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WINCH HOIST AND RECOVERY WINCH APPLICATION DATA

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I WIRE ROPE SECTION

Wire Rope .................................................................................................................1Basic Components & Strand Patterns .............................................................1Core Materials .........................................................................................................2Strand Materials .....................................................................................................2Factors Aff ecting Selection & Wire Materials ...............................................2Construction ............................................................................................................3Wire Rope Spooling ..............................................................................................3D/d Ratio & D/d Ratio Comparison .................................................................4Insuffi cient D/d Ratio ...........................................................................................4Strength Loss Over Drums & Sheaves ............................................................5Bending & Proper Groove Size ..........................................................................5Fleet Angle ...............................................................................................................6Drum Width vs Sheave Distance ......................................................................6Spooling Devices ...................................................................................................7Level Wind Devices & Grooved Drums...........................................................7Tension Roller, Level Wind Device & Fairlead (4-Way Roller) ..................7Multi-Part Block System ......................................................................................8Sheave Effi ciency & Multi-Part Block Example ............................................8Selection Of Proper Design Factor ..................................................................9Trouble Shooting ................................................................................................ 10Calculating Drum Capacity ............................................................................. 11Typical Wire Rope Anchors .............................................................................. 11

II WINCH SELECTION SECTION

Winch Selector .................................................................................................... 13Planetary Model Number And Serial Number ........................................ 14Worm Gear Model And Serial Number ...................................................... 14Planetary Hoist Terminology ......................................................................... 15Basic Planetary Hoist Operation ................................................................... 18Dual Brake System - Operation ......................................................................21Dual Brake System With Auxiliary Brake - Operation .............................22Worm Gear Terminology ..................................................................................24

TABLE OF CONTENTS

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II WINCH SELECTION SECTION

Basic Worm Gear Recovery Winch Operation ................................................................. 26Typical Recovery Winch Operation .................................................................................... 27Common Hydraulic Equations....... ...................................................................................... 28Hoisting Or Pulling & Inclines ............................................................................................... 30Assuming A Rolling Load .01 Coeff . Of Friction ............................................................. 31Assuming A Sliding Load .10 & 1.00 Coeff . Of Friction ................................................ 31Incline Example Problem ....................................................................................................... 32Duty Cycle ................................................................................................................................... 32Theoretical Thermal Ratings To Reach 250º F ................................................................. 33Worm Gear vs Planetary ......................................................................................................... 34Worm Gear Effi ciency & Planetary Effi ciency.................................................................. 34Worm Gear vs Planetary ......................................................................................................... 35Gear Set Comparison .............................................................................................................. 35Line Speed By Layer ................................................................................................................. 36Line Pull By Layer ...................................................................................................................... 36Winch Performance By Layer ............................................................................................... 37Drum Size Requirements ....................................................................................................... 37Barrel Diameter ......................................................................................................................... 37Application Checklist .............................................................................................................. 38Selection Of Motor Type ........................................................................................................ 40Fixed Displacement Motors .................................................................................................. 40Variable Displacement Motors ............................................................................................ 40Gear Motor Operation ............................................................................................................ 41Gear Motor Comparison ........................................................................................................ 41Gear Motor .................................................................................................................................. 42Piston Motor ............................................................................................................................... 42Geroler Motor ............................................................................................................................ 43Vane Motor ................................................................................................................................. 44Basic Hydraulic Schematic - Single Speed Motor ......................................................... 45Basic Hydraulic Schematic - Two Speed Motor .............................................................. 46Brake Types ................................................................................................................................. 47Static Brake ................................................................................................................................. 47Dynamic Brake ........................................................................................................................... 48Heat Load .................................................................................................................................... 48Selection Of Gear Ratio .......................................................................................................... 49Winch Application .................................................................................................................... 50Application Example ............................................................................................................... 50Static vs Dynamic ..................................................................................................................... 51Hydraulic Considerations ...................................................................................................... 51Troubleshooting ....................................................................................................................... 51

TABLE OF CONTENTS

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III RECOVERY WINCH SECTION

Typical Applications .............................................................................................. 54Major Markets ......................................................................................................... 54Types Of Recovery Products .............................................................................. 55Worm Gear Recovery Winches .......................................................................... 55Worm Gear Recovery Winch Components ................................................... 56Oilfi eld Planetary Recovery Winches .............................................................. 57Mechanical and Hydraulic Drives .................................................................... 58Hydraulic Motor Adapters .................................................................................. 58Mechanical Drive vs Hydraulic Drive .............................................................. 58Recovery Winches - Right Hand vs Left Hand ............................................. 60Recovery Winches - Front Mount vs Rear Mount ....................................... 61Typical Worm Gear Recovery Winch Installations ...................................... 62Model Code - Low Mount Worm Gear ........................................................... 63Model Code - Upright Worm Gear ................................................................... 63Special Purpose Recovery Products ................................................................ 65Maximum Line Speed Torque Information .................................................. 67Theoretical Thermal Rating (Intermittent Duty) ......................................... 68Recovery Winch Cross Reference List ............................................................. 70

IV PLANETARY HOISTS SECTION

BRADEN GEARMATIC Planetary Hoists .......................................................... 71BRADEN GEARMATIC Planetary Hoist Features .......................................... 72BRADEN GEARMATIC Planetary Hoist Model Code ................................... 72BRADEN GEARMATIC Planetary Hoist Components ................................. 74Basic Operation - Parking ................................................................................... 75Basic Operation - Lowering ................................................................................ 75Basic Operation - Hoisting .................................................................................. 76Basic Hydraulic Circuit ......................................................................................... 77Features ..................................................................................................................... 78

TABLE OF CONTENTS

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NOTES

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WIRE ROPE

BASIC COMPONENTS AND STRAND PATTERNS

• Components In A Wire Rope

• Materials

• Design & Construction

• Proper Spooling

• Mult-Part Block Systems

• Design Factors / Strengths

• Trouble Shooting

• Wire Rope Anchors

• Calculating Drum Capacity

Wire rope consists of three basic components. While few in number, these vary in both complexity and confi guration to produce ropes for specifi c purposes or characteristics. The three basic components of a standard wire rope design are:

• the core

• multi-wire strands laid helically around a core• wires that form the strand

Wire for rope is made in several materials and types: these include steel, iron, stainless steel, monel, and bronze. By far, the most widely used material is high-carbon steel. This is available in a variety of grades each of which has properties related to the basic curve for steel rope wire. Wire rope manufacturers select the wire type that is most appropriate for requirements of the fi nished product.

Wire

Strand

Core

Wire Rope

6 X 25 Independent Wire Rope Core (IWRC)

Six strands, 25 wires per strand

Dyform-18

High-strength

Low-rotation

Dyform-6

Greater bonding life

WIRE ROPE 1

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WIRE ROPE

BASIC COMPONENTS AND STRAND PATTERNS

• FC = Fiber Core

• Steel Core

- IWRC = Independent Wire Rope Center

- WSC = Wire Strand Core

• High-carbon Steel

• Specialty Metals

• High Strength Synthetic Fibers

STRAND MATERIALS

0

2040

60

80

100

120140

IPS EIPS EEIPS

• Strength (Resistance to Breakage)• Resistance to Bending Fatigue• Resistance to Vibration Fatigue• Resistance to Abrasion• Resistance to Crushing• Reserve Strength

• IPS - Improved Plow Steel• EIPS - Extra Improved Plow Steel• EEIPS - Extra Extra Improved Plow Steel

Grades of wire rope are referred to as traction steel (TS), mild plow steel (MPS), plow steel (PS), improved plow steel (IPS), extra improved plow steel (EIPS), and extra extra improved plow steel (EEIPS). (These steel grade names originated at the earliest stages of wire rope development and have been retained as refer-ences to the strength of a particular size and grade of rope.) The plow steel strength curve forms the basis for calculating the strength of all steel rope wires. The tensile strength (psi) of any steel wire grade is not constant, it varies with the diameter and is highest in the smallest wires.

The chart above shows that as the number of wires in each strand increases (i.e. the wires get smaller), the resistance to bending fatigue increases, but the resistance to abrasion decreases.

2 WIRE ROPE

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CONSTRUCTION

WIRE ROPE SPOOLING

Right Regular Lay

Left Regular Lay

Left Lang Lay

Right Lang Lay

Under Drum Over Drum

Over Drum Under Drum

Left Hand - Left Lay

Right Hand - Right Lay

WIRE ROPE 3

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D/d RATIO COMPARISON

INSUFFICIENT D/d RATIO

Recovery Winch S.A.E. D/d Standard: 8:1

4 in. (101.6 mm) Drum dia

.5 in. (12.7 mm) Wire Rope dia

d

D

Example:

(Drum diameter I Wire Rope diameter)

Hoist ANSI D/d Standard: 17:1

8.5 in. (215.9 mm) Drum dia

.5 in. (12.7 mm) Wire Rope dia

Example:

= 8:1

= 17:1

4 WIRE ROPE

“Spiraling” – Cause: Insuffi cient drum diameter and/or excessive load

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WIRE ROPE 5

STRENGTH LOSS OVER DRUMS AND SHEAVES

BENDING AND PROPER GROOVE SIZE

2 6 10 14 18 22 3026 34 38

50

60

70

80

90

100

BENDING EFFICIENCY

Right

Wrong

Right

Wrong

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6 WIRE ROPE

FLEET ANGLE

DRUM WIDTH VS SHEAVE DISTANCE

ADrum Width Between Flanges

B1

Max. Distance to First Sheave

(½º Fleet Angle per Side)

B2

Min. Distance to First Sheave

(1½º Fleet Angle per Side)

in. mm ft m ft m

6 152 28.7 8.7 9.5 2.9

8 203 38.3 11.7 12.7 3.9

10 254 47.9 14.6 15.9 4.8

12 305 57.5 17.5 19.1 5.8

14 355 67.1 20.4 22.3 6.8

16 406 76.6 23.3 25.4 7.7

18 457 86.2 26.3 28.6 8.7

20 508 95.8 29.2 31.8 9.7

22 559 105.4 32 35.0 10.7

24 610 115.0 35 38.2 11.6

26 660 124.5 38 41.3 12.6

28 711 134.1 41 44.5 13.6

30 762 143.7 44 47.7 14.5

32 813 153.3 47 50.9 15.5

34 865 162.9 49.6 54.1 16.5

36 915 172.4 11 57.2 17.4

38 965 182.0 52.5 60.4 18.4

40 1016 191.6 58.4 63.6 19.4

Fleet Angle (Left)

1½º Max. - ½º Min.

Fleet Angle (Right)

1½º Max. - ½º Min.

A

B2

B1

H

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WIRE ROPE 7

SPOOLING DEVICES

LEVEL WIND DEVICES AND GROOVED DRUMS

Diamond Screw Level Wind Grooved Drum

TENSION ROLLER, LEVEL WIND DEVICE, AND FAIRLEAD (4-WAY ROLLER)

• Tension Plates or Rollers

• Level WInd Devices

• Grooved Drums

• Fairlead Assemblies

Benefi cial in

slack wire rope

condition only

Hurst Level Wind Protects wire rope

during side pulls

Groo ed Dr m

HOISTHOIST

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8 WIRE ROPE

MULTI-PART BLOCK SYSTEMS

SHEAVE EFFICIENCY AND MULTI-PART BLOCK EXAMPLE

Parts Of Line

With Plain Bearing Sheaves

With Roller Bearing Sheaves

1 1.090 1.0402 0.568 0.5303 0.395 0.3604 0.309 0.2755 0.257 0.2256 0.223 0.1917 0.199 0.1678 0.188 0.1489 0.167 0.13510 0.156 0.12311 0.147 0.14412 0.140 0.106

Multi-part Block Example:

Load = 20,000 lbParts of line = 4Roller Bearing Sheaves

What Line Pull Is Required At Winch?

(20,000 LB Load) x (.275 Sheave Effi ciency) = 5,500 Lb Line Pull Required At The Winch

1 Part 2 Part 3 Part 4 Part 5 Part

To determine the number of parts of line, count the number of cables between the fi xed sheave and the load. Do not count the line from the winch to the fi xed sheave.

Note: This method is for hoisting applications only. DOES NOT apply to recovery applications where the load line is connected back to the recovery vehicle.

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WIRE ROPE 9

SELECTION OF PROPER DESIGN FACTOR

• Speed of Operation

– Acceleration & Deceleration

• Length of Rope

• Number, Size & Location of Sheaves & Drums

• Rope Attachments

• Conditions Causing Corrosion & Abrasion

• Danger to Human Life or Property

Wire Rope Size

Nominal Breaking Strength

(lbs.)

2:1 Design Factor

(lbs.)

3:1 Design Factor

(lbs.)

3.5:1 Design Factor

(lbs.)

4:1 Design Factor

(lbs.)

5:1 Design Factor

(lbs.)

1/4 5,880 2,940 1,960 1,680 1,470 1,176

3/8 13,120 6,560 4,373 3,749 3,280 2,624

1/2 23,000 11,500 7,667 6,571 5,750 4,600

5/8 35,800 17,900 11,933 10,229 8,950 7,160

3/4 51,200 25,600 17,067 14,629 12,800 10,240

1 89,800 44,900 29,933 25,657 22,450 17,960

1 1/8 113,000 56,500 37,667 32,286 28,250 22,600

1 1/4 138,800 69,400 46,267 39,657 34,700 27,760

6 x 19 IWRC IMPROVED PLOW STEEL (IPS)

Wire Rope Size

Nominal Breaking Strength

(lbs.)

2:1 Design Factor (lbs.)

3:1 Design Factor (lbs.)

3.5:1 Design Factor (lbs.)

4:1 Design Factor (lbs.)

5:1 Design Factor (lbs.)

1/4 6,800 3,400 2,267 1,943 1,700 1,360

3/8 15,100 7,550 5,033 4,314 3,775 3,020

1/2 26,600 13,000 8,867 7,600 6,650 5,320

5/8 41,200 20,600 13,733 11,771 10,300 8,240

3/4 58,800 29,400 19,600 16,800 14,700 11,760

1 103,400 51,700 34,467 29,543 25,850 20,680

1 1/8 130,000 65,000 43,333 37,143 32,500 26,000

1 1/4 159,800 79,900 53,267 45,657 39,950 31,960

6 x 19 IWRC EXTRA IMPROVED PLOW STEEL (EIPS)

Wire Rope Size

Nominal Breaking Strength

(lbs.)

2:1 Design Factor (lbs.)

3:1 Design Factor (lbs.)

3.5:1 Design Factor (lbs.)

4:1 Design Factor (lbs.)

5:1 Design Factor (lbs.)

1/2 29,200 14,600 9,733 8,343 7,300 5,840

5/8 45,400 22,700 15,133 12,971 11,350 9,080

3/4 64,800 32,400 21,600 18,514 16,200 12,960

1 115,000 57,500 38,333 32,857 28,750 23,000

1 1/8 143,000 71,500 47,667 40,857 35,750 28,600

1 1/4 175,800 87,900 58,600 50,229 43,950 35,160

DYFORM 18 HSLR

Wire Rope Size

Nominal Breaking Strength

(lbs.)

2:1 Design Factor (lbs.)

3:1 Design Factor (lbs.)

3.5:1 Design Factor (lbs.)

4:1 Design Factor (lbs.)

5:1 Design Factor (lbs.)

1/2 29,200 14,600 9,733 8,343 7,300 5,840

5/8 45,400 22,700 15,133 12,971 11,350 9,080

3/4 64,800 32,400 21,600 18,514 16,200 12,960

1 115,000 57,500 38,333 32,857 28,750 23,000

1 1/8 143,000 71,500 47,667 40,857 35,750 28,600

1 1/4 175,800 87,900 48,600 50,229 43,950 35,160

6 x 19 IWRC EXTRA EXTRA IMPROVED PLOW STEEL (EEIPS)

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TROUBLESHOOTING

Problem:

Rope climbing one fl ange

Possible causes:

• Hoist Not Perpendicular With First Sheave

• Hoist Not Centered On First Sheave

• Drum Flanges Not Straight

Problem:

Rope stacks in center of drum

Possible causes:

• Excessive fl eet angle (Hoist too close to fi rst sheave)

Problem:

Rope climbs both fl anges

Possible causes:

• Insuffi cient fl eet angle (Hoist too far from fi rst sheave)

Problem:

Rope not spooled smoothly

Possible causes:

• Wrong lay or wire rope

• Insuffi cient over haul weight

• Load removed from wire rope

• First layer improperly installed

Problem:

Rope “knifes in” to lower layers

Possible causes:

• Lower layers installed with insuffi cient load

• Incorrect groove width

10 WIRE ROPE

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L = Length of wire rope ft (m) all other dimensions in. (mm)

L = (A+D) x A x B x KA

D

B

C

CALCULATING DRUM CAPACITY

TYPICAL WIRE ROPE ANCHORS

U-Bolt Anchor Set Screw Anchor

Wedge Anchor

All drums require minimum fi ve (5) wraps of rope left on drum at all times

WIRE ROPE 11

Values of K

Rope DiameterK

Rope DiameterK

in. mm in. mm

1/4 6 3.29 5/8 16 0.607

5/16 8 2.21 3/4 19 0.428

3/8 9 1.56 7/8 22 0.308

7/16 11 119 1 25 0.239

1/2 13 0.925 1-1/8 28 0.191

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NOTES

12 WIRE ROPE

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WINCH SELECTOR

• General information

- Model and serial number location

- Planetary hoist terminology

- Basic planetary hoist operation

- Worm gear terminology

- Basic worm gear recovery winch operation

- Common hydraulic equations

• Do you want to pull or hoist a load?

• What is the maximum weight or amount you want to pull or hoist?

• How far do you want to pull or hoist the above load?

• Do you need to pull or hoist this amount with the drum full?

• How fast do you want to pull or hoist the above load?

• What size wire rope do you need to use?

• How much wire rope do you want to store on the winch drum?

• What is your power source?

WINCH SELECTION 13

WINCH

PLANETARY MODEL/SERIAL NUMBERS

WORM GEAR MODEL/SERIAL NUMBERS

When information on a hoist is needed, always refer to the model number and serial number. They are steel stamped into the hoists at the locations shown above. The serial number is a seven digit number. The fi rst two digits represent the year of manufacture.

Example: 02XXXXX, built in 2002.

Model and Serial Numbers

Braden worm gear winches are identifi ed by model and serial numbers stamped into a smooth surface near the top of the worm gear housing.

The winch model number and serial number must be referenced when ordering service parts or requesting information.

Do not try to identify a Braden winch by using a raised or foundry casting number.

Model and Serial Numbers

14 WINCH SELECTION

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PLANETARY HOIST TERMINOLOGY

Observe hoist

from this side

Observe hoist

from this side

Overwound Cable

Right-hand base

(standard confi guration)

Left-hand base

WINCH SELECTION 15

Brake Valve - A hydraulic counterbalance valve is usually bolted to the hoist port of the hydraulic motor. It allows oil to fl ow freely through the motor in the hoisting direction.

When oil pressure tries to rotate the motor in the lowering direction, the brake valve blocks the fl ow of oil out of the motor until the internal static brake is released. It then controls lowering speed based on the load and fl ow of oil to the motor. All the heat generated by controlling the speed of the load is dissipated by the hydraulic system, not by the internal static brake.

Grooved Drum - A cable drum with grooves on the barrel to ensure the fi rst layer of cable spools properly onto the drum.

The grooves can be cast or machined into the drum, or cast or machined into separate pieces that are mechanically fastened to the drum.

Note: Only one size cable can be used on a grooved drum.

to determine

base confi guration

to determine

base confi guration

Observe hoist

from this side

Observe hoist

from this side

Underwound Cable

Right-hand base

(standard confi guration)

Left-hand base

to determine

base confi guration

to determine

base confi guration

HOISTHOIST

HOISTHOIST

WINCH

Sprag or Overrunning Clutch - A mechanical one-way clutch on the input shaft of the hoist, between the input shaft and the static mechanical brake. The clutch allows the input shaft to turn freely in the direction required to spool cable onto the drum (i.e. lift a load), then immediately locks the hoist gear train to the mechanical brake when the hoist is stopped, holding the load in place.

Static, Mechanical, or Load-Holding Brake - A multi-disc, spring applied, hydraulically released brake that works together with the sprag clutch to hold a suspended load. This brake is not designed to stop a load being lowered, but holds the load in place when the hoist is not being operated.

First Layer Line Pull Rating - The maximum rated line pull (in pounds or kilograms) on the fi rst layer of cable. The maximum rating for any particular hoist is based on maintaining an acceptable structural design factor and service life. Certain combinations of drum, gear ratio, motor and hydraulic fl ow may reduce or increase this rating.

First Layer Line Speed Rating - The maximum rated line speed (in feet or meters per minute) on the fi rst lay of cable. Certain combinations of drum, gear ratio, motor and hydraulic fl ow may reduce or increase this rating.

D/d Ratio - The ratio of cable drum barrel diameter (D) to wire rope diameter (d). Current ANSI standards require a minimum of 17:1.

Examples:

If you know the cable diameter you want to use, multiply it by 17 to get the minimum cable drum barrel diameter.

I.e., ½ in. (13 mm) wire rope X 17 = 8.5 in (221 mm) = minimum hoist barrel diameter

If you know the barrel diameter, divide it by 17 to get the maximum wire rope diameter.

I.e., 10 in. (254 mm) barrel diameter / 17 = 0.588 or 9/16 (14 mm) = maximum wire rope diameter

PLANETARY HOIST TERMINOLOGY (CONTINUED)

16 WINCH SELECTION

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Cable Drum Dimensions -

Fleet Angle - The angle between the wire rope’s position at the extreme end wrap on a drum, and a line drawn perpendicular to the axis of the drum, through the center of the nearest fi xed sheave or load attachment point.

Wrap - A single coil of wire rope wound on a drum.

Layer - Wraps of wire rope on the same level between drum fl anges.

Freeboard - The amount of drum fl ange that is exposed radially past the last layer of wire rope. Minimum freeboard varies with the regulatory organization. ASME B30.5 requires ½ in. minimum freeboard.

Barrel

Diameter

Flange

Diameter

Distance

between

Flanges

PLANETARY HOIST TERMINOLOGY (CONTINUED)

First sheave or load should be centered between the drum fl anges, so that angles A and B are equal.

Angles A and B should be a minimum of ½º and a maximum of 1½º

½º Min

½º Min

A

BFirst Sheave

or Load

A

B

Distance

Fleet Angles A & B:

1½º Max. - ½º Min.

A=B

1½º Max

1½º Max

WINCH SELECTION 17

WINCH

BASIC PLANETARY HOIST OPERATION

DESCRIPTION OF HOIST

1. Hydraulic motor and brake valve 2. Drum, drum closure, ball bearings and oil seals 3. Base, bearing support and motor adapter 4. Brake clutch assembly 5. Brake cylinder assembly and multiple - disc brake 6. Planetary gear reducer assemblies

THEORY OF OPERATIONThe primary sun gear is directly coupled to the hydraulic motor by the inner race of the brake clutch assembly. As the motor turns in the hoisting direction (normally clock-wise), the planetary assemblies reduce the input speed of the motor and rotate the winch drum. If the output planet carrier is held from turning by the bearing support, the drum rotates in the opposite direction of the motor input shaft. If the ring is held stationary, the drum rotates in the same direction as the motor shaft.

In the hoisting direction, the static brake remains fully applied and the input shaft rotates freely through the sprag clutch. When the motor is stopped, the load tries to rotate the winch gear train in the opposite direction. The sprag clutch on the input shaft immediately locks up, allowing the fully applied static brake to hold the load from dropping. (See Dual Brake System - Operation for a detailed description of the lowering sequence of operation.)

Dual Brake System - Description

The dual brake system consists of a dynamic brake system and a static brake system.

The dynamic brake system has two operating components: 1. Brake valve assembly 2. Hydraulic motor

The brake valve is basically a counterbalance valve. It contains a check valve to allow free fl ow of oil to the motor in the hoisting direction and a pilot operated, spring-loaded spool valve that blocks the fl ow of oil out of the motor when the control valve is placed in neutral.

When the control valve is placed in the lowering position, the spool valve remains closed until suffi cient pilot pressure is applied to the end of the spool to shift it against spring pressure and open a passage.

18 WINCH SELECTION

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After the spool valve cracks open, the pilot pressure becomes fl ow-dependent and modulates the spool valve opening which controls the lowering speed.

The static brake system has three operating components:

1. Spring Applied, Multiple Friction Disc Static Brake 2. Brake Clutch Assembly 3. Hydraulic Piston and Cylinder

BASIC PLANETARY HOIST OPERATION (CONTINUED)

WINCH SELECTION 19

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BASIC PLANETARY HOIST OPERATION (CONTINUED)

HOISTING

LOWERING

20 WINCH SELECTION

HYDRAULIC

BRAKE

RELEASE

MOTOR

BRAKE

VALVE

OIL

IN PUMP

TO TANK

CONTROL VALVE

HYDRAULIC

BRAKE

RELEASEMOTOR

BRAKE

VALVE

OIL

INPUMP

TO TANK

CONTROL VALVE

HYDRAULIC

BRAKE

RELEASE MOTOR

BRAKE

VALVE

OIL

IN

PUMP

TO TANK

CONTROL VALVE

HYDRAULIC

BRAKE

RELEASEMOTOR

BRAKE

VALVE

OIL

IN PUMP

TO TANK

CONTROL VALVE

HYDRAULIC

BRAKE

RELEASEMOTOR

BRAKE

VALVE

OIL

IN

PUMP

TO TANK

CONTROL VALVE

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BASIC PLANETARY HOIST OPERATION (CONTINUED)

DUAL BRAKE SYSTEM - OPERATION

The static brake is released by the brake valve pilot pressure at a pressure lower than that required to open the pilot operated spool valve. This sequence assures that dynamic braking takes place in the brake valve and that little, if any, heat is absorbed by the static, friction brake.

The hydraulic cylinder, when pressurized, will release the spring pressure on the brake discs, allowing the brake discs to turn freely.

The static friction brake is a load holding brake only and has nothing to do with dynamic braking or rate of descent of a load.

When the control valve is placed in the hoisting position, hydraulic oil fl ows freely through the brake valve to the motor. The static brake remains fully engaged, as the sprag cams lay over and permit the inner race to turn free of the outer race.

Sprag Cams

STOPPED - HOLDING LOAD

Load attempts to rotate shaft in opposite direction.

Brake clutch locks sun gear shaft to friction brake.

HOISTING

Permits free shaft rotation while hoisting.

The winch, in raising a load, is not aff ected by any braking action. When hoisting is stopped, the sprag clutch immediately engages the friction brake.

WINCH SELECTION 21

HOIST

HOLD

WINCH

When hoisting a load, the brake clutch, which connects the motor shaft to the primary sun gear, allows free rotation of the gear train. The sprag cams lay over and permit the inner race to turn free of the outer race. The friction brake remains fully applied, but the shuttle valve allows oil to the auxiliary brake to release the brake.

For extremely light loads (such as in empty hook conditions), some slight scrubbing of the auxiliary brake plates may occur. The fully applied static brake has no eff ect on the hoist during lifting operations.

DUAL BRAKE SYSTEM - OPERATION (CONTINUED)

When the lifting operation is stopped, the load attempts to turn the primary sun gear in the opposite direction. This reversed input causes the sprag cams to instantly roll upward and fi rmly lock the shaft to the fully engaged friction brake.

When the hoist is powered in reverse, to lower the load, the motor cannot rotate until suffi cient pilot pressure is present to open the brake valve. The friction brake within the hoist will completely release at a pressure lower than that required to open the brake valve. The extent to which the brake valve opens will determine the amount of oil that can fl ow through it and the speed at which the load will be lowered. Increasing the fl ow of oil to the hoist motor will cause the pressure to rise and the opening in the brake valve to enlarge, speeding up the descent of the load. Decreasing this fl ow causes the pressure to lower and the opening in the brake valve to decrease thus slowing the descent of the load.

When the control valve is shifted to neutral, the pressure will drop and the brake valve will close, stopping the load. The friction brake will engage and hold the load after the brake valve has closed.

When lowering a load very slowly for precise positioning, no oil fl ow actually occurs through the hoist motor. The pressure will build up to a point where the brake will release suffi ciently to allow the load to rotate the motor through its own internal leakage. This feature results in a very slow speed and extremely accurate positioning.

The friction brake receives very little wear in the lowering operation. All of the heat generated by the lowering and stopping of a load is absorbed by the hydraulic oil where it can be readily dissipated.

DUAL BRAKE SYSTEM WITH AUXILIARY BRAKE - OPERATION

Auxiliary Brake

22 WINCH SELECTION

WINCH

When the lifting operation is stopped, the load attempts to turn the primary sun gear in the opposite direction. This reverse input causes the sprag cams to instantly roll upward and fi rmly lock the shaft to the fully applied static brake.

When the hoist is powered in the lowering direction, the motor cannot rotate until there is suffi cient pilot pressure to open the brake valve. The static friction brake will completely release at a pressure lower than that required to open the brake valve, typically 400 – 450 PSI (2,760 - 3,100 kPa) and 600 -700 PSI (4,140 - 4,830 kPa) respectively. The extent to which the brake valve opens will determine the amount of oil that can fl ow through it, and the speed at which the load will be lowered. Increasing the fl ow of oil to the hoist motor will cause the pressure to rise causing the brake valve opening to enlarge, speeding up the descent of the load. Decreasing this fl ow causes the pressure to lower and the opening in the brake valve to decrease in size, thus slowing the descent of the load.

When the control valve is shifted to neutral, the pressure will drop and the brake valve will close, stopping the load. The static friction brake will engage and hold the load fi rm after the brake valve has closed.

When lowering a load very slowly for precise positioning, no oil fl ow actually occurs through the hoist motor. The pressure will rise to a point where the brake will release suffi ciently to allow the load to rotate the motor through its own internal leakage. This feature results in a very slow speed for extremely accurate positioning.

The friction brake receives very little wear in the lowering operation. All of the heat generated by the lowering and stopping of a load is absorbed by the hydraulic oil, where it can be readily dissipated.

During both lifting and lowering operations, the auxiliary brake will open to allow the drum to operate. In the lifting direction, the shuttle valve diverts the oil fl ow away from the static hoist brake and allows the release of the auxiliary brake. The pressure required to completely release the auxiliary brake is 400 - 450 PSI (2,760 - 3,100 kPa). During lowering, the oil from the brake valve is sent to both the static brake and the auxiliary brake, allowing both brakes to be released simultaneously. This action assures that both brakes are released before the brake valve opens, further assuring that dynamic braking takes place within the brake valve.

DUAL BRAKE SYSTEM WITH AUXILIARY BRAKE - OPERATION (CONTINUED)

The hoist directional control valve must be a three-position, four-way valve without detents and with a spring-centered motor spool such that the valve returns to the centered position whenever the handle is released, and both work ports are opened to tank (open center, open port).

WINCH SELECTION 23

WINCH

WORM GEAR TERMINOLOGY

Starting Input Torque - The torque applied to the winch input shaft required to start a rated load upward from a suspended position. It is expressed in pound-feet, pound-inches, kilogram-meters or Newton-meters. May be referred to as static torque.

Running Input Torque - The torque applied to the winch input shaft required to maintain upward movement of rated load. It is expressed in pound-feet, pound-inches, kilogram-meters or Newton-meters. May also be referred to as dynamic torque.

Rated Input Speed - The maximum permissible input speed at rated load expressed in RPM. Exceeding rated input speed may cause damage to the worm gear set.

Full Drum or Maximum Layers - A drum containing the maximum number of cable layers which would leave a freeboard of 0.7 x the cable diameter below the drum fl ange.

Drum Storage Capacity - The maximum length of wire rope which may be wound on a cable drum without exceeding the maximum number of layers. It is expressed in feet or meters.

Rated Line Pull - The line pull on any layer that results from the output torque which produces maximum rated line pull on the fi rst layer. Rated fi rst layer line pull is based on maintaining an acceptable structure safety factor while providing an acceptable component service life. Line pull is expressed in pounds or kilograms.

Rated Line Speed - The line speed on any specifi c layer that results from rated input speed. It is expressed in feet/minute or meters/minute.

Thermal Rating (Duty Cycle) - The result of a test, expressed as the distance (feet or meters) a load travels up and down while hoisting and lowering a specifi ed weight until the lubricating oil rises from 100º F to 250º F (38º C to 121º C). 250º F (121º C) is the maximum intermittent gear oil temperature allowed. Most gear oils “break down” rapidly at higher temperatures and seals may be damaged.

Largest Recommended Wire Rope Size - Should be no larger than 1/8th the cable drum barrel diameter for most recovery applications.

Drum Clutch - Also known as a “dog-clutch” or “jaw-clutch,” consists of two or more drive lugs which engage similar driven lugs to transmit torque to the cable drum.

Free Spooling - The operation of manually unspooling wire rope from the cable drum by pulling on the free end of the rope while the cable drum is disconnected (declutched) from its power.

Wrap - A single coil of wire rope wound on a drum.

Layer - All wraps on the same level between drum fl anges.

Freeboard - The amount of drum fl ange that extends radially past the last layer of wire rope.

24 WINCH SELECTION

WINCH

WORM GEAR TERMINOLOGY (CONTINUED)

Mean Drum - A theoretical point located midway between the fi rst layer of wire rope on the cable drum barrel and the top layer. Often used as a reference point in measuring winch performance.

Gear Set Effi ciency - The relationship between the input horsepower transmitted to the winch by the prime mover and the output horsepower transmitted by the winch to the wire rope. Expressed as a percentage.

Extension Shaft - The standard cable drum shaft is extended or replaced by an extra long shaft which permits the use of capstans or CR reels at the side of the vehicle, most extension shafts are limited to a standard length of 44 to 46-1/2 in. (112-118 cm) from the cable drum center-line.

Capstan - Usually a small removable drum used to apply force to fi ber rope wrapped around the barrel with tension applied by hand. Most have a nominal barrel diameter of 7 in. (178 mm).

CR Reel - Collapsible recovery reels are used for picking up and coiling power and telephone lines which have been removed from the poles and lowered to the ground. Most CR reels have a nominal barrel diameter of 20” (508 mm).

Bull Gear - Bronze alloy gear powered by the steel worm. Braden refers to the “bull gear” as the worm gear.

Fleet Angle - The angle between the wire rope’s position at the extreme end wrap on a drum, and a line drawn perpendicular to the axis of the drum through the center of the nearest fi xed sheave or load attachment point.

WINCH SELECTION 25

First sheave or load should be centered between the drum fl anges, so that angles A and B are equal.

Angles A and B should be a minimum of ½º and a maximum of 1½º

½º Min

½º Min

A

BFirst Sheave

or Load

A

B

Distance

Fleet Angles A & B:

1½º Max. - ½º Min.

A=B

1½º Max

1½º Max

WINCH

BASIC WORM GEAR RECOVERY WINCH OPERATION

Procedure for Shifting Clutch (Where Equipped):

A To Engage Clutch

1. Insure winch motor or PTO is not running and the winch cable and cable drum are not loaded. The prime mover is stopped in neutral with parking brake set.

2. Lift lock knob on shift handle (where applicable) to disengage lock detent. Move handle to full travel to engage clutch. If shift handle lock knob will not engage detent hole, the clutch is not fully engaged. At this point it may be necessary to manually rotate the cable drum slightly in either direction to align clutch lugs while holding slight pressure on the shift handle.

B To Disengage Clutch

1. Ensure winch motor or PTO is not running and the winch cable and cable drum are not loaded. The prime mover is stopped in neutral with parking brake set.

2. Lift lock knob on shift handle (where applicable) to disengage lock detent. Move shift handle full travel to disengage clutch. If shift handle has Resistance to shift, cable drum may be manually rotated in the direction to haul-in cable to relieve the self-energized load on the drum clutch lugs and allow shift.

Note: If your operation involves lifting loads and does not require the clutch to be disengaged, Braden strongly recommends the drum clutch be mechanically locked in the fully engaged position to avoid accidental disengagement of the clutch.

Basic Winch Operating Method - Engine speed, PTO controls will infl uence your “feet” of the winch operation. Remote lever controls, air-shift cylinders and emergency stop systems should be adjusted at time of installation and all operators fully trained on their operation under a no-load condition.

Typical Winch Maneuver - When possible, position winch such that the centerline of the winch drum is perpendicular to the winch load. The angle the winch must pull from (fl eet angle) must not exceed 1-1/2º. If the fl eet angle exceeds 1-1/2º, the cable will not spool correctly resulting in damaged cable and prematurely worn winch components.

Disengage the drum clutch, as described earlier, and pull cable off of winch drum. If equipped, apply shoe or band type drum brake to control drum over-spin or “birdnesting.”

Avoid powering out winch cable as this practice causes unnecessary heat and accelerated wear of winch brake components.

Securely attach winch cable to load in such a manner to avoid damage to the load or cable. Fully engage the drum clutch as described earlier.

Release band type drum brake, if so equipped, and engage winch control. Operate controls smoothly to avoid “jerking” of load. Operate winch at slowest speed practicable for your application to reduce worm gear heat rise and maintain winch load control.

26 WINCH SELECTION

WINCH

BASIC WORM GEAR RECOVERY WINCH OPERATION (CONTINUED)

Observe winch operation carefully to make certain that all ground personnel remain clear of winch cable and load and that load does not shift requiring the repositioning of the winch cable or winch. When the load is properly positioned, stop the winch. The automatic safety brake and worm gear set are designed to hold the load when properly positioned , stop the winch. The automatic safety brake and worm gear set are designed to hold the load when properly adjusted. (Refer to “Safety Brake Service & Adjustment)

Secure the load in position. Pay out enough winch cable to remove all tension on cable and drum. Disengage drum clutch and disconnect winch cable from load.

Engage drum clutch as described earlier. When possible, visually determine that the drum clutch is fully engaged.

Wind winch cable back onto cable drum while maintaining minimum fl eet angle and suffi cient tension to cause the cable to spool properly being careful to keep hands and clothing away from cable drum and fairhead rollers.

TYPICAL RECOVERY WINCH OPERATION

The directional control valve must be a three-position, four-way valve without detents and with a spring-centered motor spool such that the valve returns to the centered position whenever the handle is released, and both work ports are opened to tank (open center, open port).

WINCH SELECTION 27

WINCH

28 WINCH SELECTION

COMMON HYDRAULIC EQUATIONS

TO FIND:

Motor Output Torque, Starting

Motor RPM

Required Motor Size (cu. in.)

Required Flow for Desired RPM:

6 cu. in. x 2000 RPM

System Flow (GPM) x 231 x .90 Vol. Efficiency.=

Example: 35 gpm x 231 x .906 cu. in.

= 1213 rpm Motor Output Speed

Motor Size (cu. in.)

= System pressure (psi) x Motor Size (cu. in.) x .1591 x Motor Starting Efficiency

System Pressure = 2500 psiSystem Flow = 35 gpmMotor Size = 6 cu. in.Motor Starting Efficiency = 70%2500 PSI x 6 cu. in. x .1591 x .70 (eff) = 1670 lb in. torque

Example:

Input Torque Required (in. lb)=

System Pressure (PSI) x .1591 x Motor Starting Efficiency

Input Torque Required = 1500 lb in.System Pressure = 2000 PSIMotor Starting Efficiency = 70%

Example:

= 6.73 cu. in. motor required200 PSI x .1591 x .70 Efficiency

1500 lb in.

Motor Size (cu. in.) x Desired RPM=

231 x .90 Vol. Efficiency

Motor Size = 6 cu. in.Desired RPM = 2000

Example:

231 x .90 = 58 GPM Required

WINCH

WINCH SELECTION 29

TO FIND:

Required Horsepower To Drive Pump

Maximum Pressure If Horsepower And Flow Are Fixed

Maximum Flow If Horsepower And Flow Are Fixed

COMMON HYDRAULIC EQUATIONS (CONTINUED)

System Pressure (PSI) x System Flow (GPM)=

1714 x .80 Pump Efficiency

System Pressure = 2500 PSISystem Flow = 35 GPM

Example:

= 64 Horsepower1714 x .80 Pump Efficiency

2500 PSI x 35 GPM

Available Horsepower x 1714 x .80 Eff.=

System Flow (GPM)

Available Horsepower = 50System Flow = 35 GPM

Example:

35 GPM50 HP x 1714 x .80 Pump Efficiency

Available Horsepower x 1714 x .80 Eff.=

System Pressure (psi)

Available Horsepower = 50System Pressure = 2500 PSI

Example:

= 27.4 GPM Max. System Flow2500 PSI

50 HP x 1714 x .80 Pump Eff.

= 27.4 GPM Max. System Flow

WINCH

HOISTING OR PULLING & INCLINES

HOISTING:

Load on hoist is equal to weight of load. Load on hoist can be reduced by multi-parting the wire rope. (See Wire Rope Section, page 8.)

PULLING ON LEVEL SURFACE:

Load on winch is reduced by a factor based on the friction between the load being moved and the surface it is sliding on. (See page 16.)

PULLING ON INCLINED SURFACE:

Load on winch is reduced by a factor based on the friction between the load being moved and the surface it is sliding on, plus the slope of the incline. (See page 16.)

x

y

x

y

30 WINCH SELECTION

WINCH

ASSUMING A ROLLING LOAD OF .01 COEFFICIENT OF FRICTION

ASSUMING A SLIDING LOAD OF .01 COEFFICIENT OF FRICTION

% OF GRADE ANGLE PULL/WEIGHT

0.00 0º 0.10

17.63 10º 0.27

36.40 20º 0.44

57.74 30º 0.59

83.91 40º 0.72

119.18 50º 0.83

173.21 60º 0.92

274.75 70º 0.97

567.13 80º 1.00

Infinity 90º 1.00

SLIDING LOAD .10 COEFFICIENT GREASED SURFACE

% OF GRADE ANGLE PULL/WEIGHT

0.00 0º 1.00

17.63 10º 1.16

36.40 20º 1.28

57.74 30º 1.37

83.91 40º 1.41

119.18 50º 1.41

173.21 60º 1.37

274.75 70º 1.28

567.13 80º 1.16

Infinity 90º 1.00

SLIDING LOAD 1.00 COEFFICIENT LOCKED RUBBER TIRES ON DRY CONCRETE

% OF GRADE ANGLE PULL/WEIGHT

0.00 0º 0.01

17.63 10º 0.18

36.40 20º 0.35

57.74 30º 0.51

83.91 40º 0.65

119.18 50º 0.77

173.21 60º 0.87

274.75 70º 0.94

567.13 80º 0.99

Infinity 90º 1.00

ROLLING LOAD .01 COEFFICIENT

WINCH SELECTION 31

WINCH

DUTY CYCLE

= How far do you want to pull or hoist the load? (Distance from A to B)

= How frequently and how fast do you want to pull or hoist the load?

32 WINCH SELECTION

Load = 10,000 lb20 Foot Long Ramp3.5 Foot RiseRolling Load

3.5 Ft. Rise20 Ft. Ramp = 17.5% of Grade

17.5% of Grade = .18 Pull/Weight

10,000 lb x .18 Pull/Weight = 1,800 lb Pull

INCLINE EXAMPLE PROBLEM

A B

WINCH

THEORETICAL THERMAL RATINGS TO REACH 250° F 9 — WORM GEAR MODELS

WINCH SELECTION 33

MO

DEL

1K1.

5K2K

3K4K

5K6K

8K10

K12

K15

K18

K20

K25

K30

K35

K40

K45

K50

K60

K70

K80

K90

K10

0K15

0K

AMS3

750

460

330

210

140

110

9060

50AM

SU3

750

460

330

210

140

110

9060

50AL

U2

Con

t.57

041

026

018

014

011

080

60AM

GU

5C

ont.

1,18

084

053

037

029

023

016

013

010

080

6050

ALG

U2

Con

t.89

063

040

028

021

017

012

010

080

AMU

7C

ont.

1,18

084

053

037

029

023

016

130

100

8060

5050

AMS7

Con

t.1,

530

1,09

068

047

037

030

021

016

013

010

080

70AM

S10

Con

t.C

ont.

1,55

098

068

053

042

030

023

019

014

012

010

080

60AM

SU10

Con

t.C

ont.

1,55

098

068

053

042

030

023

019

014

012

010

080

60AM

SU12

Con

t.C

ont.

Con

t.1,

200

830

6 40

520

370

290

230

180

140

130

100

8070

AMS2

0C

ont.

Con

t.C

ont.

1,56

01,

080

840

670

480

370

300

230

190

160

130

100

9070

60M

S30

Con

t.C

ont.

Con

t.1,

890

1,31

01,

020

820

590

450

360

280

230

200

150

120

100

9080

7060

MS5

0C

ont.

Con

t.C

ont.

Con

t.C

ont.

Con

t.C

ont.

1,04

080

065

049

040

036

028

022

019

016

014

012

010

080

7060

50W

150

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

*WA

RNIN

G: D

o no

t ope

rate

win

ch in

this

cate

gory

. Dam

age

to th

e ge

arse

t will

occ

ur.

MU

8A50

040

027

517

012

090

7540

Leng

th o

f pul

l in

feet

to 2

50º F

. reg

ardl

ess

of s

peed

or l

ayer

(pou

nds

pull)

WINCH

WORM GEAR VS PLANETARY RM GEAR VS PLANETARY

WORM GEAR VS PLANETARY EFFICIENCY

40%—50% EFFICIENT 90%—98% EFFICIENT

10 HP

INPUT

10 HP

INPUT5 HP

HEAT

0.5 HP

HEAT

5 HP WORK

9.5 HP WORK

34 WINCH SELECTION

WINCH

For the same load and line speed, a worm gear winch will require approximately twice the input horsepower as a planetary hoist.

WORM GEAR VS PLANETARY EFFICIENCY

12,000 LB Hydraulic Winches

Worm Gear Planetary AHSU3–10F–096 PD12C–29064–02

GEAR SET COMPARISON

WORM GEAR PLANETARY

ADVANTAGESSelf Locking High Efficiency

Simple / Reliable Continuous Duty Cycle

Lower Cost High Line Speeds

DISADVANTAGESLow Efficiency Complex Brake

Limited Duty Cycle Higher Cost

Limited Line Speed Higher Operator Skill

WAHS A

WINCH SELECTION 35

WINCH

LINE SPEED BY LAYER

LINE PULL BY LAYER

36 WINCH SELECTION

5.16 in.

6.28 in.61,875 lb in. TORQUE

5.156 in.= 12,000 lb

61,875 lb in. TORQUE

6.281 in.= 9,850 lb

1st Layer

12,000 lb

250 fpm

3rd Layer

9,850 lb

305 fpm

WINCH

WINCH PERFORMANCE BY LAYER

DRUM SIZE REQUIREMENTS

WORM GEAR

Small barrel diameter

Limited rope storage

BARREL DIAMETER (D/d)

PLANETARY

Large barrel diameter

Additional rope storage

Where

D = Drum Diameter

d = Rope Diameter

SAE D/d Standard for RECOVERY WINCH: 8:1

example:

ANSI D/d Standard for HOISTS 17:1

example:

WINCH SELECTION 37

4.0 in. drum

5.0 in. wire rope= 8:1

Layer Line Pull (lb) Line Speed (fpm) Rope Capacity (ft)

1 12,000 250 65

2 10,820 277 138

3 9,850 305 218

4 9,040 332 305

5 8,360 360 399

PD12C-29064-02 2700 psi @ 80 gpm (9/16 in. Wire Rope)

8.5 in. drum

5.0 in. wire rope= 17:1

WINCH

INTERACTIVE APPLICATION CHECKLIST

PACCAR WINCH LIT2238, Customer Application Checklist, is useful for gathering customer information.

An interactive version of this form is accessible via the PACCAR WINCH intranet and Note ‘Reset’ and ‘Print’ buttons at bottom. Form may also be configured to generate and save an XML file of entered data.

If desired, the next page may be reproduced and used.

38 WINCH SELECTION

3/4

X

WINCH

WINCH

MOTOR TYPES

FIXED-DISPLACEMENT MOTORS

VARIABLE-DISPLACEMENT MOTORS

• Gear

• Piston

• Geroter

• Vane

40 WINCH SELECTION

GEAR VANE

GEROTOR AXIAL PISTON

BENT AXIS PISTON

SWASH PLATE PISTON

WINCH

GEAR MOTOR OPERATION

• Two teeth react to high pressure and rotate the gears.• Pressure in mesh zone acts on one tooth.• Trapped pressure does not affect torque.• Only two teeth have tank pressure opposing rotation.

GEAR MOTOR STARTING EFFICIENCY COMPARISON

WINCH SELECTION 41

STANDARD Tooth Form MODIFIED Tooth Form

85% AVG

70% MIN

88% AVG

70% MIN

83% AVG

600 MINIMUM SMOOTH OPERATING RPM 600

WINCH

GEAR MOTOR

• Low cost• High horsepower for size

• High horsepower for size• High line speeds• High starting efficiency (75–85%)• Low speed operation (250–400 rpm)

• Poor low speed operation (50–600 rpm)• Poor starting efficiency (75–85%)• Noise at high rpm

• Noise at high rpm• High speed efficiency loss

STANDARD Tooth Form MODIFIED Tooth Form

PISTON MOTOR

• Highest horsepower for size• Wide speed range (50 to 4000+ rpm)• Quieter operation• High volumetric efficiency• High pressure capability• High starting efficiency

• Higher cost• Dirt sensitive

ADVANTAGES DISDVANTAGES

42 WINCH SELECTION

STANDARD Tooth Form MODIFIED Tooth Form

ADVANTAGES

DISADVANTAGES

WINCH

GEROLER MOTOR

• Low speed operation

• Low to moderate cost

• Good volumetric efficiency (90–96%)

• Moderate-to-high starting efficiency (70–80%)

• Small “envelope”

• Limited flow capacity

• Wide range in static & dynamic efficiency

• Moderate noise

ADVANTAGES DISDVANTAGES

WINCH SELECTION 43

WINCH

VANE MOTOR

• Quiet operation

• Small “envelope”

• Higher cost

• Low starting efficiency

• Sensitive to shock loading

• Dirt sensitive

ADVANTAGES DISDVANTAGES

44 WINCH SELECTION

Fixed Displacement Variable Displacement

WINCH

BASIC HYDRAULIC SCHEMATIC, SINGLE-SPEED MOTOR

WINCH SELECTION 45

WINCH MOTOR

BRAKE

VALVE

WINCH

BRAKE

WINCH ASSY

W/BRAKE VALVE

& STATIC BRAKE

CONTROL

VALVE

PUMP

WINCH

BASIC HYDRAULIC SCHEMATIC, TWO-SPEED MOTOR

46 WINCH SELECTION

WINCH MOTOR

BRAKE

VALVE

WINCH

BRAKE

WINCH ASSY

W/BRAKE VALVE

& STATIC BRAKE

CONTROL

VALVE

TWO-SPEED

SELECTORVALVE

PUMP

WINCH

BRAKE TYPES

• Static (Braden)

• Dynamic (Gearmatic)

• Brake valve (Braden)

• Band brake

STATIC BRAKE

WINCH SELECTION 47

STATIC BRAKE

MOTOR

PUMP

Low Pressure

TO TANK

Medium Pressure High Pressure

WINCH

BASIC HYDRAULIC SCHEMATIC, DUAL-SPEED MOTOR

HEAT LOAD

• Dynamic brake

- Winch housing

- Hydraulic system

• Brake valve with static brake

- Hydraulic system

• Band brake

- Atmosphere

- Poor load control

48 WINCH SELECTION

Low Pressure Medium Pressure High Pressure

MOTOR

DYNAMIC BRAKE

WINCH

GEAR RATIO SELECTION

• Smooth operation

• Good low-speed operation

• Adapts well to low-horsepower systems

• Can adapt to smaller, low-cost motors

• Limited high-speed operation

• Limited horsepower transmission

Advantages Disdvantages

WINCH SELECTION 49

HIGH REDUCTION (example: 60:1)

• High line speed

• High horsepower transmission

• Reduced noise in some applications

• Poor low-speed performance

• Sacrifice of some smoothness of operation

• Requires larger, more expensive motors

Advantages Disdvantages

LOW REDUCTION (example: 20:1)

WINCH

WINCH APPLICATION

• 1st-layer line pull

• 1st-layer line speed

• Wire rope diameter

• Wire rope storage capacity

Information required

APPLICATION EXAMPLE

A truck crane has a 16–ton hook load on four parts of line. Wire rope diameter is .50 inches

and 400 feet of storage is required. Desired hook speed minimum is 42 fpm. Horsepower available

is 100 hp.

Make a winch selection from this information.

Horsepower formulas

Mechanical horsepower

Winch load

Winch line speed

Overall winch performance

HORSEPOWER (HYD) =

HORSEPOWER (MECH) =LINE PULL x LINE SPEED

33,000 lb-ft/minute x WINCH EFFICIENCY

HORSEPOWER =

HORSEPOWER =16 tons x 2,000 lb/ton x 42 ft/min

33,000 lb-ft/min x 0.65 EFFICIENCY

MECHANICAL HORSEPOWER

16 tons x 2,000 lb/ton x 0.275 SHEAVE EFFICIENCY = 8,800 lb LINE PULL REQUIRED AT WINCH

42 fpm AT HOOK X 4 PARTS OF LINE = 168 fpm AT WINCH

LINE PULL = 8,800 lb

LINE SPEED = 168 fpm

• Pressure (psi)

• Flow (gpm)

50 WINCH SELECTION

LOAD (lb) x SPEED (fpm)

33,000 x WINCH EFFICIENCY

PRESSURE x FLOW

1714 x WINCH EFFICIENCY

WINCH

STATIC VS. DYNAMIC

Torque to start rotation (start to lift

a suspended load)

Torque to continue rotation

(keep a load moving once started)

Static efficiency Dynamic efficiency

• 1 to 1.5 x pump flow

• De-aeration

• Heat dissipation

Reservoir sizing and design

HYDRAULIC CONSIDERATIONS

• Reduces working pressure

• Leads to shaft seal failure

• Winch brake malfunction

Excessive backpressure

• Brake valve pilot orifice plugged or loose

• Brake cylinder seal defective

• Damaged brake will not release

Load cannot be lowered smoothly or lowered at all

TROUBLESHOOTING

• Brake cylinder seal defective

• Motor shaft seal failure

Oil leaks from vent plug

• Excessive back pressure

• Worn or damaged brake discs

• Brake clutch worn and slipping

Brake will not hold the load in neutral

• Mounting surface causing binding

• Relief valve set too low or needs repair

• Hoisting rated load on top layer

• Rigged improperly

Winch will not hold hoist rated load

WINCH SELECTION 51

WINCH

TROUBLESHOOTING (continued)

• Mounting surface binding the winch

• Heat exchanger blocked

• Reservoir level

• Relief valve set too low

• Poor pump efficiency

Winch runs hot

• Relief valve set too low

• Oil flow to motor too low

• Operator error or improper control valve

• Winch not mounted properly

Winch “chatters” when hoisting

• Improper fleet angle

• Mounting off center

• Wrong rope lay

• Wire rope taken set (overload)

Spooling problems

52 WINCH SELECTION

WINCH

WINCH SELECTION 53

WINCH

TYPICAL APPLICATIONS

• Tilt Deck Car Carriers

• Wreckers/Tow Trucks

• Utility O.E.M. Products & Add-On Equipment

• Underground Cable Pulling

• Oilfield “Hot Shot” Vehicles

• Oilfield Rig Moving Vehicles

• Pipeline Construction

• Drilling/Work-Over Rigs

• Refuse Hauling

• Roll-Off Hauling

• Machinery Moving & Rigging

• Railroad Car Moving

• Boat Hauling Trucks

• House Moving Vehicles

• Highway Maintenance Vehicles

• Logging/Forestry

• Trailers

• Military Recovery Vehicles

• General Construction

MAJOR MARKETS

• Wrecker

• Car Carrier

• Logging

• Forestry

• Truck Crane

• Mobile Crane

• Oilfield

• Pipeline

• Military

• Machinery Moving & Rigging

• Construction

• Trailer

• General Hydraulic

• Refuse

• Utility

• Compaction

• Drill Support

• General Truck

54 RECOVERY WINCHES

WINCH

RECOVERY WINCHES 55

TYPES OF RECOVERY PRODUCTS

• Low-Mount (8,000 - 35,000 lb Line Pull)

• Upright (10,000 - 150,000 lb Line Pull)

Worm Gear Units

Planetary Recovery Units

• BG25R (25,000 lb Line Pull)

• Special Purpose Products (Various Ratings)

• H20R & H35R (20,000 - 35,000 lb Line Pull)

• Oilfield Planetary Recovery Winches

Low Mount

WORM GEAR RECOVERY WINCHES

Upright

Model Line Pull

lb kg

MU8/HU8 8,000 3,636

ALU2/AHU2 10,000 4,545

AMSU3/AHSU3 10,000 4,545

ALGU2/AHGU2 12,000 5,454

AMU7/AHU7 20,000 9,090

AMGU5/AHGU5 20,000 9,090

AMSU10/AHSU10 30,000 13,636

WINCH

WORM GEAR RECOVERY WINCH COMPONENTS

Worm GearHousing

Drum Shaft

Worm Brake

Drum Band Brake*

Clutch**

Bearing Leg

ShifterFork

Base Angle

* Avoids drum overrun and cable birdnesting.** Negative draft angle resists disengaging under load.

Dr

Be

Worm Gear

WORM GEAR RECOVERY WINCH OPTIONS

• Mechanical Drive

• Hydraulic Motor Drive

• Low Mount

• Upright

• Band Brake

• Remote Controlled Clutch and/or Band Brake

• Extension Shaft (Single or Double)

• Left or Right Assembly

• Left or Right Hand Gear Set

56 RECOVERY WINCHES

WINCH

Model First-layer Line Pull Line Speed Rope Capacity

lb kg fpm mpm ft m

HP35A 35,000 15,909 53 16 26 8

HP50B 50,000 22,727 39 12 37 11

HP65A 68,500 31,070 28 9 47 14

HP75A 75,000 34,090 26 8 43 13

HP80A 80,000 38,260 27 10 52 16

HP100B 100,000 45,360 52 16 47 14

HP125B 125,000 56,695 46 14 47 14

HP130A 130,000 59,091 21 6 42 13

OILFIELD PLANETARY RECOVERY WINCHES

RECOVERY WINCHES 57

WINCH

MECHANICAL DRIVE vs. HYDRAULIC DRIVE

• Simple Design & Service• Simple Operation• Greater Versatility, Power, & Speed• Overload Protection• High Efficiency• Power Beyond Capability

• Semi-skilled Operation• Loss of Efficiency• No Overload Protection• Higher Service Skill Required• Higher Maintenance• Higher Initial Cost

Advantages Disadvantages

Mechanical Drive Hydraulic Drive

MECHANICAL and HYDRAULIC DRIVES

HYDRAULIC MOTOR ADAPTER

Adaapts hydraulic motor to existing mechanical drive winch

58 RECOVERY WINCHES

WINCH

RECOVERY WINCHES – RIGHT-HAND vs. LEFT-HAND

59

LEFT-HAND ASSEMBLY

All views are of HOUSING side of winch. Assume clockwise rotation of the input shaft.

Drum Rotation

Drum Rotation

Drum Rotation

Drum Rotation

Left-Hand Gear Set

Right-Hand Gear Set

Left-Hand Gear Set

Right-Hand Gear Set

RIGHT-HAND ASSEMBLY

Left Side of Truck

Right Side of Truck

Drum Rotation

Drum Rotation

Drum Rotation Drum

Rotation

Left-Hand Gear Set

Right-Hand Gear Set

Left-Hand Gear Set

Right-Hand Gear Set

WINCH

RECOVERY WINCHES – RIGHT-HAND vs. LEFT-HAND (continued)

LEFT-HAND ASSEMBLY

RIGHT-HAND ASSEMBLY

Low or Front Mount Winch Upright or Bed Mount Winch

Input

Input Input

Input

Passenger Side

Driver Side

Low Mount as Bumper Winch

Upright Mounted in Bed

Wire Rope

Wire Rope

<VIEW

60 RECOVERY WINCHES

WINCH

RECOVERY WINCHES – FRONT MOUNT vs. REAR MOUNT

Front Mount, Right-hand Assembly Rear Mount, Right and Left-hand Assemblies

RECOVERY WINCHES 61

WINCH

TYPICAL WORM GEAR RECOVERY WINCH INSTALLATIONS

Front Mount Terminology and Conventions

Input shaft or hydraulic motor toward the truck cab.

Right or left-hand assembly indicates which side of the drum the gear housing is located

(determined while sitting in the drivers position or standing behind the vehicle).

Extension shaft toward the curb side.

Haul-in is over the top of the cable drum (overwound).

Right or left hand gear cut determines the direction the input shaft will turn to rotate the

drum in the correct haul-in direction.

Right-hand assembly and right hand gear cut - input shaft rotates counter-clockwise to haul-in (overwound).

Right-hand assembly and left hand gear cut - input shaft rotates clockwise to haul-in (overwound).

Left-hand assembly and right hand gear cut – input shaft rotates counter-clockwise to haul-in (overwound).

Left-hand assembly and left hand gear cut – input shaft rotates clockwise to haul-in (overwound).

Rear Mount Terminology and Conventions

Input shaft or hydraulic motor toward the truck cab.

Right or left-hand assembly indicates which side of the drum the gear housing is located

(determined while sitting in the drivers position or standing behind the vehicle).

Haul-in is over the top of the cable drum (overwound).

Right or left hand gear cut determines the direction the input shaft will turn to rotate the

drum in the correct haul-in direction.

Left-hand assembly and right hand gear cut – input shaft rotates counter-clockwise to haul-in (overwound).

Left-hand assembly and left hand gear cut – input shaft rotates clockwise to haul-in (overwound).

Right-hand assembly and right hand gear cut – input shaft rotates counter-clockwise to haul-in (overwound).

Right-hand assembly and left hand gear cut – input shaft rotates clockwise to haul-in (overwound).

NOTE: Worm gear winches may be operated where haul-in is under the bottom of the drum

(underwound). In these cases, the brake must be “set for underwind”. This should be specified at the time of order or may be

done in the field. Contact the factory for additional information.

62 RECOVERY WINCHES

WINCH

A B S U 3 - 10 F EB R RA

Left Hand AssemblyRight Hand Assembly

Left Hand Gear CutRight Hand Gear Cut

Extension Shaft(One Side Only)Extension Shaft

Special(Both Sides)

Front or Bumper MountIs Most Common Install

10" Normal Drum Barrel

Designed & TestedTo SAE J706A

Convertible BaseElectric DriveHydraulic Drive

Mechanical DriveLightweight Housing

Revised Gear ProfileSpacer Added BetweenWorm Gear & Housing

Underslung or Low Mount

Basic Winch Model

A

CEHLM

GS

U

3

-

----

--

-

-

--

--

-

-

-

-

-

RALA

RL

EB

EEB

SPL

F

10Length Between Flanges

MODEL CODE – LOW MOUNT WORM GEAR

MODEL CODE – UPRIGHT WORM GEAR

Low Mount Upright

RECOVERY WINCHES 63

WINCH

SPECIAL-PURPOSE RECOVERY PRODUCTS

HUP-12A

PD35A

PD18D

PLANETARY RECOVERY WINCHES/UNIVERSAL BUMPERS

PD18C

PD18D

64 RECOVERY WINCHES

WINCH

SPECIAL-PURPOSE RECOVERY PRODUCTS

BD12A DIGGER DRIVE

WR30 WORM GEAR SWING DRIVE

SD40 SWING DRIVE

BP200B UNDERGROUND CABLE PULLING WINCH

PCD24B PLANETARY CAPSTAN DRIVE

RECOVERY WINCHES 65

WINCH

SPECIAL-PURPOSE RECOVERY PRODUCTS

Bumper Packages

• Winch and bumper assemblies tested in compliance with SAE J706 to twice the rated load

• Cable rollers for full load capacity up to 45º from center

• Optional built-in toolbox, street or curbside extension shafts, and two-speed hydraulic motors

• Modular construction for easy maintenance and installation

• Capstan-only bumper packages

Capstan and Capstan Drives

• Ductile iron capstan

• Lighter aluminum capstan for line applications

Extension Shaft Winches

• Double extension shaft on some models

• Mechanical or hydraulic drive

• Two-speed hydraulic motors

• Wire rope roller assembly

Speed Reducers and Swing Drives

• High output torque

• Slow to medium speeds

• Precise control

• Smooth operation

Model BP200B

• Specifically designed for underground cable pulling applications

• Diamond screw level wind system

• Adjustable-drag free spool & two-speed hydraulic motor

66 RECOVERY WINCHES

WINCH

WINCH MODEL

LINE PULL

POUNDS

MAX. LINE

SPEED FPM

MAX. INPUT SPEED

RPM

TORQUE REQUIRED

LB IN STATIC

TORQUE REQUIRED

LB IN DYNAMIC

WINCH MODEL

LINE PULL

POUNDS

MAX. LINE

SPEED FPM

MAX. INPUT SPEED

RPM

10,000 16 400 2,770 1,9908,000 20 500 2,220 1,6006,000 26 660 1,665 1,2004,000 40 1,000 1,110 8002,000 58 1,440 555 400

No Load 80 2,000 - - 20,000 28 480 5,900 4,50016,000 35 600 4,720 3,60012,000 47 800 3,540 2,7008,000 71 12,000 2,360 1,8005,000 89 1,540 1,480 1,130

No Load 102 1,740 - -

10,000 16 400 2,770 1,990

30,000 18 330 8,070 6,140

8,000 20 5,000 2,220 1,590

25,000 21 400 6,725 5,120

6,000 26 670 1,660 1,190

20,000 27 500 5,380 4,090

4,000 40 1,000 1,110 800

15,000 35 660 4,035 3,070

2,000 58 1,440 550 400

10,000 53 910 2,690 2,050

No Load 80 2,000 - -

5,000 68 1,300 1,345 1,020

12,000 19 580 1,950 1,500

No Load 97 1,850 - -

10,000 23 700 1,625 1,250

45,000 18 330 13,300 9,980

8,000 29 870 1,300 1,000

35,000 23 420 10,340 7,760

6,000 39 1,160 975 750

25,000 32 590 7,390 5,540

4,000 52 1,550 650 500

15,000 54 990 4,430 3,330

2,000 72 2,200 325 250

10,000 79 1,130 2,960 2,220

No Load 72 2,200 - -

No Load 84 1,500 - -

20,000 19 480 3,950 3,000

100,000 12 180 35,160 27,000

15,000 25 640 2,960 2,250

80,000 15 220 28,130 21,600

10,000 38 960 1,980 1,500

60,000 20 300 21,100 16,200

5,000 60 1,540 990 750

40,000 29 440 14,060 10,800

No Load 79 2,000 - -

20,000 43 650 7,030 5,400

20,000 28 400 7,050 5,350

15,000 50 750 5,280 4,050

15,000 37 530 5,290 4,010

5,000 66 1,000 1,760 1,350

10,000 56 800 3,520 2,680

No Load 66 1,000 - -

5,000 88 1,280 1,760 1,340

150,000 15 300 35,066 27,400

No Load 140 2,000 - -

112,500 22 450 26,764 20,550

35,000 15 280

75,000 30 600 17,843 13,700

30,000 18 330

37,500 60 1,200 8,921 6,850

25,000 21 400

No Load 125 2,500 - -

20,000 27 50015,000 35 66010,000 53 9805,000 68 1,300

No Load 93 1,740

9,420 7,1638,070 6,1406,730 5,1105,380 4,0904,040 3,0702,690 2,0501,350 1,020

- -

ALGU2

AMU7

AMGU5

AMSU12

AMS20

MS50

W150A

LOW MOUNT WORM GEAR WINCHES

AMSU3

UPRIGHT WORM GEAR WINCHES

AMS3

AMS7

AMS10 AMSU10

TORQUE REQUIRED

LB IN STATIC

TORQUE REQUIRED

LB IN DYNAMIC

MAXIMUM LINE SPEED/TORQUE INFORMATION

(All line pulls & line speeds are for 1st layer of cable)

To convert lb line pull to kN,

multiply lb value by .004448.

To covert lb in. torque to Nm,

multiply lb in.value by .113

RECOVERY WINCHES 67

WINCH

MO

DEL

1K1.

5K2K

3K4K

5K6K

8K10

K12

K15

K18

K20

K25

K30

K35

K40

K45

K50

K60

K70

K80

K90

K10

0K15

0K

AMS3

750

460

330

210

140

110

9060

50AM

SU3

750

460

330

210

140

110

9060

50AL

U2

Con

t.57

041

026

018

014

011

080

60AM

GU

5C

ont.

1,18

084

053

037

029

023

016

013

010

080

6050

ALG

U2

Con

t.89

063

040

028

021

017

012

010

080

AMU

7C

ont.

1,18

084

053

037

029

023

016

130

100

8060

5050

AMS7

Con

t.1,

530

1,09

068

047

037

030

021

016

013

010

080

70AM

S10

Con

t.C

ont.

1,55

098

068

053

042

030

023

019

014

012

010

080

60AM

SU10

Con

t.C

ont.

1,55

098

068

053

042

030

023

019

014

012

010

080

60AM

SU12

Con

t.C

ont.

Con

t.1,

200

830

6 40

520

370

290

230

180

140

130

100

8070

AMS2

0C

ont.

Con

t.C

ont.

1,56

01,

080

840

670

480

370

300

230

190

160

130

100

9070

60M

S30

Con

t.C

ont.

Con

t.1,

890

1,31

01,

020

820

590

450

360

280

230

200

150

120

100

9080

7060

MS5

0C

ont.

Con

t.C

ont.

Con

t.C

ont.

Con

t.C

ont.

1,04

080

065

049

040

036

028

022

019

016

014

012

010

080

7060

50W

150

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

TBD

*WA

RNIN

G: D

o no

t ope

rate

win

ch in

this

cate

gory

. Dam

age

to th

e ge

arse

t will

occ

ur.

MU

8A50

040

027

517

012

090

7540

Leng

th o

f pul

l in

feet

to 2

50º F

. reg

ardl

ess

of s

peed

or l

ayer

(pou

nds

pull)

THEORETICAL THERMAL RATING (Intermittent Duty)

68 RECOVERY WINCHES

WINCH

THEORETICAL THERMAL RATING (Intermittent Duty)

LOW - MOUNT WORM GEAR WINCHES

1st LAYER LINE PULLBRADEN TULSA RAMSEY DP REMARKS

LB KG

8,000 3,630 MU8A 938 246 N/A Mech. Input

8,000 3,630 HU8A H938 H246 8GAAX3L1A Hyd. Mtr. Input

10,000 4,535 ALU2-10F 1060 400 N/A Mech. Input

10,000 4,535 AHU2 H1060 H400 10GHAAX3L1A Hyd. Mtr. Input

10,000 4,535 AMSU3-10F 1060 400 N/A Mech. Input

10,000 4,535 AHSU3-10F H1060 H400 10GHAAX3L1A Hyd. Mtr. Input

12,000 5,445 ALGU2-10F 1242 600 N/A Mech. Input

12,000 5,445 AHGU2-10F H1242 H600 12JAAX3L1H Hyd. Mtr. Input

20,000 9,070 AMU7-14F 12 700 N/A Mech. Input

20,000 9,070 AHU7-14F H12 H700 15UBEX3R3G Hyd. Mtr. Input

20,000 9,070 AMGU5-12F 18G 800 N/A Mech. Input

20,000 9,070 AHGU5-12F H18G H800 N/A Hyd. Mtr. Input

30,000 13,610 AMSU10-12F 24 930 N/A Mech. Input

30,000 13,610 AHSU10-12F H24 H930 30BBX3L1F Hyd. Mtr. Input

35,000 15,875 AMSU12-12F N/A 940 N/A Mech. Input

35,000 15,875 AHSU12P-12F N/A H940 N/A Hyd. Mtr. Input

RECOVERY WINCHES 69

WINCH

RECOVERY WINCH CROSS-REFERENCE LIST

UPRIGHT WORM GEAR WINCHES

1st LAYER LINE PULLBRADEN TULSA RAMSEY DP REMARKS

LB KG

10,000 4,535 AMS3-10 1138 R10 N/A Mech. Input

10,000 4,535 AHS3-10 H1138 HR10 N/A Hyd. Mtr. Input

20,000 9,070 AMS7-15 19 R20A N/A Mech. Input

20,000 9,070 AHS7-15 H19 HR20A 20BCX3L3G Hyd. Mtr. Input

20,000 9,070 AMS7-15A N/A N/A N/A Mech. Input

20,000 9,070 AHS7-15A N/A N/A N/A Hyd. Mtr. Input

20,000 9,070 AMS7-15B 23 R20 N/A Mech Input

20,000 9,070 AHS7-15B H23 HR20 N/A Hyd. Mtr. Input

30,000 13,610 AMS10-18 N/A R30A N/A Mech. Input

30,000 13,610 AHS10-18 N/A HR30A 30BBX3L1F Hyd. Mtr. Input

30,000 13,610 AMS10-18A N/A N/A N/A Mech. Input

30,000 13,610 AHS10-18A N/A N/A N/A Hyd. Mtr. Input

30,000 13,610 AMS10-18B 34 R30 N/A Mech. Input

30,000 13,610 AHS10-18B H34 HR30 N/A Hyd. Mtr. Input

45,000 20,410 AMS20-18B 64 R45 N/A Mech. Input

45,000 20,410 AHS20P-18B H64 HR45 N/A Hyd. Mtr. Input

60,000 27,215 MS30-20B 70 R65L N/A Mech. Input

60,000 27,215 HS30P-18B H70 HR65L 65AAX4L1D Hyd. Mtr. Input

100,000 45,360 MS50-20B 80 R100L N/A Mech. Input

100,000 45,360 HS50P-20B H80 HR100L 100BBX4L1D Hyd. Mtr. Input

70 RECOVERY WINCHES

WINCH

BRADEN GEARMATIC PLANETARY HOISTS

MODEL1st LAYER LINE PULL

LB KG

BG3B 3,000 1,363

BG4B 4,000 1,818

BG6B 6,000 2,727

BG8B 8,000 3,636

PD12C 12,000 5,454

PD15B 15,000 6,818

PD17A 17,000 7,727

PD21A 20,250 9,205

GH15B 15,000 6,818

GH30B 26,840 12,200

GH50B 44,000 20,000

CH165A 16,500 7,500

CH175B 17,500 7,954

CH210A 21,000 9,545

CH230B 23,000 10,454

CH280A 28,000 12,727

CH400B 40,000 18,181

PLANETARY HOISTS 71

WINCH

72 PLANETARY HOISTS

BRADEN GEARMATIC PLANETARY HOIST FEATURES

• High line-pull

• Patented Braden brake valves

• Anti-friction bearings throughout, with all parts

running in oil

• Easily adapted

• High-capacity brake

• Full-load wire rope anchors*

*API and other regulatory organizations specify keeping 5 wrap of wire rope on drum at all times.

• Gear ratios

• High-speed reverse

• Personnel handling (offshore cranes)

• Auxiliary Brake

• Ratchet and pawl

• Tension rollers

• Hydraulic motor

• Motor displacement

• High-pressure piston motors

• Low-flow motors

• Two-speed motors

• Drum options

• Various sizes

• Grooved drums

• Free fall

• Controlled (CF)

• Full-release (FF)

• Encoders

• Last-wrap and 3rd-wrap indicators

• EMM (Electronic Maintenance Module

BRADEN GEARMATIC PLANETARY HOIST OPTIONS

WINCH

Braden and Gearmatic Planetary Hoists are available in a wide variety of configurations with optional drums, gear ratios, and motor displacements to meet your requirements.

The configuration of each product may be determined by this typical model numbering system:

PD 12 C — FF — 41 V 039 — 02 G R — 1

POWERDRUM

MAXRATING

MODELSERIES

OPTION GEARRATIO

MOTORTYPE

MOTORSIZE*

DRUM CODE

DRUM AND BASE OPTIONS

CHARACTER DESIGNATION

PD POWER DRUM

12 MAXIMUM RATED LINE PULL CAPACITY, LB. (X 1,000)

C MODEL SERIES (DESIGN CHANGES)

FF FULL-RELEASE FREE FALL OPTION (CF = CONTROLLED FREE FALL)

41 TOTAL GEAR REDUCTION RATIO (THE PD12C IS AVAILABLE in 21:1, 29:1, 41:1, and 59:1 RATIOS)

V V=VARIABLE-SPEED PISTON MOTOR (P=FIXED-DISPLACEMENT PISTON MOTOR, NO LETTER=SINGLE OR TWO-SPEED GEAR MOTOR

039 HYDRAULIC MOTOR DISPLACEMENT, CU INCHES/REVOLUTION (033/024 INDICATES TWO-SPEED MOTOR–IN THIS CASE, EITHER 3.3 OR 2.4 CU. IN. MAY BE SELECTED

02 DRUM CODE (COMMON DRUM OPTIONS FOR MOST MODELS INCLUDE –01, –02, –04, –05, –06, –22, AND –25)

G GROOVED CABLE DRUM OPTION

R TENSION ROLLER OPTION

1 API 2C CERTIFICATION OPTION - PERMITS LIFTING & LOWERING OF PERSONNEL FOR OFFSHORE CRANE APPLICATIONS

OTHER OPTIONS

U UNDERWOUND CABLE DRUM OPTION

L LEFT-HAND BASE OPTION

P RATCHET AND PAWL OPTION

* WHERE NO MOTOR IS SPECIFIED, “000” OR SAE MOTOR SHAFT AND BOLT PATTERN (FOR EXAMPLE, “C4C” ) WILL BE PROVIDED

BRADEN GEARMATIC PLANETARY HOIST MODEL CODE

PLANETARY HOISTS 73

WINCH

74 PLANETARY HOISTS

BRADEN GEARMATIC PLANETARY HOIST COMPONENTS

SPRAGCLUTCH

BRAKEPISTON

BRAKEPLATES

BASE

HYDRAULICMOTOR

BRAKEVALVE

SECONDARYPLANET SET

PRIMARYPLANET SET

PRIMARYSUN GEAR

SECONDARYSUN GEAR

RING GEAR& DRUM

BRAKEPLATES

SPRAGCLUTCH

WINCH

PLANETARY HOISTS 75

BASIC OPERATION

PARKING

LOWERING

Static brake is fully applied by spring force. Sprag clutch is locked. Hydraulic motor is stationary - drum remains stationary.

Static brake is hydraulically released. Lowering speed is controlled by oil flow through brake valve and motor. Braking is done by brake valve, heat is absorbed into hydraulic system.

WINCH

76 PLANETARY HOISTS

BASIC OPERATION

HOISTING

STATIC BRAKE APPLIED WHILE HOISTING

UNIDIRECTIONAL CLUTCH

Free Direction Locked Up

Static conditions maintained

in brake pack during hoistingPositive locking when hoisting terminated

Static brake remains fully applied. Input sun gear rotates in “free” direction of sprag clutch.

HOIST HOLD

WINCH

PLANETARY HOISTS 77

BASIC HYDRAULIC CIRCUIT

For a more detailed description of hoisting and lowering operations, see Winch Selection Section, Basic Planetary Hoist Operation.

Static

Disc Brake

Winch

Assembly

to Tank

Brake

Valve

Motor

Control Valve

Pump

Oil In

WINCH

78 PLANETARY HOISTS

FEATURES

BRADEN PATENTED BRAKE VALVES

Full-load

AnchorAnti-friction Bearings Throughout High-capacity

Brake

High-effi ciency

Motor

EASILY SERVICED THROUGH MOTOR END

WINCH

PLANETARY HOISTS 79

NOTES

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