Compactor Overturns and Rollover Protective Structures

| |
CPWR - The Center for Construction Research and Training

Summary Statement

This study examined government investigation reports of work-related deaths and injuries in 1986- 2002 to learn the public health implications of a widespread lack of rollover protective structures and seatbelts on compactors.
April 2004


Photo courtesy North Carolina Department of Labor.

Acknowledgments

Nancy Calkins, Data Analyst, Caldwell, Idaho, was helpful in compiling data from the OSHA Web site used in this analysis. Resources from the Hazard Information Foundation, Inc., Sierra Vista, Arizona, assisted in identifying and describing some of the cases that were analyzed. In addition, Cok, Wheat, Brown, McGarry & Bidegaray, PLLP, Bozeman, Montana, provided discovery materials useful in designing the approach to this study. The North Carolina Department of Labor provided photographs used in this report's cover and elsewhere. The U.S. Department of Energy also provided one photograph used in this report.

Many federal OSHA offices provided copies of their inspection reports for this study. They include the following area offices: Albany, Atlanta East, Atlanta West, Austin, Avenel, Baton Rouge, Billings, Birmingham, Buffalo, Calumet City, Chicago North, Cincinnati, Cleveland, Columbus, Corpus Christi, Dallas, Erie, Fort Worth, Houston North, Houston South, Indianapolis, Jackson (Miss.), Little Rock, Lubbock, Madison (Wisc.), Manhattan, Oklahoma City, Peoria, Philadelphia, Phoenix, Denver, Portland (Ore.) , Syracuse, Toledo, Utica, and Wilkes-Barre. In addition, the following state programs provided copies of their investigation reports: Alaska, California, Indiana, Kentucky, Maryland, Minnesota, New York, North Carolina, Oregon, South Carolina, and Washington.

Abbreviations

CIMA Construction Industry Manufacturers Association
FACE Fatality Assessment and Control Evaluation
NIOSH National Institute for Occupational Safety and Health
OMB Office of Management and Budget
OSHA U.S. Occupational Safety and Health Administration
ROPS Rollover Protective Structure
SAE Society of Automotive Engineers

Contents

Summary
Background

    The Society of Automotive Engineers Recommended Practice
    Army Corps of Engineers Requirements
    Other Governmental Actions
    ROPS Effectiveness and Availability
    Types of Compactors
Research Methods
Machine, Environmental, and Human Factors
    Machine-Related Factors
    Environmental Factors
    Human Factors
Possible ROPS Design Defects
Seatbelt Effectiveness
OSHA Enforcement
Discussion and Recommendations
References

Tables
1. Rollover protective structures available from Saf-T-Cab, Inc., for compactors, 1976
2. 58 compactor-overturn cases analyzed, with associated characteristics
3. Use of the Haddon matrix to analyze the risk factors related to a compactor overturn injury

Annexes
A. Figures 1 - 8
B. The Usefulness of OSHA and NIOSH Reports for This Research

Summary

Compactors - also known as steamrollers - are mobile vehicles used to increase the density of soil and roadways and to seal and smooth asphalt surfaces. Compactors tend to overturn during some operations, thus putting their operators at risk. A rollover protective structure (ROPS) is a part of a compactor or other heavy equipment designed to protect an operator from a crushing injury in the event of a rollover. Particularly with seatbelt use, ROPSs have been shown to save lives.

In 1971, the Employment Standards Administration, part of the U.S. Department of Labor, drafted the following language under the Construction Safety Act: "The promulgation of specific standards for rollover protective structures for compactors...is reserved pending consideration of standards currently being developed." The newly established U.S. Occupational Safety and Health Administration (OSHA) adopted the language in its rules the following year. Although consensus standards were developed soon thereafter (by the Society of Automotive Engineers), the OSHA rules were never changed to require ROPS on compactors.

This study examined government investigation reports of work-related deaths and injuries in 1986- 2002 to learn the public health implications of a widespread lack of ROPS and seatbelts on compactors. Among the findings:

  • Operators and drivers have been killed or seriously injured as a result of a lack of ROPSs and seatbelts on compactors. Compactors with ROPSs were found to restrict overturns to 90°, whereas compactors without ROPSs were found to average more than two revolutions per event.
  • Of 58 compactor overturns examined, nearly half involved the smooth-drum type of compactor, as compared with the steel-drum type and the pad-foot type.
  • The highest overturn hazard locations were along roadway or embankment edges. The next-mosthazardous situation was runaway machines, typically down slopes.
  • Compacting of soil appears to have been more hazardous than other compacting operations, especially for the smooth-drum and pad-foot compactors. Soil edges were a hazard, as were soft soil pockets that can drop under the weight of a unit.
  • The stability of a compactor was affected by maintaining vibration while stationary, turning away from a slope with articulated steering, or using water as ballast, because water can slosh from side to side in the water tanks.
  • Loading or unloading compactors on trailers posed potential overturn hazards; the hazards were caused by skidding on inclines by smooth-drum compactors, using wood blocks or planks as a ramp, or loading a narrow unit that lacks the width to reach both loading ramps.
  • Failure to use a seatbelt when a compactor had an ROPS was a hazard. Some seatbelts were inoperable and some had not been installed on new compactors. However, using a seatbelt when there was no ROPS resulted in a death also.
  • When an ROPS was reported as the part of a compactor that pinned or crushed an operator, in five instances where the reports were detailed, it was an overhead canopy that struck the operator.
  • An OSHA directive in 1998 established that the lack of an ROPS and seatbelt on compactors is a hazard enforceable under the OSHA General Duty Clause.
Compactors, or steamrollers, are used to increase the density of embankments and roadways and to level and seal asphalt pavement. They have been indispensable in the construction of roads, streets, air strips, earthworks, parking lots, dams, levees, and railroad beds. Compaction is applied using pressure, kneading, impact, and vibration (Church 1981; Galion 1959). A rollover protective structure (ROPS) is a part of a compactor or other heavy equipment designed to protect an operator from a crushing injury in the event of a rollover.

Although ROPSs likely would save lives and prevent serious injuries of compactor operators, particularly with seatbelt use, the U.S. Occupational Safety and Health Administration (OSHA) has not promulgated a standard that would require the devices - and seatbelts - on compactors. The expectation for such a standard was based on a 1972 construction-equipment ROPS standard, which excluded compactors yet stated:

    The promulgation of specific standards for rollover protective structures for compactors...is reserved pending consideration of standards currently being developed (29CFR1926.1000, p.327 ).

The following report uses government reports of work-related injuries and deaths to describe the hazards of construction work using compactors without ROPSs and with/without the added factor of seatbelt use.

Several questions drove the analysis. First, was a suggestion by Brickman and Barnett (1999) that ROPS present more of a hazard in an overturn than if they are not installed. Another is the question of the general effectiveness of ROPSs for compactors. A third issue has been the added value of seatbelt use. Fourth, what have been OSHA and industry responses thus far to the problem.

Background

Decades ago, studies identified unstable embankment foundations as unable to support the weight of a compactor (Ritter and Paquette 1960, p. 374) and operating compactors at the edge of high fills as dangerous (Baker 1957). The Naval Training Command wrote that a "roller is easier to overturn than most other equipment," adding that rolling a shoulder presents a risk of an overturn into a ditch (1973, p. 375).

Some early statistics indicated a pernicious problem related to compactor overturns. California reported 14 compactor overturn-related deaths between 1965 and 1972 (White 1973). Woodward Associates' 1974 analysis reported 13 compactor overturn-related injuries during 1971 and 1972 in California.

The Construction Industry Manufacturers Association, CIMA, alerted the public to the hazard of operating compactors on slopes in a booklet (1978): "the danger of sliding and/or tipping on steep slopes is always present regardless of how heavy or stable your machine may appear to be." The booklet identified the potential of caving edges also. CIMA recommended always wearing a seatbelt on a compactor that was equipped with an ROPS; avoiding operating a machine too close to an overhang, deep ditch, or hole; and always traveling slowly over rough terrain and hillsides.

Between 1950 and 1970, two ROPS standards emerged that affected construction equipment: a Society of Automotive Engineers recommended practice and U.S. Army Corps of Engineers design criteria. Besides the Army Corps move, several government entities established ROPS standards: the states of California and Oregon, and the U.S. Departments of Agriculture (Forest Service) and Interior. In addition, several state highway departments specified ROPSs in purchase orders for construction and highway maintenance equipment.

The Society of Automotive Engineers Recommended Practice

In 1966, the Society of Automotive Engineers (SAE) began developing recommended practices for protective devices for mobile construction and earthmoving equipment. The SAE developed a standard to allow an ROPS to yield through deformation and absorb some of the energy of a rollover so as to lessen the violence of the overturn. The structure was designed to deform through a plastic range that would neither break nor intrude into the operator's protective zone (National Safety Council 1976). It was not until 1975, however, that the SAE issued a recommended practice for ROPSs on compactors, classifying them as earthmoving construction equipment. In 1981, the SAE reclassified compactors as other than earthmoving machines (SAE 1975, 1981), thus removing compactors from a classification that included bulldozers, scrapers, and graders.

Army Corps of Engineers Requirements

The Corps of Engineers began requiring heavy canopies as rollover protection on crawler tractors in 1960. In 1967, the Corps issued its Safety-General Requirements, which required steel canopies and seatbelts on any construction equipment that presented a construction hazard, including compactors (Article 18.A.20). The manual required a canopy design that would support twice the weight of the machine and provide at least a 52-inch clearance from the machine's deck to the roof of the canopy.

In 1970, the Corps issued a nationwide circular that required ROPSs to be used on construction projects; plus, whenever ROPSs were required for any part of a project, they were to be required for the entire project (Murphy 1970). The North Pacific Division of the Corps then issued a circular to establish a uniform policy for accepting ROPSs installed on construction equipment, which included rollers and compactors. Furthermore, because of the rough terrain on nearly all construction work and the potential number of rollovers in the Northwest, the Division required ROPSs unless specifically waived by the District Engineer (Zink 1970). In 1972, the Corps specified ROPSs on rollers and compactors (Woodward Associates 1974).

Other Governmental Actions

Pursuant to the Construction Safety Act of 1969, the U.S. Department of Labor announced a notice of proposed rulemaking in 1971 to add Safety and Health Regulations for Construction to the Code of Federal Regulations (Federal Register, Feb. 2, 36:22). The proposed regulations included compactors as earthmoving equipment and required ROPSs to conform to SAE minimumperformance criteria. The final rule, published in 1971, read, "The promulgation of specific rules for compactors and rubber-tired "skid steer" equipment is reserved pending standards currently being developed." (Federal Register, April 17, 36:75)

With the passage of the Occupational Safety and Health Act (OSHAct), which took effect on April 29, 1971, publication of the construction rules in the Code of Federal Regulations was delayed until 1972, when OSHA published a rule for ROPSs that exempted compactors, as well (Federal Register, 37:66, April 5).

In 1972, however, OSHA notified the public that if a standard was reserved with a delayed effective date, the working conditions would be subject to the General Duty Clause, Section 5(a)(1) of the Occupational Safety and Health Act. Under this clause, OSHA may cite an employer for failing to provide a place of employment free from recognized hazards that are likely to cause death or serious physical harm. OSHA named the lack of an ROPS as such a hazard in certain situations, but also named other factors, such as machine speed, nature of the soil, the grade of the terrain, falling-object risk, and training.

In 1976, California issued safety regulations that required ROPSs and seatbelts on rollers and compactors (Division of Industrial Safety 1976).

The Office of Management and Budget issued its Regulatory Program of the U.S. Government for April 1, 1985 to March 31, 1986. In the document, OSHA stated its intention to amend the current ROPS standard so as to eliminate gaps in coverage and specifically named the problem of deaths associated with compactors. OSHA stated that the installation of ROPSs and seatbelts on compactors could have prevented deaths, but said seatbelts were not required in 1971 because of the unavailability of technology (OMB 1985) (see below).

In the meantime, Miles (1986), of the OSHA Directorate of Field Operations, specified that the General Duty Clause could be cited when compactors were used in a manner that posed a recognized hazard to the operator.

In preparation for the ROPS rule, OSHA established a task force to develop requirements for compactors (Richter 1987). The task force recommended that compactors be equipped with ROPSs, as specified in SAE Recommended Practice J1040 (1986); that ROPS be designed to support at least two times the weight applied at the point of impact; and seat belts meet SAE J386. The industry expected OSHA to require ROPSs on all compactors in late 1988, and at least one company planned to offer ROPSs on all of its compaction equipment as standard equipment (Richter 1987). OSHA never promulgated the rule.

In 1998, OSHA issued a guideline that recognized equipment rollover as a hazard under the General Duty clause. OSHA recognized that ROPSs and seatbelts were feasible to reduce this hazard (Swanson 1998).

ROPS Effectiveness and Availability

Protective canopies for crawler tractors and anti-roll bars for agricultural tractors had emerged in the 1950s (Myers 2000). The first patent for an agricultural tractor protective frame was issued in 1954, and the first use of an anti-roll bar on roadside mowing tractors was in 1958 (Skromme 1986). Construction equipment canopies were available from several manufacturers in 1958 (MacCollum 1958). Protective structures were demonstrated to be effective as early as 1956 by the U.S. Forest Service in overturn tests conducted on crawler tractors (E&R 1956). Anti-roll bars on mowing tractors were designed to prevent a roll beyond 90°, which proved to significantly reduce deaths from this type of work. These tractors experience slope exposures similar to the edge work of compactors.

Starting in June 1973, Woodward Associates (1974) conducted a study for OSHA on the feasibility of retrofitting ROPSs on construction equipment, excluding compactors. Nonetheless, fatality data analyzed from California and the Corps of Engineers included compactors. The study concluded that ROPSs clearly reduced injuries and deaths related to vehicle rollovers. Moreover, the study found that ROPS designs were available for most heavy-construction equipment manufactured after 1960 and that rollovers occurred in all types of terrain and to all types of vehicles.

In Sweden, the use of ROPSs on agricultural tractors has proven to be effective in reducing death rates from 17 per 100,000 tractors in 1960 to 0.3 per 100,000 tractors, with a 98% compliance in 1990; using seatbelts can save additional lives (Myers 2000). In addition, ROPS have proven to be life-savers where they have been required on mining (Woodward 1980) and construction equipment (MacCollum 1984).

In 1976, Saf-T-Cab , an ROPS manufacturer, listed available rollover protective structures for virtually all compactors manufactured in the United States based on the Corps of Engineers design criteria (Woodward Associates 1976) ( table 1).

Table 1. Rollover protective structures available from Saf-T-Cab, Inc., for compactors, 1976
Make Model
Bros SP, SPV 370, SPV 725, SPV 735, SPV 845, SP 2800, SP 3000, SP 3500, SP 6000, SP 10000
Caterpillar* 814, 815, 824, 825, 830, 834, 835
Clark-Michigan RW-140, RW-181
Galion 3-5, 5-8, 8-12, and 10-14 Ton Tandem; 10-12 and 12-14 Ton 3-Wheel; and 9-T-15 9-Wheel
Hyster C-350A, C-451A, C-450, C-500, C-530, C-550
Ingersoll Rand SP 42, SP 54
Ingram 3-5, 5-8, 8-12, 10-14 Ton; 8, 10, and 14 Ton 3-wheel; 9-2800P, 9-3400-P, 11-2700, and 13-2300
Koehring 60, 100, 140, K-550
Raygo/Wagner 2-36, 45, 80, 400, 404, 600; (Wagner) SF-17, WC-317
Tampo RS-16, RS-28, RS-38, RS-166A, RH-48, RP-16, SP-312, SP-750, SP-950
Vibro Plus CA-25
* includes wheel dozers
Source: Woodward Associates 1976.

Types of Compactors

In 1973, the Society of Automotive Engineers described three types of compactors: tamping (pad) foot compactors, smooth steel rollers, and rubber-tired rollers in a nomenclature standard. The standard referred to compactors (also called "rollers") as smooth-drum, pad-foot (sometimes called "sheepsfoot"), and rubber-tired (also called "pneumatic") (figs. 1-3). Both the smooth-drum and padfoot compactors were manufactured as double drum or single drum, and some had a vibration mechanism designed into the drum wheels to assist in compaction. Units lacking the vibration feature were called static compactors.

An alternative steering mode for many compactors is articulated steering. This combines a prime mover (with the engine) and a trailer that are tightly connected. Steering is through two hydraulic cylinders that push and pull at the connection.

On compactors, an ROPS can be designed with two posts or four posts (fig. 4) and can have a canopy overhead to provide shade; these canopies may be designed as part of the ROPS system. Some modern compactors use a single-post ROPS with a canopy extending to the sides to absorb the impact of an overturn. A principle in ROPS design is to restrict an overturn to no more than 90°.

Research Methods

The collection of cases to be analyzed followed a two-step process. First, the researcher identified OSHA inspection reports and Fatality Assessment and Control Evaluation (FACE) investigations of compactor overturns and runovers by the National Institute for Occupational Safety and Health (NIOSH). Four of OSHA reports were also included in the NIOSH investigations. Most of the cases were found on the internet at the OSHA and NIOSH websites. Others were identified from newspaper articles, litigation files, and through assistance from the Portland, Oregon, Area OSHA Office. A total of 123 cases was identified.

The next step was to request the complete investigation report from OSHA under the Freedom-of- Information Act (although, to protect privacy, all names were expunged from the reports, except for decedents and officials representing the employers). The NIOSH reports were accessible through the internet.

Case files were compiled for 58 injury events involving compactor overturns (table 2). The cases ranged from the year 1985 to 2002.

Some OSHA reports related to the same incident; some addressed falls and collisions, as well as overturns. Eight others dealt with scheduled inspections in which the OSHA General Duty Clause was used to cite the lack of an ROPS or of a functioning seatbelt. OSHA data were not comprehensive and omitted many nonfatal events and all pre-1985 overturns, as well as incidents involving public employees where OSHA lacked jurisdiction.

Data from the reports were placed into a Haddon matrix to analyze the role of machine, environmental, and human factors and the temporal dimension (before, during, and after) of each incident (Runyan 1998; Hadden 1970, 1980). In addition, flowcharts were used to understand the factors that comprised the causal chain leading to and the characteristics of each overturn (Feyer and Williamson 1998; Myers 1992).

The Haddon matrix provided a way to categorize risk factors against three stages of an incident (see table 3). The first stage is pre-event (for example, compacting along an embankment edge); the second stage is the event (such as, an overturn); and the third stage is post-event (for instance, extrication). The risk factors were classified as related to the energy agent (such as, the compactor); the environment (for instance, a steep slope); and operator/driver (for instance, wearing a seatbelt).

Nonetheless, because of limitations in the data, this analysis can't show whether one type of compactor is more dangerous than the others; there is no way to know how much of the work was done using each type.

Table 2. 58 compactor overturn cases analyzed, with associated characteristics

State

OSHA Inspection Number

Yr

Injury Type

Type of Roller

ROPS Present

Seatbelt Present

Incident Type

Roll Over deg.

Operation

Comments

1

AL

300956950

96

fatal

rubber

No

No

edge

180

loading

anti-sloshing baffles in water tank

2

AR

107703555 107703563

92

fatal

pad

No

No

edge

180

soil

leg disability; unable to jump

3

CO

302071550

98

fatal

smooth

No

No

runaway

540

transport

ROPS removed

4

GA

101281608

87

fatal

pad

No

No

edge

190

soil

 

5

GA

102834579

88

fatal

rubber

No

No

runaway

180

gravel

 

6

IL

100089754

85

fatal

smooth

No

No

edge

900

asphalt

 

7

IN

124019019

93

fatal

smooth

No

No

runaway

180

transport

 

8

KY

115948929

91

fatal

rubber

No

No

runaway

unk

transport

 

9

MD

302796149

99

fatal

smooth

No

Yes y

edge

180

soil

wore seatbelt

10

MN

104557012

87

fatal

pad

No

No

edge

1080

soil

 

11

MN

111609665

90

fatal

rubber

No

No

edge

270

gravel

1963 model

12

MN

120400437 a

95

fatal

rubber

No

No

runaway

180

asphalt

 

13

MS

017443771

88

fatal

pad

No

No

edge

90

shoulder

 

14

MS

109070300

94

fatal

pad

No

No

edge

180

soil

articulated position

15

MS

109257709

95

fatal

rubber

No

No

edge

180

gravel

 

16

NC

002998193

87

fatal

rubber

No

No

edge

unk

shoulder

dozer operator

17
NC
014992093
86
fatal
rubber
No
No
runaway
270
transport
turn angle problem

18

NC

302936265 b

00

fatal

smooth

No

No

edge

90

asphalt

asphalt sank, 1T unit

19

NM

300675071

99

fatal

rubber

No

Yes y

edge

180

soil

wore seatbelt

20

NY

115927170

92

fatal

smooth

No

No

edge

unk

shoulder

 

21

OH

103040200

91

fatal

smooth

No

No

edge

90

asphalt

 

22

OH

103336467

95

fatal

smooth

No

No

edge

180

shoulder

 

23

OH

301530283

97

fatal

smooth

No

No

edge

180

transport

 

24

OH

302510367

99

fatal

smooth

No

No

edge

220

asphalt

 

25

OR

107298770

90

fatal

smooth

No

No

edge

360

chip-seal

 

26

OR

115714776

91

fatal

smooth

No

No

edge

180

shoulder

vibrator on, stopped

27

SC

126476977

95

nonfatal

smooth

No

No

edge

 

soil

 

28

SD

113327894

98

nonfatal

rubber

No

No

edge

180

shoulder

articulated position

29

TX

102338530

88

fatal

rubber

No

No

edge

630

shoulder

 

30

TX

103609319

86

fatal

rubber

No

No

edge

450

shoulder

water ballast

31

TX

108761438

91

fatal

smooth

No

No

runaway

720

chip-seal

no brake fluid

32

WA

115328064

97

fatal

smooth

No

No

edge

180

shoulder

 

33

OK

103637120

86

fatal

rubber

unk

unk

unk

unk

unk

riding double

34

SC

124654401

93

nonfatal

smooth

unk

unk

edge

180

loading

used only one ramp

35

TX

107562456

92

fatal

pad

unk

unk

edge

unk

transport

ramp

36

TX

101496586

89

fatal

unk

unk

unk

runaway

unk

in tow

 

37

AK

124096314 c

97

fatal

smooth

Yes

Yes n

edge

90

loading

"top member of ROPS"

38

AR

110353844

93

fatal

pad

Yes

Yes n

edge

90

soil

struck "right top portion of the ROPS"

39

GA

302563101

00

fatal

pad

Yes

Yes n

edge

90

soil

ROPS struck victim;unbuckled belt to jump

40

GA

303378830

00

nonfatal

pad

Yes

Yes n

edge

90

soil

"top of ROPS"

41

KY

002781524

87

fatal

pad

Yes

Yes n

edge

90

soil

ROPS crushed skull

42

KY

304289200

01

fatal

pad

Yes

Yes n

object

unk

soil

struck in head by overhead canapy

43

MD

127378016

96

nonfatal

smooth

Yes

defective

edge

unk

stone

pinned under "overhead protection"

44

MD

127378594

97

nonfatal

smooth

Yes

defective

soft area

90

soil

"overhead canopy," vibrator may have been on

45 46

MN MO

104558358 FACE d

87 97

fatal fatal

pad smooth

Yes Yes

Yes n

edge edge

90 unk

soil asphalt

ROPS on arm struck by ROPS

47

MT

100762657

89

fatal

pad

Yes

Yes n

edge

unk

soil

pinned by ROPS

48

NC

018576249

91

fatal

pad

Yes

No

edge

720

landfill

cab crushed

49

NC

111116166

95

fatal

pad

Yes

Yes n

edge

90

rock

"roll bar cage" above pinned victim

50

NC

111116257

94

fatal

smooth

Yes

1 of 2 n

edge

90

loading

struck by ROPS, 2 seats, 1 belt

51

NC

305747313

02

fatal

smooth

Yes

No

runaway

90

transport

head struck canopy support

52

NY

106161888

02

nonfatal

smooth

Yes

Yes n

soft area

90

soil

"top of ROPS" pinned head

53

OH

DOE e

02

none

smooth

Yes

Yes y

slope

90

soil

survived

54
OR
105201941
88
fatal
rubber
Yes
Yes n
runaway
90
transport
rear gravel box on victim

55

SC

302417621 f

99

fatal

smooth

Yes

No

edge

90

soil

cab, new, pinned under ROPS

56

TX

109448084

93

fatal

smooth

Yes

Yes n

turn

90

transport

"roof of cab" landed on victim

57

TX

302662770

00

fatal

pad

Yes

Yes y

soft area

90

soil

crushed by canopy "cross-beam"

58

WA

303218817

00

fatal

smooth

Yes

Yes n

 

90

soil

ROPS on shoulder

NOTE: for NIOSH FACE reports see http://www.cdc.gov/niosh/face/inhouse.html
a NIOSH FACE Report 95MN47
b NIOSH FACE Report 2000-20
c NIOSH FACE Report 97AK01
d NIOSH FACE Report 97MO37
e U.S. Department of Energy (2002)
f NIOSH FACE Report 99SC03
y seatbelt worn
n seatbelt not worn


Table 3. Use of the Haddon matrix to analyze the risk factors related to a compactor overturn injury

Factor Pre-event Event Post-event
Machine 1. articulated steering
2. a 9-wheel rubber-tired roller
3. no ROPS or seatbelt
1. rolled about 190°
2. ballast dumped out
1. steering wheel and throttle controls crushed
Environment 1. non-paved road
2. ditch along road edge
3. company required seatbelt use when present
4. 4% road grade
1. soft sand/gravel edge
2. sunny
3. roadside ditch 6-feet deep
1. tire marks indicate sharp turn away from road edge
Operator/ driver 1. 21-year-old female
2. 20 minutes of training
3. 200 hours of experience
4. driving in reverse
1. head, shoulder, and arm pinned under machine 1. extricated by co-worker
2. permanent brain damage

Machine, Environmental, and Human Factors

Machine, environmental, and human factors contributed to the 58 compactor overturn injuries described in the OSHA and FACE investigation reports analyzed in detail (see table 2).

Machine-Related Factors

Of the 58 overturns, nearly half (27) related to the smooth-drum, with the remainder roughly divided between the pad-footed (15) and rubber-tired (13) compactors (fig. 5). The type of compactor in one case was unknown.

For the pad-footed compactor overturns, all but two occurred along a road or embankment edge. One other overturn was initiated by an obstruction and another by sinking soft soil. The circumstances related to one overturn were unknown. Eight of the rubber-tired compactor overturns occurred at a road or embankment edge, and another five occurred when a unit went out of control as a runaway because of either brake or gear-shifting defects. As for the smooth-drum compactor, 20 of the 27 overturns occurred along roadway or embankment edges, four were runaways, one was cornering too fast, one was initiated by sinking soft soil, and the cause of one was unknown.

In two cases, leaving a compactor vibrator engaged while stationary may have led to the settling of soil on one side of the unit, allowing it to drop at an angle and overturn. Research has also identified cases where articulation of a mobile unit with the jackknife pointed toward an edge presented a substantial overturn hazard. Three situations led to a hazard in articulated (prime mover and trailer) units. In one situation, the center of gravity of the prime mover and the trailer may have combined in the turned situation to lower the tip angle of the compactor. (In a turned position, the wheels are directed away from the center and may no longer support that portion of the vehicle.) In another situation, the unit's momentum may have aided a tripping situation for an overturn. In the third situation, when turning away from an edge, one set of wheels or drums pointed away from the edge while the other set pointed and moved toward the edge.

A sloshing effect can also be a factor in overturns. Water may be used as ballast in ballast bins or in drums, and water tanks are typically mounted on compactors as a source for spraying. This water or other liquid can slosh toward a slope causing a shift in the center of gravity of the unit.

In another case, an operator steered across a road, but the steering angle of the machine did not allow him to turn sharply enough to become parallel with the edge, and thus, he went over the edge.

More than half - 55% - of the compactors involved in the 58 overturns did not have ROPSs, including 93% of the rubber-tired ones. The lack of an ROPS was a risk factor for an injury. By contrast, an ROPS in combination with a seatbelt offered a system of operator protection in the case of an overturn. However, two new compactors failed to have a seatbelt installed, and two other seatbelts were inoperable with a broken latch and a missing nut needed to secure the belt to the unit.

When a compactor was restricted to a 90° overturn, the severity of any injury was less. Two additional examples not investigated by OSHA indicated the value of ROPS (U.S. Department of Energy 2002). In one such overturn, the operator, who'd worn a seatbelt, walked away without serious injury (fig.6). This unit overturned because it was compacting a slope laterally rather than up and down the slope. In another case, a four-post ROPS is credited with saving the operator's life in another pad-foot single-drum overturn (Patterson 1987). The operator suffered no fractures and was released from the hospital.

Environmental Factors

The most significant environmental factor contributing to compactor overturns was found to be working near an edge of a road or embankment (see fig. 5). The slope at which an overturn was initiated ranged from 12° to 45°, and some overturns occurred with abrupt drop-offs such as over a pavement edge. A compactor may extend over an edge, an edge may give way and sink, or an edge may be sloped so that other factors may accumulate so as to reach the tip angle of the unit. There were two cases in which a compactor sank on a deep asphalt pour that was still warm and caused a tipping situation.

Next in significance in this category were steep slopes and roadway curves, where gear-shifting problems or poor brakes led to runaways (fig. 7). Indeed, steep slopes and curves at the bottom of a roadway have combined to present an overturn hazard; notably, no pad-footed compactor experienced a runaway, perhaps because that type of compactor does not operate on smooth surfaces. Other conditions contributing to runaways included hitting soft soil areas that depress on relatively level land, turning too fast, and kinetic issues such as striking rocks or other obstructions in a roadway.

In connection with the environment, the type of operation was also associated with compactor overturns. In compacting soil, pad-footed and smooth-drum compactors predominate, because rubber-tired compactors are rarely used for this task. Driving a compactor from one location to another as a method of transport was also related to overturns, principally through runaway excursions.

Compacting roadway shoulders presented a risk because a shoulder is an edge. When a compactor attempted to stay off asphalt while compacting a shoulder, some overturns occurred where a shoulder wasn't wide enough. Asphalt compacting presented a risk at the road edge where the deep, hot mix sank under the compactor's weight and on slopes when runaway excursions occurred on the smooth surface.

Hazards during gravel compacting may be similar to those associated with shoulder work Loading and unloading compactors from trailers posed hazards because of the lack of friction of a steel-drum on ramps, the sometime lack of adequate width to reach from one ramp to another, the occasional use of unstable boards as ramps, or unloading onto a slope where a runaway was possible after descending a ramp. Compacting stone may be hazardous because the stone can be slippery. Landfills present irregular and steep terrain.

Human Factors

The most serious human factor was a lack of seatbelt use, or an operator's unbuckling a seatbelt during an overturn and attempting to jump. However, using seatbelts without an ROPS is a recognized crushing hazard also, and one individual was belted in while there was no ROPS. In an overturn without an ROPS, the operator's chance of survival depends on jumping clear of the overturn path. One victim was unable to jump because of a disability.

Possible ROPS Design Defects

One argument against implementing an OSHA standard for ROPSs on compactors has been that ROPSs are a hazard, because Brickman and Barnett (1999) identified 11 cases in which an ROPS was the crushing agent in an overturn injury.

In this study of 58 cases, one ROPS design feature did emerge as a consistent safety issue. In five of the cases in which an ROPS was cited as the cause of a fatal injury, a canopy struck the operator. Canopies have typically been used for shade, but have been adopted in some cases as part of ROPS design. Other cases of individuals struck by ROPSs did not contain enough information to determine the part of the structure that struck the victim. The number of incidents may have been higher than the 5 incidents identified, because a falling or jumping operator would likely move in the direction of the canopy during a rollover.

Every ROPS-equipped compactor considered in this study of 58 cases was restricted to a 90° overturn, except one. The exception was a 1972 model landfill pad-foot compactor with an atypical tricycle design that overturned, crushing the cab, and killing the operator. The compactor overturned twice (720°), with the cab offering little resistence to the overturn, thus making it ineffective as an ROPS.

In another case of a fatal overturn in an ROPS-equipped compactor, there was a design problem: the seat was situated to the side for improved edge viewing but rendered the unit more awkward to steer, especially in a runaway situation (fig. 8). (The compactor was not equipped with a seatbelt.)

Seatbelt Effectiveness

compactor. Several cases included runaway units that did not overturn, but from which operators fell or jumped and were injured by the impact of the fall. An ROPS-seatbelt combination might have prevented injuries, if a seatbelt had been used. Other situations involved collisions with either offhighway or highway vehicles in which a seatbelt likely would have saved lives. The victims in the two collisions that did not involve overturns were thrown off a compactor by the force of a collision and killed by the impact of the crash.

Several factors led to the problem of seatbelt non-use. Among these were the failure of an operator to use a belt (possibly because of discomfort or seatbelt malfunction), unfastening a belt during a runaway excursion or overturn as a panic response, the lack of a seatbelt with an ROPS, the presence of a seatbelt when an ROPS was not present, and dependence upon a cab as a restraint system.

If cabs are used as restraints, instead of seatbelts, the doors must be closed. Three cases involved cabs. One was a case of a non-crush-resistant cab, which was discussed above. The other two cases involved operators who had a cab door open and, during an overturn, each operator was unrestrained, falling through the door and being crushed by the cab frame. The Scandinavians have adopted enclosed cabs as their restraint device (Myers 2000), but the door needs to be closed to restrain the operator in the event of an overturn.

OSHA Enforcement

Until the early 1990s, OSHA typically excluded overturns from ROPS-related citations, because a standard was not in force. However, some jurisdictions and states used OSHA's General Duty Clause to cite employers who failed to provide a workplace free of the overturn hazard. In addition, compliance officers used the clause to cite employers for not requiring the use of a seatbelt in the presence of an ROPS. The OSHA 1998 directive (Swanson) provides for consistency in citing the lack of an ROPS as a violation under the clause. Six compactor-overturn cases were cited as General Duty Clause violations between 1999 and 2002.

Discussion and Recommendations

Workers continue to die and suffer injury from overturns of compactors lacking ROPSs more than 30 years after the passage of the Occupational Safety and Health Act of 1970, which established OSHA. The problem has long been recognized.

As long ago as 1974, in his report to OSHA, Woodward felt compelled to offer insight - albeit unsolicited - into a myth of compactor safety:

    The number of deaths and injuries attributed to the overturn of asphalt rollers would seem to indicate the improbability of designating "safe" work practices for the seven types of vehicles studied in this program. Asphalt rollers are almost always used on flat level road sections with small grade changes. They are never used off the highway bed in rocky, uneven terrain (like a dozer is), never used at a high speed with heavy loads (like a scraper is), never used in a manner to radically change their center of gravity (like a loaded front-end loader), never even used in the relatively shallow sloping angles that a motor grader experiences. A description of the work practices of a roller would seem, on paper, to indicate work conditions that are very unlikely to allow roll-overs. But rollers do overturn! And operators are injured and killed.

Several recommendations are offered as a result of this study.

  • OSHA should promulgate a standard that requires ROPSs and seatbelts on all compactors (rollers) where employers are covered by the OSHAct. This standard should extend beyond the construction sector and should include public employees in state OSHA plans. In the interim, OSHA should establish a special-emphasis program that cites the lack of an ROPS and seatbelt on compactors (and all off-highway vehicles) as a violation of the General Duty Clause.
  • The U.S. Department of Labor's Advisory Committee on Construction Safety and Health should consider recommending an emergency temporary standard to OSHA that requires the installation of ROPSs and seatbelts on compactors (rollers).
  • All compactors (or rollers) an ROPS should either be retrofitted with an ROPS and seatbelt or scrapped.
  • Training procedures for the safe operation of compactors (rollers) are needed. These procedures need to deal with the safety of an extra rider on the vehicle during instruction. The training of operators as established by the manufacturer should include the following:
    • proper uses of a compactor (for instance, roll slopes perpendicularly and not laterally)
    • the presence of an ROPS
    • mandatory presence of (and use of) operational seatbelts
    • procedures for runaway prevention and actions in case of a runaway
    • stability factors of the vehicle including knowledge of its tip angle, the effect on the tip angle of adding ballast, the static and dynamic effect on the center of gravity of articulating the vehicle, and its inherent instability as compared to other vehicles
    • environmental hazards, including slopes, edges, obstructions, hot asphalt at the edges, soft soil pockets, and the lack of friction on rock surfaces
    • the need to properly maintain the vehicle-braking system.
  • Research is needed into how to prevent the overturn-related crushing of an operator by the canopy portion of an ROPS in the event of a seatbelt failure or a failure in to use a seatbelt.
  • Vibratory compactors should be designed to automatically disengage (from dynamic to static mode) when an operator stops a vehicle.
  • Articulated vehicles should be designed for stability in any operational position.
  • Vehicles with ROPS cabs should be designed to operate only when the door is shut
  • Trailers with loading ramps should be used when transporting compactors so the ramps can accommodate the width of the compactor and assure adequate friction to avoid slipping or skidding.
  • Padding on the interior of the ROPS is needed to protect against head injury during overturns.

References

Baker, Robert F. January 1957. Factors influencing the choice of compaction equipment. Public Works.124- 128, 152.

Brickman, D.B., and R.L. Barnett. 1999. Safety Analysis of Roller Compactors Exposed to Rollover. Triodyne Safety Briefs , 14(4), Chicago : Triodyne, Inc.

Church, H.K. 1981. Excavation Handbook. New York : McGraw-Hill Book Co., p. 14-26.

---. 1978. Roller Compactor Safety Manual for Operating and Maintenance Personnel. Milwaukee , Wisconsin : CIMA.

E & R Development Company. Tractor Canopy Impact Tests Conducted at Reading , California During June 1956. Report No. G22-2, July 20.

Feyer, A-M, and A.M. Williamson. 1998. Human factors in accident modeling. Encyclopaedia of Occupational Health and Safety, Third Edition . Geneva : ILO, II:56.8-56.13.

Galion Iron Works & Mfg. Co. 1959. Why compaction? And how to get it. Roads and Streets, April. 120- 122, 127-128, 133, 136-137.

Haddon, W. 1970. On the escape of tigers: an ecologic note. Am J Public Health. 60:2229-2234.

---. 1980. Options for the prevention of motor vehicle crash injury. Israeli Medical Journal, 16:45-65.

Lockie, D.A. March 21, 1974 . The ROPS Saga: OSHA Says Roll Overs Must be Safe. Machine Design. 198- 203.

MacCollum, D.V. October 1958. Tractor Canopies. Pacific Builder and Engineer. pp. 98-99.

---. 1984. Lessons from 25 Years of ROPS. Professional Safety, January, 25-31.

Miles, J.B. 1986. Letter to Thomas A. Berry dated March 1, 1985 . Washington , D.C. : Occupational Safety and Health Administration, Directorate of Field Operations.

Murphy, W.B. 1970. Safety: Requirement for Rollover Protective Structures. Circular No. 385-1-44. Washington , D.C. : Office of the Chief of Engineers, Department of Army, June 12, 1970 .

Myers, Melvin L. 1992. Preventing Logging Fatalities in Alaska , presented at the International Winter Meeting, The American Society of Agricultural Engineers , Nashville , Tennessee , December 15-18, Paper No. 927508 .

---. 2000. Prevention effectiveness of roll-over protective structures, part I: strategy evolution, 2000. Journal of Agricultural Safety and Health , 6(1):29-40.

National Safety Council. 1976. Roll Over Protective Structures. Safety Newsletter. Wood Products Section (Sec. G), Chicago (now Itasca , Il), May, p. 1-3.

Naval Training Command , U.S. Navy. 1973. Rate Training Manual: Equipment Operator 3 & 2. NAVTRA 10640-G. Washington , D.C. : U.S. Government Printing Office, p. 375.

OMB, Office of Management and Budget. 1985. Regulatory Program of the United States Government for the period, April 1, 1985 to March 31, 1986 . Executive Office of the President, pp. 314-15.

Patterson, N. 1987. Covered cab credited with saving operator as vehicle turns over. Birmingham Post-Herald . March 6, p. C1.

Richter, K. 1987. Memorandum regarding OSHA's Requirements, Ingersoll-Rand Construction Equipment, Compaction Division, August 20, 1987 .

Ritter, L.J., and Radnor J. Paquette. 1960. Highway Engineering. New York : Ronald Press Co.

Runyan, C.W. 1998. Using the Haddon matrix: introducing the third dimension. Injury Prevention. 4:302-307.

SAE, Society of Automotive Engineers. 1973. SAE Standard: Nomenclature- Compactors/Rollers-SAE J1017. pp. 1534-1536.

---. 1975. SAE Recommended Practice: Categories of off-highway self-propelled work machines-SAE J1116. 41.01-41.02.

---. 1981. SAE Recommended Practice: Categories of off-highway self-propelled work machines-SAE J1116 JUN81. 41.01-41.02.

---. 1986. SAE Recommended Practice: Performance criteria for rollover protective structures (ROPS) for earthmoving, construction, logging, and industrial machines-SAE J1040 FEB86. SAE Standards . Warrendale , PA : Society of Automotive Engineers. pp. 40.297-304.

Skromme, A.B. 1986. History of Rollover Protection for Farm Tractors. Presented at the dedication ceremony of a Historic Milestone in Agricultural Engineering, "Rollover Protection for Farm Tractors," Waterloo, Iowa , September 25.

Swanson, Russell B. 1998. 03/16/1998 - Guidelines for ROPS on pneumatic compactors and "skid steer: equipment . OSHA Office of Construction and Engineering, http://osha.gov/pls/oshaweb/owadisp.show_document?p_table-interpretation&p_22546&p_... 11.12.2002.

U.S. Army Corps of Engineers, Department of the Army. 1967. General Safety Requirements, EM 385-1-1. In: Safety and Health Requirements Manual. Washington , D.C. : Government Printing Office.

U.S. Department of Energy. 2002. Operating Experience Summary. Office of Environment, Safety, and Health. Summary 2002-09, May 6.

White, Richard. 1973. Descriptions of work fatalities involving roll-overs of steel-wheel road rollers, California , 1965-72 and Descriptions of work fatalities involving roll-overs of steel-wheel compactors, California , 1965-72. A Report. San Francisco , Calif. : Division of Labor Statistics and Research, Department of Human Relations Agency, State of California .

Woodward, J.L. 1980. Survey of Rollover Protective Structures (ROPS). Report to the U.S. Bureau of Mines by Woodward Associates, Inc., Contract No. J0285022.

Woodward Associates Inc. 1974. Study to determine the engineering and economic feasibility of retrofitting ROPS on pre-July 1, 1969 construction equipment . Prepared for Office of Standards, OSHA. U.S. Department of Labor Contract No. L-73-158, July 15.

---. 1976. Program final report design criteria and guidelines for falling object protective structures (FOPS). WA Report 76-22F, U.S. Bureau of Mines Contract No. J0357110.

Zink, W.M. 1970. General Safety Requirements, Circular No. 385-1-1, July 1, Portland , Oregon : North Pacific Division, Corps of Engineers, Department of the Army.



Annex A: Figures 1 - 8

Figure 1. A double smooth-drum compactor with an ROPS canopy and articulated steering. Figure 2. A pad-foot compactor with a single drum and articulated steering.
Figure 3. A rubber-tired compactor with a two-post ROPS. Figure 4. A double drum pad-foot compactor with articulated steering and a four-post ROPS with a canopy.

Figure 5. Number of compactor overturns resulting in operator injury, by conditions and type of compactor, 1985-2002

Note: 56 cases
Source: Based on OSHA and NIOSH reports


Figure 6. A compactor overturn that shows the anti-roll function of an ROPS

Source: U.S. Department of Energy


Figure 7. Conditions contributing to overturns, by type of compactor and number of overturn incidents, 1985-2002

Source: Based on OSHA and NIOSH reports


Figure 8. A seat and steering wheel perpendicular to the front of a compactor, which has no seatbelt; this unit was involved in an overturn-related death


Source: North Carolina Department of Labor

Annex B: The Usefulness of OSHA and NIOSH Reports for This Research

Unless a researcher had the OSHA inspection number or the employer's name, it was nearly impossible to access OSHA files through the Freedom of Information Act. Issues related to using the OSHA reports fell into two categories: (1) different policies between state and federal programs and the lack of record retention and (2) the exclusion of inspection information that was critical to identifying risk factors.

The reports were available from OSHA through two approaches. One approach was to request all reports by investigation number within ten federal regions. The other approach was to request the reports from the OSHA Area Office (in federal jurisdictions) or state OSHA agency (in state jurisdictions). To protect confidentiality, OSHA Accident Reports were provided with all names expunged from the reports, except decedents and officials representing the employers.

Federal policy is to retain reports related to fatalities indefinitely and to destroy other reports after seven years of retention. However, state programs have a variety of retention rules. For example, California destroys all reports after three years, and other states have report retention rules that fall somewhere between the California and federal policies. Nonetheless, many federal offices could no longer locate older fatality reports, which typically had been sent to archives. Some were lost and some were destroyed.

The California policy was particularly problematic. OSHA did not post its report summaries on the Internet until four to five years after the incident because it has a process of evaluating and editing the summaries before they were posted. By the time the California cases were searchable on the Internet, the original reports had been destroyed.

In addition, OSHA policy is to protect the privacy of individuals named in the reports. Thus, names other than the company officials and the decedent were typically marked out. However, policy varies broadly in excluding other information based upon additional criteria such as interagency memoranda and government agent opinions. In the case of the Oklahoma Area Office, nearly all information based upon the field notes was struck out since it was judged to be "opinion," as were typed narratives, sketches of the scene, whole witness statements (without their names and other personal identifiers), and manufacturer information, etc., all of which could assist in identifying risk factors. In addition, Kansas has a privacy law that precluded the release of any inspection report information and is the antithesis of an open records doctrine.

Conversely, a lot of information that was released proved helpful. Some compliance officers were detailed in naming the make and model of units, and though more rarely, the machine's hour meter reading. Photographs were invaluable in examining the terrain and the type of machine-whether compactor or trailer-involved in the incident. Some OSHA reports included a handwritten record of "fatal facts," which was useful and provided consistency between the risk factors reported from one report to another. Especially detailed were the reports from the North Carolina state program. The Portland Area Office assisted in identifying additional and more recent cases that had yet to be posted on the Internet. In one case, the compliance officer reviewed the employer's accident log and discovered three additional compactor overturns in which no serious injury occurred.

Police reports enclosed with the reports were also useful, for they typically included precise measurement of slopes and distances. Police reports also detailed witness statements and observations regarding the part of the machine that struck the victim.

The NIOSH FACE reports were helpful because they used much of the same information that was applied in the Haddon matrix. However, they did not cite the OSHA investigation report, which was problematic in producing a consistent file on each case. Although some FACE reports detailed the machine involved in the incidents including photographs, other reports' authors appeared reluctant to name the make and model of the machine. In determining risk factors, this information was critical from the viewpoint of identifying engineering solutions to the injury risks.

One jurisdiction that was likely undercounted was the government sector. Some state programs, such as North Carolina, aggressively regulate state and local government sectors. Also, some OSHA Area Offices, such as Portland, actively investigate federal agencies. In North Carolina, where the state investigates state and local government employers that are outside federal jurisdiction, seven overturn incidents were investigated and three (43%) of them involved either city or state employees. Since most of the government sectors were unregulated, investigating these omitted sectors may be a role for NIOSH's FACE program to