on the height and  
distance of the measurement position from the flown and  
subwoofer systems. The entire system should be measured,  
phase-aligned, and equalized using the SIM System II  
Sound Analyzer and CP-10 Parametric Equalizer.  
The MSL-6, MSL-4, and DS-2P systems should be set to  
the same polarity. The polarity for the 650-P depends on  
the height and distance of the measurement position  
from the flown and subwoofer systems.  
The entire system should be measured, phase-aligned,  
and equalized using the SIM System II Sound Analyzer  
and CP-10 Parametric Equalizer.  
Flown MSL-6, DS-2P, and MSL-4;  
650-P on the Floor  
The system from the previous example can be supple-  
mented with a row of four DS-2Ps (or PSW-2s), sus-  
pended below the lower MSL-6 array, to reinforce the  
low frequencies. The MSL-4s are hung below the DS-2Ps  
at 20°.  
9
 
3
Use a / 16” hex wrench to remove the nuts that mount  
Driver Troubleshooting  
the low driver. Support the driver as the last nut is  
removed to prevent it from falling. Twist the driver  
sideways and up/ down to remove it from the back of  
the cabinet.  
The Remote Monitoring System (RMS)is the best method  
to query the status of the drivers in a system before and  
during the performance. RMS monitors peak power,  
peak voltage, and average voltage (VU) for each amplifier  
channel, allowing immediate detection and muting for  
drivers with open or shorted voice coils, with minimal  
disruption to the system. Contact Meyer Sound for more  
information about RMS.  
Verifying Polarity  
Incorrect driver polarity impairs system performance  
and may damage the drivers. All Meyer Sound loud-  
speakers are shipped with the drivers in correct align-  
ment. However, if the driver or circuit wiring has been  
removed or disassembled in any loudspeaker in a system  
for any reason, check the polarity between adjacent  
loudspeakers and between drivers in the same cabinet.  
In the absence of RMS, several methods can be employed  
to obtain information about the state of the drivers.  
We recommend that SIM System II be used to check  
polarity but a real-time frequency analyzer with one-  
third octave resolution is adequate.  
Driver Troubleshooting with TPL  
The TPL LEDs can indicate serious driver problems, if  
interpreted correctly. If one MSL-6 in a system exhibits  
substantially more TPL activity than others receiving  
the same audio signal, then one of the drivers corre-  
sponding to the excessively active LED may have a short  
circuit. This is a potentially dangerous condition for the  
electronics; shut the MSL-6 down immediately.  
!
Since polarity reversal causes excessive driver  
excursion at high source levels, use moderate levels  
when conducting these tests.  
Driver Polarity in the Same Loudspeaker  
The TPL circuit does not activate if there is no power  
dissipation in the driver, regardless of the input signal  
level. Therefore, if all MSL-6s in a system receiving the  
same audio signal exhibit TPL activity except one, then  
that unit may have an open voice coil; disconnect it and  
contact Meyer Sound for repair information.  
Use the following test procedure to verify polarity be-  
tween high frequency horn drivers:  
1. Place a monitoring microphone 5 ft from the grill  
frame, 8.5” below the top ofthe speaker, at the mid-  
point of the center horn (center-line of cabinet).  
2. Connect a signal source to the loudspeaker and  
note the frequency response.  
Removal, Inspection, and Replacement  
The polarity of the high drivers is correct if the fre-  
quency response is ±3 dB 1 – 4 kHz. Polarity reversal for  
the center or outer horns is indicated by 12 – 15 dB  
cancellation in the same region. Check the wiring to the  
high frequency drivers and to the MP-4 and correct the  
problem.  
To determine whether a low or high frequency driver is  
functioning properly, or replace a damaged driver, contact  
Meyer Sound to obtain the Low Driver Inspection and  
Evaluation Procedure for Self-Powered Series Products  
(part # 17.010.120.01) or the High Driver Inspection  
and Evaluation Procedure for Self-Powered Series  
Products (part # 17.010.120.02). These documents are  
accurate for inspection and verification but have yet to  
be updated for the different driver removal procedure  
for the MSL-6.  
Use the following test to verify polarity between low  
frequency drivers:  
1. Place a monitoring microphone 5 ft from the grill  
frame, 28” below the top of the cabinet, at the mid-  
point between low drivers (center-line of cabinet).  
The MSL-6 has two rear hatch covers that must be re-  
moved to access the high and low drivers. Remove the  
screws for either hatch with a Phillips screwdriver. The  
hatch is sealed with a rubber gasket so it must be pulled  
off with moderate force.  
2. Connect a signal source to the loudspeaker and  
note the frequency response.  
The polarity of the low drivers is correct if the frequency  
response is ±3 dB 125 – 500 Hz. Polarity reversal for one  
of the low drivers is indicated by 12 – 15 dB cancellation  
in the same region. Check the wiring to the low drivers  
and to the MP-4 and correct the problem.  
7
Use a / 16” open-end wrench to remove the nuts that  
secure the high driver to the horn. Hold the driver as the  
final nut is removed to prevent it from falling. Twist the  
driver sideways and up/ down to remove it from the  
back of the cabinet.  
10  
 
Use the following test to verify polarity between high  
and low frequency drivers:  
1. Place a monitoring microphone 5 ft from the grill  
frame, 24” below the top of the cabinet, at the mid-  
point between low drivers (center-line of cabinet).  
2. Connect a signal source to the loudspeaker and  
note the frequency response.  
The polarity is correct if the frequency response is  
±3 d B 500 Hz – 1 kHz. Polarity reversal is indicated by a  
6 – 12 dB cancellation in the same range.  
Polarity Between Adjacent Loudspeakers  
Use the following test procedure to verify the polarity  
between adjacent MSL-6 loudspeakers:  
1. Position two loudspeakers adjacent to each other.  
2. Place a measurement microphone six ft from the  
speakers on the axis between them.  
3. Connect a signal source to one speaker and note the  
frequency response and overall level.  
4. Apply the same signal to the second speaker with  
the first speaker still connected.  
The polarity is correct if the frequency response remains  
constant with a significant increase in amplitude. Broad-  
band cancellation (decreased overall level) indicates  
polarity reversal.  
Phase Poppers  
We do not recommend using phase poppers to analyze  
driver polarity. The phase response for all drivers varies,  
to some degree, over the frequency range in which it  
operates. Since phase poppers do not discern variations  
in phase with respect to frequency, they do not provide  
accurate information about the phase response through  
the crossover.  
Phase poppers are, therefore, not useful for performing  
phase measurements on individual loudspeakers or full-  
range sound systems containing one or more crossovers.  
If necessary, apply a phase popper only to loudspeakers  
with identical drivers without a crossover, and check  
the overall system phase response with a frequency  
analyzer and/ or listening test.  
11  
 
Dimensions  
All units in inches  
26.9  
14.0  
3.1  
12.5  
24.2  
0.5  
C.G.  
30.4  
29.4 Ref  
C.G.  
42.8  
22.0  
1.6  
7.4  
32.2  
12.5  
42.5  
32.3  
Top  
Front  
Side  
(Rigging Typ, both ends)  
Physical Construction  
Upper & Lower  
Braces ⁄16" Steel,  
Pivoting Lift Ring  
3
1500 lb. Load Capacity,  
5:1 Safety Factor  
(12 places)  
ASTM A36  
3
⁄8"-16 Reinforcement  
Rods, B7 Alloy Steel  
High-Frequency  
Horn Section  
Fluid-Cooled High  
Frequency Driver,  
4-inch Diaphragm  
(2-inch Throat)  
5
⁄8" Plywood Sides  
3
⁄16" inch ASTM A36  
Flare-Adjusting  
Foam Bullet  
Steel Support Channel  
Fluid-Cooled Back-  
Vented 12-inch Cone  
Low-Frequency Driver  
Low-Frequency  
Horn Section  
11 Ga. Steel  
Side Braces  
Low-Frequency  
Vent  
Resonance-  
Damping Foam  
3
⁄8" Plywood  
Top & Bottom  
Bracing Fastened With  
3
⁄8"-16 Grade B Steel  
Flathead Socket Screws  
(32 Total)  
12  
 
!
Safety Summary  
English  
Français  
To reduce the risk of electric shock, disconnect the loud-  
speaker from the AC mains before installing audio cable.  
Reconnect the power cord only after making all signal  
connections.  
Pour réduire le risque délectrocution, débrancher la  
prise principale de lhaut-parleur, avant dinstaller le  
câble dinterface allant à laudio. Ne rebrancher le bloc  
dalimentation quaprès avoir effectué toutes les connections.  
Connect the loudspeaker to a two-pole, three wire grounding  
mains receptacle. The receptacle must be connected to a  
fuse or circuit breaker. Connection to any other type of  
receptacle poses a shock hazard and may violate local  
electrical codes.  
Branchez lhaut-parleur dans une prise de courant à 3  
dérivations (deux pôles et la terre). Cette prise doit être  
munie dune protection adéquate (fusible ou coupe-circuit).  
Le branchement dans tout autre genre de prise pourrait  
entraîner un risque délectrocution et peut constituer une  
infraction à la réglementation locale concernant les  
installations électriques.  
Do not install the loudspeaker in wet or humid locations  
without using weather protection equipment from Meyer  
Sound.  
Ne pas installer lhaut-parleur dans un endroit où il y a de  
l’eau ou une humidité excessive.  
Do not allow water or any foreign object to get inside the  
loudspeaker. Do not put objects containing liquid on, or  
near, the unit.  
Ne pas laisser de leau ou tout objet pénétrer dans lhaut-  
parleur. Ne pas placer de r´cipients contenant un liquide  
sur cet appareil, ni à proximité de celui-ci.  
To reduce the risk of overheating the loudspeaker, avoid  
exposing it to direct sunlight. Do not install the unit near  
heat emitting appliances, such as a room heater or stove.  
Pour éviter une surchauffe de lhaut-parleur, conserver-la  
à l’abri du soleil. Ne pas installer à proximité dappareils  
dégageant de la chaleur tels que radiateurs ou appareils  
de chauffage.  
This loudspeaker contains potentially hazardous voltages.  
Do not attempt to disassemble the unit. The unit contains  
no user serviceable parts. Repairs should be performed  
only by factory trained service personnel.  
Ce haut-parleur contient des circuits haute tension  
présentant un danger. Ne jamais essayer de le démonter.  
Il ny a aucun composant qui puisse être réparé par  
l’utilisateur.Toutes les réparations doivent être effectuées  
par du personnel qualifié et agréé par le constructeur.  
Deutsch  
Español  
Um die Gefahr eines elektrischen Schlages auf ein Mini-  
mum zu reduzieren, den Lautsprecher vom Stromnetz  
trennen, bevor ggf. ein Audio-Schnittstellensignalkabel  
angeschlossen wird. Das Netzkabel erst nach Herstellung  
aller Signalverbindungen wieder einstecken.  
Para reducir el riesgo de descarga eléctrica, desconecte de  
la red el altoparlante antes de instalar el cable de  
señalización de interfaz de la segnale. Vuelva a conectar el  
conductor flexible de alimentación solamente una vez  
efectuadas todas las interconexiones de señalizatción.  
Der Lautsprecher an einegeerdetezweipoligeDreiphasen-  
Netzsteckdose anschließen.Die Steckdose muß mit einem  
Conecte elaltoparlante a un tomacorriente bipolar y trifilar  
con neutro de puesta a tierra. El tomacorriente debe estar  
conectado a la protección de derivación apropiada (ya sea  
un fusible o un disyuntor). La conexión a cualquier otro  
tipo de tomacorriente puede constituir peligro de descarga  
eléctrica y violar los códigos eléctricos locales.  
geeigneten  
Abzw eigschu tz (Sicheru ng od er  
Leistungsschalter) verbunden sein. Der Anschluß der  
unterbrechungsfreien Stromversorgung an einen anderen  
Steckdosentyp kann zu Stromschlägen führen und gegen  
die örtlichen Vorschriften verstoßen.  
No instale el altoparlante en lugares donde haya agua o  
humedad excesiva.  
Der Lautsprecher nicht an einem Ort aufstellen, an dem  
sie mit Wasser oder übermäßig hoher Luftfeuchtigkeit in  
Berührung kommen könnte.  
No deje que en el altoparlante entre agua ni ningún objeto  
extraño. No ponga objetos con líquidos encima de la  
unidad ni cerca de ella.  
Darauf achten, daß weder Wasser noch Fremdkörper in  
das Innere den Lautsprecher eindringen. Keine Objekte,  
d ie Flü ssigkeit enthalten, au f od er neben d ie  
unterbrechungsfreie Stromversorgung stellen.  
Para reducir el riesgo de sobrecalentamiento, no exponga  
la unidad a los rayos directos del sol ni la instale cerca de  
artefactos que emiten calor, como estufas o cocinas.  
Um ein Überhitzen dem Lautsprecher zu verhindern, das  
Gerät vor direkter Sonneneinstrahlung fernhalten und  
nicht in d er N ähe von w ärm eabstrahlend en  
Haushaltsgeräten (z.B. Heizgerät oder Herd) aufstellen.  
Este altoparlante contiene niveles de voltaje peligrosos en  
potencia.No intente desarmar la unidad,pues no contiene  
piezas que puedan ser repardas por el usuario. Las  
reparaciones deben efectuarse únicamente por parte del  
personal de mantenimiento capacitado en la fábrica.  
Im Inneren diesem Lautsprecher herrschen potentiell  
gefährliche Spannungen. Nicht versuchen, das Gerät zu  
öffnen.Es enthält keine vom Benutzer reparierbaren Teile.  
Rep aratu ren d ü rfen nu r von au sgebild etem  
Kundenienstpersonal durchgeführt werden.  
13  
 
Controls and Connectors  
!
WARNINGS:  
THIS PRODUCT MUST BE GROUNDED  
This surface may reach high temperatures while in use.  
To ensure proper operation, allow at least 6 inches  
clearance from this surface and adequate ventilation.  
To reduce the risk of electric shock do not remove cover.  
No operator serviceable parts inside.  
Mains AC inlet  
Mains circuit  
breakers  
Refer servicing to qualified personnel.  
To reduce the risk of fire or electric shock  
Tie-wrap anchor  
do not expose this appliance to rain or moisture.  
ATENCIÓN  
:
ACCESO INTERNO SOLO  
MSL-6  
VHF Limit  
HI Limit  
AUTORIZADO  
A
PERSONAL TÉCNICO CALIFICADO  
High Limit (red)  
Low Limit (red)  
ACHTUNG  
:
GEHÄUSE NICHT ÖFFNEN WARTUNG  
UND REPARATUR NUR DURCH ELEKTROFACHKRÄFTE  
ATTENTION ENTRETIEN ET REPARATIONS  
INTERNES NE SONT AUTORISEES QU'AU  
PERSONNEL TECHNIQUE QUALIFIÉ  
:
LO Limit  
Active  
/
Speaker Fault  
UK WARNING: THIS APPARATUS MUST BE EARTHED.  
NO OPERATOR SERVICEABLE PARTS INSIDE.  
REFER SERVICING TO QUALIFIED PERSONNEL  
Input Polarity  
PUSH  
Power LED (green/red)  
Input polarity switch  
2 +  
3 +  
10K  
Balanced  
Auto-Voltage Select  
95-125V  
50-60Hz  
~
208-235V~  
50-60Hz  
1400W RMS MAX 1400W RMS MAX  
1
ESD  
220K  
Case  
2
2
1
1
3
3
Earth / Chassis  
Signal input and  
loop connectors  
Network  
Input  
Loop  
Remote Monitoring  
System panel  
Meyer Sound, Berkeley, CA. USA  
Remote Monitoring System  
(if RMS is installed)  
Rear User Panel shown with the optional  
Remote Monitoring System (RMS) panel  
!
WARNINGS
THIS PROD
This surface may
To ensure proper w  
clearance from thia  
To reduce the risk o
No operator services  
Refer servicing to qo  
To reduce the risk o
do not expose this a
ATENCIÓN: ACCR  
AUTORIZADO  
A
PE
ACHTUNG: GEHÄ
UND REPARATUR N
ATTENTION: ENT
INTERNES NE SONT AU  
PERSONNEL TECHNIA  
UK WARNING: TH
NO OPERATOR SERVIC
REFER SERVICING TO Q
H  
Auto-Voltag
10A RMS  
20A Peak  
88-127V  
50-60Hz  
~
700W RMS M
Operational e  
Turn on 80V
Turn on 160V
2
1
1
3
3
Network  
Input  
Loop  
Remote Monitor System  
Meyer Sound, e  
European Rear User Panel  
with IEC 309 connector  
Contact Information  
Meyer Sound Germany  
Gmbh  
Carl Zeiss Strasse 13  
56751 Polch, Germany  
Meyer Sound Laboratories, Inc.  
2832 San Pablo Avenue  
Berkeley, California 94702  
Telephone:510 - 486 - 1166  
Telephone: 49.2654.9600.58  
FAX: 49.2654.9600.59  
FAX:  
510 - 486 - 8356  
14  
 

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