Electro Voice Speaker EVI 12 User Manual

EVI-12, EVI-15 and EVI-28  
Loudspeaker Systems  
Applications Guide  
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Welcome to the world of Vari Intense® horn  
technology from Electro-Voice. This Applications  
Guide is not intended as a “very intense” descrip-  
tion of installation procedures, but more as a partial  
description of applications and a discussion with  
the designer to help you understand this revolution-  
ary technology and use the Electro-Voice Vari In-  
tense® systems to install better-sounding systems  
and significantly reduce time and material costs.  
In a nutshell, here are the major advantages of  
the new EVI systems:  
• Rectangular coverage pattern.  
Traditional horns deliver an elliptical pattern  
to the floor. VI horns deliver a rectangular  
pattern, which helps to fill in the corners of  
the room. No more costly delay lines or cheap  
seats!!  
• Even SPL front-to-back.  
The unique, patented throat and flare struc-  
ture of the VI horn delivers a 6-10 dB hotter  
signal to the rear of the room, eliminating ear-  
strain at the back of the seating area and pain-  
ful ears at the front.  
• Greater Intelligibility.  
VI horns deliver sound to fill only the  
floorplan, providing uniform direct-field SPL  
and an order of magnitude less energy into  
the reverberant field. This provides an increase  
in mid- to high-frequency intelligibility of 6 dB  
in most applications.  
• One horn replaces two.  
With VI technology we’ve eliminated the de-  
structive interference which occurs between  
long- and short-throw horns. We’ve also elimi-  
nated the cost of a properly designed two-horn  
system which must include another power am-  
plifier channel for good power control and  
impedance matching.  
• Labor savings in the box.  
With structural rigging from the factory, these  
systems will fly more conveniently and in less  
time than many competitive products. In addi-  
tion, less time is spent on the aiming and repo-  
sitioning that is required with traditional long-  
throw/short-throw horn combinations. This  
will save you additional money.  
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Installation procedures for any conventional angled woofer. Note: the 12-in. driver in the EVI-  
loudspeaker are fairly well-defined and easy to un- 12 is at a different angle than the 15-in. driver in the  
derstand: find an appropriate hanging height and  
EVI-15, optimizing the floor pattern with the differ-  
position that affords a clear path to the listening area ing directivities of the two drivers. In the EVI-28,  
(such as above the center of a stage or above the the VI horn is crossed over to a pair of vertically-  
lectern in a church), and aim the loudspeaker to- arrayed 8-inch woofers with a proprietary technique  
wards the center or just to the rear of center of the that provides delay, amplitude and frequency shad-  
room. With this method you hope to cover the  
majority of the room with fairly consistent sound,  
but the mid and high frequencies never seem to fill  
perfectly. It is frequently aimed a little too far back  
and there is a large amount of slap echo, or the  
front row is too loud, the back row too soft and the  
front and back row corners sound muted due to a  
lack of high-frequency energy. Other solutions to  
filling the room have been suggested and imple-  
mented, including a dual-horn format (one long  
ing to the two woofers.  
The EVI-12, EVI-15 and EVI-28 systems are  
installed just like any conventional loudspeaker,  
keeping in mind a few simple guidelines. Let me  
preface these guidelines with a simple but impor-  
tant comment: the VI systems are extremely versa-  
tile and will work in a large variety of applications.  
They will work well with tall ceilings, short ceilings,  
rectangular rooms, slightly trapezoidal rooms and a  
whole host of odd shapes so long as the coverage  
throw and one short throw). This method works area is fairly close to rectangular. The larger  
fairly well, but encounters several problems: the EVI-12 and EVI-15 have been tested in rooms with  
added expense of another horn/driver combination; 12-foot ceilings and performed very well, although  
the vastly increased time to physically install and with reduced width of throw. A single EVI-12  
then tune the level and aiming of two horns; the in- was installed in a room 75-foot by 150-foot and an  
evitable destructive interference patterns through-  
average RT60 of 4.5 in the mid band and performed  
out the listening area; the expense of another ampli- very well with good intelligibility and a minimum of  
fier channel to achieve correct impedance match-  
ing; and the need for a very aesthetically clean in-  
slap echo. It has been thought in the past that if the  
floor pattern does not fit the VI horn exactly, then it  
stallation, with no odd-looking (to the customer) cannot be used at all. This is not the case, and if it  
dangling horns. Another solution is to have a horn were the case, we could not use standard constant-  
that is variable angle, in order to throw a narrow directivity horns in most applications either. The  
pattern to the back of the room. The problem with  
this concept is that this doesn’t take into account  
the drop in SPL between the near throw (about 25  
larger VI systems have an “optimum” room that is  
approximately twice the height in width and three  
times the height in length. This is the ideal condi-  
feet) and the far throw (about 70 feet), so the high tion, but the figures and descriptions that follow  
frequenciesareabout10dB down in the back of the  
room. To solve all of these problems, the Vari In-  
tense® horns were invented, yet another innovation  
inthelongtraditionofElectro-Voice. When properly  
aimed, theVariIntense® hornscanprovideextremely  
even SPL throughout an entire room, filling in the  
corners without pushing too much energy at the  
back wall, thus avoiding slap echo. The rules of  
fixed installation have just changed...  
should give you a good feel for the wide-range ca-  
pabilities of the systems.  
EVI-12 and EVI-15 Installation:  
The nominal floorplan that the system will  
cover with equal SPL is approximately two “units”  
wide by three “units” long, where the height of the  
loudspeaker defines the size of the “unit.” For ex-  
ample, iftheloudspeakeris18 feet above the floor, it  
The Electro-Voice EVI-12, EVI-15 and will typically cover a floorplan of about 36 feet wide  
EVI-28 enclosures are the first in a new generation by 54 feet long. In this typical installation (see Fig-  
of problem-solving systems. The new systems are ure 1), the back panel of the loudspeaker is mounted  
designed as a package, with easy mounting, refin- approximately 0.6 units (about 11 feet) back from  
ishing ability, lightweight, compact and unobtrusive the first row and has a nominal angle of the top of  
size and shape and the classic musical sound that the enclosure parallel to the floor or slightly tilted  
Electro-Voice is known for. The new small-format back (2 to 3 degrees). For rooms that are much  
VI horn maintains consistent directional control  
longer than normal, the VI systems are very easy to  
down to 2,000 Hz. In the EVI-12 and EVI-15 the aim and position to fill the entire length. Experi-  
VI horn is optimally crossed over to an specially mentsinactuallisteningroomshaveshownthatwith  
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the same mounting height of 18 feet, but with the  
front of the enclosure tilted up by approximately  
10° (see Figure 2), the total floorplan now encom-  
passed the same 36 foot width, but at least 64 feet  
in length, an additional 10+ feet of extension. Of  
course, the front row position has moved back  
about 5 feet with the change in angle as shown, but  
this is easy to account for when initially positioning  
the system (and is exactly what happens if you take  
a conventional system and change the angle). For  
rooms that are closer to square, tilting the loud-  
speaker system down by 15° provides a very clean  
and horns closer together than possible with me-  
dium-format horns will produce somewhat better  
results, but will always result in fairly severe lobing.  
Polar measurements in 2° increments show the  
lobing very well, but the smoothingrequiredfortrans-  
lationtotheEASE10° resolution database will elimi-  
nate the vast majority of peaks and dips, resulting  
in what appears to be a fairly smooth simulation. In  
contrast, the new VI systems have no problems with  
interference, and maintain very good tonality even  
far to the sides and to the back, outside the “equal-  
SPL” pattern area. This effect is due to the precise  
square pattern. In this case, the offset to the first matching of directivities in the midrange and treble,  
row is about 0.25 times the height of the system. giving a consistent (although noticeably quieter) fre-  
For example, a tall, square room is about 60 feet quency response out to nearly 50 feet in width and  
wide, and only 65 feet long. Tilting the enclosure  
down by 15° at a 30 foot mounting height makes a and 0° aiming angle. This has the advantage of pro-  
60 foot wide by 60 foot long pattern. The offset to viding a much more uniform power response into  
the first row is 0.25 multiplied by the 30 foot height, the reverberant field, ensuring that the inevitable  
or about 7.5 feet forward from the back of the en- reflections (minimized bythe VI concept) are con-  
65–70 feet in length from the same 18-foot height  
closure. Minor adjustments in aiming will make the sistentintonalquality.  
SPL fill the room very evenly with no loss in tonality  
in the corners and high overall intelligibility.  
EVI-28 Installation:  
The EVI-28 makes use of the same high-fre-  
quency horn as the EVI-12 and EVI-15, but in-  
cludesapairofhigh-power, high-efficiency8woof-  
By contrast, a typical two-way system with a  
60° x 40° CD horninthe same mountinglocationas  
Figures 1 and 2(see Figure 3) produced a floor plan  
that sounded tonally fairly consistent with a 20- to ers in a very compact package. The system is pro-  
24-foot width and 30-foot depth with an offset of vided with a 2,000-Hz passive crossover featuring  
nine feet to the front row. On paper, this seems like tweeter protection and a proprietary passive equal-  
adequate performance, but in the room it has very ization circuit that provides frequency-shading, am-  
noticeable (6 dB or greater) variation in overall level  
from side to center, and in some aiming cases over  
10 dB of variation from front to back as well as a  
pronounced lemon shape. The sides of the first  
three to five rows in a church and the last few rows  
were noticeably muted and much lower in overall  
level. As mentioned before, a two-horn system can  
work fairly well, but the physical offsets required  
for installation inevitably result in some amount of  
destructive interference throughout the room  
(see Figure 4). Figure 4 was produced using a  
90° x 40° CD horn aimed down by 65° and a  
60° x 40° horn aimed down by 30°. The actual  
physical offsets were used to simulate the floor  
response in direct-field SPL. The displayed figure  
agrees very well with the measured response, show-  
ing a 14-dB variation at 4kHz in a distance of 3 feet  
horizontally. Tonal changes as a result of interfer-  
ence pattern change versus frequency were clearly  
audible in an acoustically well-behaved room, but  
were overall much less audible than for a single sys-  
tem with a conventional CD horn. Locating drivers  
plitude-shading and time delay to the two woofers.  
An Acoustic Lens Filter on the grille helps to elimi-  
nate spurious lobes and provides a degree of acous-  
tic loading. These features heavily modify the polar  
responseofthetwowoofers, providinganextremely  
uniform polar pattern with a shape that matches the  
VI horn’s unique SPL profile. They also smooth  
the transition between woofers and the horn to mini-  
mize horizontal lobes, providing amazingly even  
coverage through the crossover point. This extends  
theVIcharacteristicdownto500Hzinanextremely  
compact enclosure.  
The high-frequency horn in the EVI-28 is  
mounted tilted 15° back relative to the EVI-12  
and EVI-15. Along with the polar steering in the  
woofer’s crossover, this arranges the dispersion for  
long throws relative to the mounting height. The  
recommended operational vertical angle is minus  
5°from the top surface of the enclosure to minus  
45°, defining a maximum used vertical dispersion  
of 40°. The standard aiming of the system when it  
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is mounted above a flat floor is with the top of the  
enclosure parallel to the floor. In this orientation,  
the system will provide even SPL over a floorplan  
that is approximately twice as wide as the mounting  
height, and five times as long. Tilting the enclosure  
down by approximately 10- to 15° relative to the  
slope of the floor will produce a floorplan the same  
as an EVI-12 or EVI-15. At the standard aiming,  
the 45° nearfield operational angle defines an ap-  
proximate offset to the first useable row of one-half  
the height of the speaker system above the listening  
plane.  
In a typical installation, the top surface of the loud-  
speaker will point slightly above the head height of  
the furthest targeted seating or standing area. This  
will ensure the minimum amount of slap echo from  
the back wall. In an under-balcony situation, the  
sharp cutoff above the zero degree axis prevents  
early ceiling reflections from causing interference  
patterns in the listening area. Since an EVI-28 has  
a very smooth and rapid drop-off towards directly  
below the cabinet, you can actually stand right in  
front of the speaker (see Figure 12) without ear  
strain or heavy microphone feedback. The remark-  
able absence of lobes to the rear allows the system  
to be mounted directly overhead to target a par-  
ticular area without disturbing the audience below  
or behind the cabinet.  
For example, FIGURE 11 shows a typical under-  
balcony application that has a floor with an upward  
slope of 5°. The speaker is mounted 10 feet above  
the seated head height, so the horizontal width is  
fixed at approximately 20 feet. The enclosure is  
tilted back by 5° to provide a 50-foot throw, with  
the outskirts of the pattern filling in the rear aisle  
area with tonally accurate but reduced overall SPL.  
If the under-balcony seating area is only 35 feet  
deep, then the enclosure should be tilted down by  
about 10° relative to the floor in order to prevent  
excess slap echo and preserve intelligibility.  
Figure 12 shows a typical small-room application,  
perfect for a 20-foot by 30-foot boardroom or  
meeting hall. In this case, the head height is actually  
defined by a standing height of approximately 6 feet,  
so the long-throw axis should be very close to hori-  
zontal. Then the included 40 degree angle points  
directlytowardstheentirelisteningarea, minimizing  
slap echo while retaining a full width, high intelligi-  
bility and even SPL throughout the listening area.  
Q vs. Intelligibility:  
The “Q” of a system is a good measure of the  
system’s directivity, and in some ways a good mea-  
sure of whether the system’s in-room response will  
be consistent across the frequency range. A typi-  
cal 12-inch two-way system with a 60o x 40o horn  
will maintain a fairly constant Q from 16-30 or  
12-15 dB (normally about 26, or 14dB) from  
3,000–20,000 Hz, and a 90o x 40o a Q of 13-15  
(11-12dB). Very-high-directivity horns such as a  
40o x 20o will have an average Q in the range of  
45 (16.5 dB), and very-low-directivity horns like a  
120o x 40o will have a Q of 7-9 (8.5-9.5 dB). It is  
generally thought that a high-directivity horn will  
havegreaterintelligibility acrossa givenpatternarea  
than a lower-Q device, and this is true in most cases.  
Also true in most cases is that a standard horn pat-  
tern will not fill a typical floorplan, thus drastically  
reducing the effectiveness of the higher Q. In direct  
comparison, the VI horn pattern will fill a majority  
of floorplans with direct-field sound rather than re-  
lying on reverberant energy to “fill in the gaps” in  
overall sound quality and quantity. The Q of the VI  
systems are very consistent from 1,000–20,000 Hz,  
with a range of 10-18 (10-12.5 dB) and an aver-  
age Q of 13.5 (11.5dB) or consistent with the overall  
directivity of a 90o x 40o system. This might lead  
you to believe that the VI systems are “low-Q” and  
inappropriate for highly reverberant rooms, but the  
plots of the direct-field SPL and its accompanying  
C50 ratio show a significant advantage to the VI  
systemoveraconventional60o x40o system. As we  
all know, high Q only helps when the polar response  
fits into the listening space as closely as possible.  
Please keep this in mind when using Q as a bench-  
mark for system intelligibility. For those unfamiliar  
with the term C50, it is a measure of intelligibility  
defined by the acoustic power in the room in the  
first 50 msec divided by the power from 50 msec  
to infinity, expressed in dB. The minimum recom-  
mendedlevelofintelligibilityis0dB, roughlyequiva-  
lent to 10% Alcons.  
A Note on Simulation Software:  
Data files for AcoustaCADDTM and EASETM  
are available from Electro-Voice’s BBS, by special  
request or on Electro-Voice’s Website (http://  
www.electrovoice.com). The figures have all been  
produced in EASE, but with the current 10° resolu-  
tion of the software, much of the 2° resolution data  
we collect has been lost in the required averaging  
translation to the 10-degree format. The net result  
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is that 3dB of long-throw SPL and 1.5-2dB of side-  
fill level has been lost. A higher resolution data file  
Please note: the pull-up location on the lower  
section of the back panel of the enclosure MUST  
is needed to provide a “real world realistic” simula- be used to hang the system in order to provide a  
tion. Figure 5 shows the raw 2° polar data with safe, stablemountingsystem. Thepull-uppointpro-  
the averaged 10° data superimposed. Also shown vides an additive safety, as it is capable of holding  
are floorplans from our 2° modeler, DCSO, the 5- the speaker system with a safety factor of at least  
degree AcoustaCADD and 10-degree EASE. By 5:1 in the unlikely event of a failure in the main load-  
comparing the 2°, 5° and 10° resolution you can eas- bearing system.  
ily see the apparent loss in direct-field SPL. This  
For the EVI-28, the mounting holes are posi-  
loss shows up as a series of “steps” along the length tioned very near the center of gravity for easy aim-  
of the room and an artificially narrowed throw with ing. The U-brackets may be rotated all the way  
less SPL in the corners than would be achieved in a  
around the back of the enclosure, allowing easy in-  
real-world installation. Please keep this in mind stallation and aiming. The maximum vertical angle  
when using simulation software.  
that may be reached is approximately 35°, less if  
the loudspeaker is mounted flush against a ceiling.  
In this case, the enclosure may be rotated upwards  
by at least 15°, more than sufficient for nearly any  
application (see Figure 15). The brackets are sup-  
plied with friction washers that will prevent the en-  
closure from rotating over time, but to be abso-  
lutely certain, the installer should use a set screw in  
the threaded hole to fix the enclosure permanently  
in position.  
The described hanging methods are rated for  
suspending only one speaker (with a minimum of  
an 8:1 safety factor). Hanging any additional  
weight from the speaker will exceed its strength  
rating and create an unsafe condition.  
Hanging EVI Systems:  
For the EVI-12 and EVI-15 the physical  
mounting of the systems have been designed to be  
as easy as possible, with two simple options avail-  
able. By far, the easiest solution is to use the op-  
tional sturdy, cost effective EVI-12MB or  
EVI-15MB U-Brackets that mount to the 3/8-16  
T-nut locations on the sidesoftheenclosure.Thesup-  
pliedforged-shouldereyeboltmustbeusedinthet-nut  
location on the lower back side of the system as a  
pull-uppoint(seefigure13). With this arrangement,  
the U-Bracket holds approximately 80% of the  
weight of the system, and the pull-up point pro-  
vides a convenient method of adjusting the aiming  
angle. The U-Brackets have easy-to-install bolt  
patterns and include three sets of OmniMount 100  
bolt patterns. For most applications, this will be  
the preferred methodology as it is fast, aesthetically  
pleasing, flexible and inexpensive. However, this  
method will not work in all applications, so we have  
included a second set of T-nut locations on the top  
of the enclosure so that the hanging cables can be  
completely out of view from below (see Figure 14).  
The front pair of hanging points should carry ap-  
proximately 50 lbs of the enclosure’s weight, with  
the required pull-up point taking the balance of  
the weight (about 5 lb). The T-nut locations are  
intended to be used only with forged shoulder  
eyebolts with a minimum tensile strength of 350 kg  
(770lb). The inexpensive EBK-1 kit includes three  
eyebolts, especially helpful when access to quality  
forged shoulder eyebolts is limited. Please keep in  
mind that the center of gravity is designed to be  
behind the main hanging points. This means that  
the back of the system will rotate as much as 50  
degrees down, allowing easy aiming adjustment to  
virtuallyanyangle.  
A Sampling of EVI Applications:  
Now that the technical details are covered,  
here are a few ideas on applications that the EVI  
systems will cover with far more uniform sound and  
lower overall cost than any conventional enclosure.  
The first and most obvious application is in a church  
or some other well-defined space that has a fairly  
tall ceiling, and proportions of roughly 2 x 3 (see  
Figure 1). In this application, the EVI systems can  
easily replace a central cluster or distributed sys-  
tem with a single low-cost enclosure and still main-  
tain a more uniform sound distribution. Figure 2  
shows a similar room, but with a somewhat longer  
throw, where the EVI systems also perform very  
well. Manyauditoriumsandtheatresaremuchwider  
than a typical set of church pews, so Figure 6 shows  
a fairly standard auditorium floor plan and possible  
mounting locations. Any interference between the  
systems will be concentrated in the center aisle,  
where sound quality is not as critical. The EVI-12,  
EVI-15 and EVI-28 systems are also ideal for re-  
placing distributed arrays, providing much more  
uniform coverage at a lower cost. See Figure 7 for  
5
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replace a distributed system along a very long, fairly  
wide corridor where very high SPLs are not  
required on a continuous basis (such as an airport  
concourse with 15 to 20 foot ceilings, where a  
speaker would be placed about every 75 feet). See  
Figure 10 for approximate mounting locations and  
floorplan coverage.  
These are but a few of the widely varied  
applications where the new EVI-12, EVI-15 and  
EVI-28 systems will easily outperform a conven-  
tional system. The extremely uniform coverage of  
the systems are fairly insensitive to placement, re-  
quire only a few simple calculations to find the best  
mounting location, and the aiming angle is no more  
or less sensitive than a conventional loudspeaker.  
This makes installation nearly foolproof. Even  
installation in non-optimal conditions will produce  
remarkably even coverage and high intelligibility.  
an idea on how the same auditorium floor plan could  
be easily covered in a surround-style arrangement  
with just two EVI systems per side rather than four  
distributed arrays. Although not providing the high-  
est intelligibility or smoothest response, it is appli-  
cable to cinemas and some musical preferences.  
This has the advantages of cutting installation time,  
amplifier channels, additional delay lines and at the  
same time providing superior coverage.  
A gymnasium is another perfect application  
for the EVI systems, covering each grandstand from  
a pair of centrally located EVI systems (see Figure  
8). In addition, you can cover the entire gymna-  
sium from either a single lengthwise-oriented sys-  
tem or with a pair of widthwise-spaced systems  
with lower-SPL coverage on the floor of the  
gymnasium than in the stands, so the players are  
not disturbed by announcements (see Figure 9).  
When the EVI-12 and EVI-15 systems are  
tilted up approximately 15°, their coverage pattern  
lengthens to match a level EVI-28 at 5 times the  
height. In such cases the systems work very well to  
As questions arise, you may feel free to con-  
tact us at 800/234-6831, or FAX at 616/695-1304.  
NOTE: All figures are direct-field SPL and C50 produced in EASE with interference turned  
on when applicable. All plots depict the intended listening areas only, and do not include the  
“offset distance” to the first row. For example, the first set of plots on figure 3 depict the same  
54’ x 36’ area as figure 1. See notes on simulation software.  
Figure 1  
EVI SYSTEM MOUNTED  
AT 18’ HEIGHT AND  
0° AIMING ANGLE  
C50  
(TOP PARALLEL TO FLOOR)  
Direct Field SPL  
6
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Figure 2  
EVI SYSTEM MOUNTED  
AT 18’ HEIGHT AND  
+10° AIMING ANGLE  
TILTED BACK  
FROM FLOOR  
Direct Field SPL  
C50  
Figure 3  
CONVENTIONAL 60X40 SYSTEM  
MOUNTED AT 18’ HEIGHT AND  
AIMED ABOUT 30° DOWN  
Direct Field SPL  
C50  
CONVENTIONAL 60X40 SYSTEM  
MOUNTED AT 18’ HEIGHT AND  
AIMED ABOUT 25° DOWN  
C50  
Direct Field SPL  
7
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Direct Field SPL  
Figure 4  
Figure 5  
Horizontal Polar  
Raw  
Smoothed  
AcoustaCADDTM Direct Field SPL  
Vertical Polar  
Raw  
S moothed  
EASETM Direct Field SPL  
DCSO Direct Field SPL  
8
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Figure 6  
EVI SYSTEM MOUNTED  
AT 20’ HEIGHT AND  
8° AIMING ANGLE  
Direct Field SPL  
C50  
9
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Figure 7  
EVI SYSTEM MOUNTED  
AT 18’ HEIGHT AND  
-10° AIMING ANGLE  
EVI SYSTEM MOUNTED  
AT 22’ HEIGHT AND  
-10° AIMING ANGLE  
Direct Field SPL  
C50  
10  
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Figure 8  
EVI SYSTEM MOUNTED  
BACK-TO-BACK  
AT 30’ HEIGHT AND  
+5° AIMING ANGLE  
Direct Field SPL  
C50  
11  
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Figure 9  
EVI SYSTEM MOUNTED  
AT 25’ HEIGHT AND  
15° AIMING ANGLE  
Direct Field SPL  
C50  
12  
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Figure 10  
2 EVI SYSTEM MOUNTED  
BACK-TO-BACK AT 40’ HEIGHT  
AND +10° AIMING ANGLE  
C50  
Direct Field SPL  
13  
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Figure 11  
Figure 12  
Figure 14  
Figure 13  
BOLTS AND CABLING/CHAINS MUST  
BE RATED FOR OVERHEAD LIFTING  
(SEE TEXT)  
BOLTS AND CABLING/CHAINS MUST  
BE RATED FOR OVERHEAD LIFTING  
(NOT SUPPLIED)  
PULL-UP STRAP  
3/8-16 FORGED SHOULDER  
EYEBOLT (SUPPLIED) WITH  
PULL-UPSTRAP  
ATTACHED TO 3/8-16  
FORGED SHOULDER  
EYEBOLT(SEETEXT)  
Figure 15  
600 Cecil Street, Buchanan, MI 49107  
800/234-6831, 616/695-6831, 616/695-1304 Fax  
©Telex Communications, Inc. 1998 • Litho in U.S.A.  
Part Number 534762—9822  
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