Cab over

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Volvo FH16.700.jpg
Volvo FH cab-over lorry
Overview
ManufacturerVarious
Also calledCOE, forward control
Production1899 - present
AssemblyWorldwide
Body and chassis
ClassLight, medium, and heavy
Body styleCab over engine

Cab-over, also known as cab over engine (COE), cab forward (U.S.), flat nose (Canada), or forward control (UK), is a body style of truck, bus, or van that has a vertical front, "flat face" or a semi-hood, with the cab of the truck sitting above (or forward of) the front axle. This contrasts with a conventional truck where the engine is mounted in front of the driver.

This truck configuration is currently common among European and Asian truck manufacturers. European regulations set restrictions for both the total length and the length of the load area, which allow a cab length of 2.35 m (7 ft 8+12 in) in combination with the maximum load area length. This allows a sleeper cab with a narrow bunk, and would allow a bonneted (hooded) day cab. Nonetheless, no manufacturer in Europe produces such day cabs with bonnets. The last manufacturer of a conventional in Europe, Scania, stopped production in 2005. (The reason was a decline to less than 1000 units worldwide, with European sales declining by 50% and sales in South America by 90%, within one decade.) Generally speaking, Asian regulations are even stricter, and the relatively shorter journey distances allow more heavy trucks to forgo sleepers to save even more length.

The cab-over configuration is common for garbage trucks, as the short wheelbase allows a tight turning radius and the low cab height eases driver entry and exit.

Cabover trucks are widely used in the United States for refuse collection, terminal tractors, and other vocational applications requiring a tight turning radius or frequent ingress/egress by the driver. Autocar, the oldest surviving motor vehicle manufacturer in America, produces primarily cabover trucks. Although cabover trucks were popular among United States heavy truckers and trucking companies during the 1970s because of strict length laws in many states, when those length laws were repealed, most heavy-truck makers moved to other body styles. One of the reasons is the Federal Bridge Formula, which is unique to the US, and encourages spreading out the load. If axle distances are too tight, the maximum load allowance is reduced. For COEs operated at maximum weight in the US, this required an axle directly behind the front bumper. This cab design caused an awkward climb into the cab for the driver, forcing them to climb up behind the front wheel, then moving to the front and into the cab. European or Chinese or Japanese truckers enter their cab in a straight fashion with handrails left and right.

Cabovers are also very popular in the US's light- and medium-duty truck segment where compact size is required for urban mobility without sacrificing payload; Toyota subsidiary Hino, Isuzu, and Mitsubishi Fuso models are a regular sight for this reason. American companies Paccar (which owns the Kenworth and Peterbilt brands) and Freightliner still manufacture traditional cab over engine designs for the Australian and South African markets where length restrictions still make them advantageous.

In Australia, both American (cab over axle) and European/Japanese/Chinese (cab forward of axle) types, as well as the conventional type are common. Cab over engine types dominate urban and light duty use, with conventional trucks predominating in remote and off-road areas. Both types are common for highway use.

History[edit]

Vintage COE: 1942 Chevrolet
Preserved International Harvester Metro Van in Portland, Oregon in 2012

The first truck in the United States was built by Autocar in 1899 using a format then called "engine-under-the-seat" and was available with optional 3.7 or 6.0 kilowatts (5 or 8 hp) motors.[1] Although early Autocar trucks were not exactly "cab-over", since the truck did not have a cab, per se, they were the fore-runners to COEs. The Sternberg company of Wisconsin produced cab-over trucks as early as 1907, though by 1914 only their seven-ton model was a cab-over. They reintroduced the cab-over layout in 1933 with their "Camel Back" model, which allowed the cab to be tilted to access the engine.[2]

The introduction of the first modern cab-over layout in the United States is credited to industrial designer Viktor Schreckengost, who, with engineer Ray Spiller, designed a cab-over truck for the White Motor Company in 1932. Schreckengost was later joined by other designers such as Raymond Loewy who designed the Metro series of vans and trucks for International Harvester. The bodies for these vehicles were initially produced by the Metropolitan Body Company (MBC). The company produced a wide variety of truck and commercial bodies for several vehicle manufacturers such as Chevrolet, Ford, Dodge Bros., and International Harvester until 1948 when they were purchased by the latter. MBC was instrumental in the development of COE route delivery bodies in the 1930s.[3]

The laws of the time limited overall truck length to 12.8 metres (42 ft) on highways. Setting the cab over the engine and front axle shaved several feet off the length of the tractor, feet which could then be added to the length of the trailer while keeping the dimensions of the entire truck within the permissible limit. Schreckengost patented the design in 1934.

Autocar reintroduced the engine-under-the-seat format with their Model U in 1933, which became a staple of U.S. roads and the U.S. military through World War II and well into the 1950s.[1]

White-Freightliner introduced its first tilting cab-over design in 1958, which allowed the entire cab to tilt forward for access to the engine.[2]

Design aspects[edit]

The 1962 Sisu KB-112/117 was the first European serial produced truck with a hydraulically tiltable cabin, enabling easy access to the engine.

In Class 8 tractors (using the US designation), the cab-over design allows the vehicle's wheelbase to be shorter than in the conventional arrangement, wherein the engine is placed in front of the cab, covered by a horizontal or sloping hood that opens to allow engine access. Its shorter wheelbase allows cab-over semi trucks to have a shorter overall length, thereby allowing for longer trailers to be used. For light- and medium-duty solid- or rigid-axle trucks, the cab-over design requires less length for the cab and engine, in a given wheelbase, and therefore allows a greater length for the truck body or load area.

In both class 8 tractors and light- and medium-duty vocational trucks, the cab-over-engine design gives the COE model an advantage in maneuverability over a conventional model. And since COEs are generally lighter than conventionals, they can often haul heavier loads, given equal gross vehicle weight rating (GVWRs) and gross combination weight rating (GCWRs). Despite the COE designs' being smaller in general, over-the-road tractors can still be fully equipped with single or bunk beds. Also, lack of a hood gives better visibility to the driver and a tighter turning radius, and significantly reduces the forward blind spots.

One critique is that the shorter wheelbase in the COE semi-trucks gives a rougher ride than those with conventional cabs, as the driver's seat is above the front axle. In the 1970s, COEs used to be noisier, because the engine is directly below. This was an important consideration back then: Interior noise in the cab was between 80 and 90 db(A), creating an unhealthy work environment.[4] As of 2017, US long distance trucks provide an interior noise level of 60–70 db(A) at highway speed, while European long distance trucks, all built as a COE, provide a level of 60–65 db(A). As highway speeds are a slightly higher in the US, this performance can be viewed as equivalent.[citation needed]

Because of their flat front design, early COE semi-trucks had significantly worse aerodynamics than conventional tractors. Modern cab-over designs, in both semi-trucks and light- and medium-duty models, have improved aerodynamics significantly over early models, but often still have higher drag coefficients than their modern conventional-design counterparts. This works against fuel economy, and offsets some of the improvement in fuel consumption garnered from the lighter weight of the cab-over truck when running less than fully loaded.[citation needed]

Although the tilting cab gives comparatively unobstructed access to the engine, its deployment causes unsecured items in the cab and sleeper (if equipped) to fall onto the windshield or under the instrument panel.[5] Vehicles without a tilting cab will usually be equipped with removable floor panels through which mechanics can access and service the engine. In Europe, Mercedes-Benz was the last manufacturer to use such panels instead of a tilting cab, with the last non-tilting cabs produced well into 1983.

Safety aspects[edit]

Tatra 813 Kolos 8x8 Drive Military Truck
Land Rover 101 Forward Control with radio-vehicle body

Truck occupant safety depends on survival space within the cab, with "rollover" being the most significant heavy truck accident causing occupant casualties. [6] In the 1950s, when many truck cabs were still wooden structures, knowledge about the most common accidents was already established, and led to the first mechanized truck cab crash test in 1959, performed by Volvo. The test became a Swedish standard, and was adopted by the European Community in simplified form as ECE R-29 in 1974. During the early 1980s, the safest place for a truck driver was a European truck, usually a cabover.

Decision-making is based on human perception in first place, results of statistics might not be present. Motor placement before or under the cab does not have much influence on the results of rollovers. Behind the danger of a rollover, heavy truck on heavy truck accidents are the second most relevant reason for occupant casualties. With a 1980s US conventional, the result of such accident was: Frame, front axle and wheels would go under the truck in front, while the motor got pushed into the cab (which was very small in a 1980s conventional).[7][8] Contrary to these real-world results, the motor in front, which would crush the truck driver in an accident, was nonetheless perceived as "protection", and this perception was an important factor for the adoption of these trucks in the US, during the 1980s.[citation needed]

Both conventionals and cabovers need structural protection against rollovers, and special protection against massive objects at the height of another truck body. The survival space should be able to move backward on the frame. Today (2017), crash tests have been adopted all over the world (the most important ones still being similar to the Swedish tests of the 1960s), and the 1970s/80s safety advantage of European trucks no longer exists.[citation needed]

In military use, the COE design increases the chance of crew injury or death in the event of running over a landmine. This is because the tire that detonates the mine is directly below/beside the driver.[9]

See also[edit]

References[edit]

  1. ^ a b "Archived copy". Archived from the original on 2015-02-08. Retrieved 2016-08-23.CS1 maint: archived copy as title (link)
  2. ^ a b Holtzman, Stan (1995). American Semi Trucks. MBI Publishing Company. pp. 82–85. ISBN 0-7603-0038-0.
  3. ^ Staff. "Metropolitan Auto and Carriage Co., Metropolitan Body Co". Retrieved 14 December 2013.
  4. ^ Reif, Zygmunt F.; Moore, Thomas N.; Steevensz, Arthur E. (February 1980). Noise Exposure of Truck Drivers. Vehicle Noise Regulation and Reduction Session. Detroit: Society of Automotive Engineers.
  5. ^ Richards Award Winning Kenworth Cabover
  6. ^ Herbst, Brian R.; Forrest, Stephen M.; Meyer, Steven E.; Clarke, Christopher C.; Bell, Lauren D.; Oliver Nelson, Arin (2015). Test Methods for Occupant Safety in Heavy Truck Rollovers (PDF). RCOBI Conference. Retrieved 7 November 2017.
  7. ^ "Castro Valley: Lanes reopen after big-rig fatal wreck blocks I-580 for hours". East Bay Times. US. 14 September 2017. Retrieved 6 November 2017. Photo 5 shows the engine pushed into the cab on a conventional truck
  8. ^ Old Truck Crash Test – via YouTube. COE crash tests from the 1970s on a 1975 Volvo F609 COE
  9. ^ Ramasamy, A.; Hill, A.M.; Hepper, A.E.; Bull, A.M.J.; Clasper, J.C. "Blast Mines: Physics, Injury Mechanisms And Vehicle Protection" (PDF). JR Army Med Corps Journal.com. Archived from the original (PDF) on 2012-05-10. Retrieved 2012-06-20.