Snowmobile Polaris IQ (2007-2008 year). Manual - part 47

7.2

PVT System

PVT SYSTEM

Overview

The Polaris drive system is a centrifugally actuated variable
speed belt drive unit. The drive clutch, driven clutch, and belt
make up the torque converter system. Each clutch comes from
the factory with the proper internal components installed for its
specific engine model. Therefore, modifications or variations of
components at random are never recommended. Proper clutch
setup and adjustments of existing components must be the
primary objective in clutch operation diagnosis.

Drive Spring

The drive spring opposes the shift force generated by the clutch
weights, and determines the neutral RPM, engagement RPM,
and wether the engine RPM remains flat, rises, or falls during
shift out. When changing only the drive spring, installing a
spring with a lower pre-load rate will result in a lower
engagement RPM speed, while installing a spring with a higher
pre-load rate will result in a higher engagement RPM. 

Clutch Weight

The clutch weights generate centrifugal force as the drive clutch
rotates. The force generated changes in relation to the engine
RPM and with specified weight of each clutch weight. When
changing only the clutch weights, a lighter weight will result in
a higher engagement RPM, lower shifting force, and higher shift
out RPM. Installing heavier weights has the opposite effect

Neutral Speed

Engine RPM when the force generated by the clutch weights is
less than the pre-load force generated by the drive spring. In this
mode, the drive clutch is disengaged.

Engagement RPM

Engine RPM when the force generated by the clutch weights
overcomes the drive spring pre-load force and the moveable
sheave begins to close or “pinch” the drive belt. The engagement

mode continues until no more belt slippage occurs in the drive
clutch. Once 100% belt engagement is achieved, the sled will
accelerate along the low ratio line until the drive clutch up shift
force overcomes the opposing shift force generated by the
driven clutch.

Shift Out Over-Rev

Engine RPM that spikes above the desired operating RPM
speed. The shift out RPM should come down to the desired
operating RPM, but never below, after the driven clutch begins
to open.

Shift Out RPM

Engine RPM at which the up shift force generated by the drive
clutch overcomes the shift force within the driven clutch. In this
mode, the drive clutch will move the belt outwards, and the
driven clutch will allow the drive belt to be pulled down into the
sheaves.

During WOT operation, the shift out RPM can be seen as the
maximum, sustained RPM displayed on the tachometer. The
shift out RPM should be the same RPM as the recommended
engine operating RPM. If the shift out RPM is above the
recommended engine operating RPM, install heavier drive
clutch weights. If the shift out RPM is below the recommended
engine operating RPM, install lighter drive clutch weights.

The shift out RPM should remain constant during both the
upshift and back shift modes.

Driven Spring

A compression spring (Team driven clutch) or torsional spring
(Polaris P-85 driven clutch) works in conjunction with the helix,
and controls the shift rate of the driven clutch. The spring must
provide enough side pressure to grip the belt and prevent
slippage during initial acceleration. A higher spring rate will
provide more side pressure and quicker back shifting but
decreases drive system efficiency. If too much spring tension
exists, the driven clutch will exert too much force on the belt and
can cause premature belt failure.

Back-Shifting

Back-shifting occurs when the track encounters an increased
load (demand for more torque). Back-shifting is a function of a
higher shift force within the driven clutch then within the drive
clutch. Several factors, including riding style, snowmobile
application, helix angles, and vehicle gearing determine how
efficient the drive system back-shifts. The desired engine
operating RPM should never fall below 200 RPM when the
drive system back-shifts.

CAUTION

Because of the critical nature and precision balance in-
corporated into the PVT system, it is absolutely essen-
tial that no attempt at clutch disassembly and/or repair 
be made without factory authorized special tools and 
service procedures. Polaris recommends that only au-
thorized service technicians that have attended a Po-
laris-sponsored service training seminar and 
understand the proper procedures perform adjust-
ments or repairs.

7.3

PVT System

7

Final Gearing

The final drive gear ratio plays an important role in how much
vehicle load is transmitted back to the helix. A tall gear ratio
(lower numerical number) typically results in lower initial
vehicle acceleration, but a higher top-end vehicle speed. A
lower gear ratio (higher numerical number) typically results in
a higher initial vehicle acceleration, but a lower top-end vehicle
speed.

Choosing the proper gear ratio is important to overall drive
system performance. When deciding on which gear ratio to use,
the operator must factor in the decision where the snowmobile
will be ridden, what type of riding will be encountered, and the
level of performance the operator hopes to achieve.

Gearing a snowmobile too low for extended high-speed runs
may cause damage to the drive belt and drive system, while
gearing a snowmobile too high for deep-snow, mountain use
may cause premature belt and clutch wear.

Typically, it is recommended to gear the snowmobile with a
slightly higher ratio than the actual top speed the snowmobile
will ever achieve.

1:1 Shift Ratio

A 1:1 shift ratio occurs when the drive clutch and the driven
clutch are rotating at the same RPM.

The mathematical vehicle speed for a given gear ratio at a 1:1
shift ratio is represented in the chaincase gearing charts located
in the Final Drive Chapter.

Low / High Ratio

Low ratio is the mechanical position when the drive belt is all the
way down into the drive clutch, and all the way out on the driven
clutch. High ratio represents when the drive belt is all the way
out on the drive clutch, and all the way in on the driven clutch.

Driven Helix / Ramp

The helix cam is the primary torque feedback component within
the driven clutch, regardless of driven clutch type. The
beginning angle of the helix must transmit enough torque
feedback to the moveable sheave in order to pinch the drive belt
while minimizing belt slip. The flatter or lower the helix angle,
the more side force will be exerted on the moveable sheave,
while the steeper, or higher the helix angle, the less side force

will be exerted on the moveable sheave.

7.4

PVT System

GENERAL INFORMATION

Special Tools

Team “12 Cooling Fin Driven Clutch” Offset Alignment Tool

PS-46998

Team “24 Cooling Fin Driven Clutch” Offset Alignment Tool

PS-47477

Drive Clutch Puller (3/4 - 16 x 7/16) - All Fuji Fan / Liquid Cooled Engines

2872084

Drive Clutch Puller (3/4 - 16 x 14mm) - Domestic 500 / 600 / 700 / 800 / FS / FST Engines

2872085

Drive Clutch Puller (14mm)

2871855 

Replacement Handle for ALL Clutch Pullers

5020326

Drive Clutch Holding Wrench

9314177-A

Strap Wrench

PU-45419

Replacement Strap

305085

Drive Clutch Spider Nut Socket

2870338

Drive Clutch Spider Removal and Spider Installation Tool

2870341-A

Pin Centering Tool

2870401

Clutch Pin Installation Tool

2870402

Clutch Pin Punch

2870507

Tapered Reamer - 29mm Short Drive (Fuji Snow Engines Only)

2870576

Tapered Reamer - 29mm Long Drive (Non-2007 600/700 CFI Domestic Snow Engines Only)

PS-48584

Tapered Reamer - 31mm (2007 600/700 CFI Domestic Snow Engines Only)

PS-48587

Roller Pin Tool

2870910-A

Drive Clutch Button Removal Tool

2870985

Clutch Bushing Replacement Tool Kit

2871025

Clutch Holding Fixture

2871358

Clutch Compression Tool

8700220

Spider Assembly Tool

8700221

Clutch Compression Tool Extensions for TEAM driven

PS-45909

Clutch Pilot Tool (used with the 2871358 to compress the clutch)

PU-45779

Drive Clutch Compression Tool (Compresses drive clutch without removing clutch from engine.)

2871173

7.5

PVT System

7

Drive Clutch Springs

NOTE: Springs listed as color - #### will have the
last four digits of the part number painted on the

spring coil. Tag each spring with the part number
and spring force when not in use.

PART NUMBER

COLOR

WIRE 

DIAMETER 

(inches)

FREE LENGTH 

+/-.125”

FORCE LBS.@2.50” - 

1.19” (+/- 12 LBS.)

LOAD 

RATE 

(lbs./inch)

7041021

Clear

.157”

4.14

70 - 130

44

7041022

Black

.140”

4.25”

44 - 77

25

7041063

Purple

.168

4.37

75  135

53

7041062

Silver

.207

3.12

75 - 243

151

7041065

Pink

.177

4.69

112 - 200

64

7041060

Orange

.196

3.37

70-199

98

7041083

Red

.192

3.77

120 - 245

94

7041102

Yellow

.192

2.92

44 - 185

105

7041061

Brown

.200

3.14

69 - 212

109

7041132

White

.177

2.92

34 - 141

81

7041168

Green

.177

3.05

42 - 142

76

7041148

Gold

.207

3.25

100 - 275

133

7041150

Red/White

.192

3.59

100 - 220

91

7041286

Silver/Gold

.218

3.05

77 - 240

163

7041080

Blue

.207

3.55

120 - 300

137

7041781

Dark Blue/White

.225

3.42

120 - 310

145

7041945

Almond

.218

3.65

140 - 330

145

7041645

Almond/Gold

.207

4.00

150 - 290

107

7041818

Black/White

.218

3.52

140 - 320

137

7041816

Almond/Black

.200

3.75

165 - 310

111

7041922

Almond/Blue

.218

3.75

150 - 310

122

7041988

Almond/Red

.207

4.27

165 - 310

110

7042083

Black/Green

.218

3.38

120 - 340

168

7043342

Black - 3342

.218

3.46

140 - 330

145

7043076

Black - 3076

.225

2.67

40 - 340

229

7043120

Black - 3120

.225

2.78

60 - 340

213

7043077

Black - 3077

.255

2.90

80 - 340

198

7043121

Black - 3121

.255

3.05

100 - 340

183

7042287

Black - 2287

.207

3.40

110 - 290

137