M5 (Cape Town)

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M5

Route information
Maintained by City of Cape Town and Western Cape Department of Transport and Public Works[1]
Length37 km (23 mi)
Major junctions
North end N7 in Dunoon
Major intersections M14 in Killarney Gardens
M87 in Milnerton
M8 in Milnerton
N1 in Brooklyn
M16 in Maitland
N2 / M52 in Mowbray
M18 in Athlone
M34 in Rondebosch
M24 in Kenilworth
M68 in Plumstead
M38 in Southfield
M55 in Grassy Park
M35 in Grassy Park
South end R310 in Muizenberg
Location
CountrySouth Africa
Highway system
M4 M6

The M5 is an expressway in the City of Cape Town Metropolitan Municipality, South Africa. It connects Milnerton on the Western Seaboard in the north to Muizenberg in the south, and crosses both the N1 and the N2. For part of its length, from the N1 interchange to Plumstead, it is a limited-access freeway (motorway).[2][3] From Mowbray to Muizenberg it is parallel to the M4 Main Road.

Route

The M5 begins at the Potsdam interchange with the N7 highway in the suburb of Dunoon. It goes south-south-west as Potsdam Road and reaches a junction with the M14 (Blaauwberg Road), where it becomes Koeberg Road and becomes a dual carriageway. The M14 joins the M5 for a few metres southwards before becoming its own road eastwards (Plattekloof Road) while the M5 continues south as Koeberg Road. It proceeds southwards for 9 kilometres, through the large suburb of Milnerton, to reach the Koeberg Interchange with the N1 highway (Table Bay Boulevard) in Brooklyn, where it becomes a limited-access motorway.

It proceeds southwards from the N1 interchange as the Black River Parkway, crossing the Black River, through Maitland, to reach an interchange with the N2 highway (Settlers Way) near Mowbray, where it becomes the Kromboom Parkway. It proceeds southwards, through Athlone, Rondebosch East and Lansdowne, to reach the M68 (Ottery Road) interchange in Plumstead, where the M5 loses its motorway status but remains a dual-carriageway as Prince George Drive. It proceeds southwards, through Retreat, to enter Muizenberg on the False Bay Coast, where it terminates at a roundabout junction with the R310 (Baden Powell Drive).

An aerial view of the M5 highway with the Black River running alongside it.
Smash and Grab Hot Spot at M5 through Retreat

Koeberg interchange

The largest interchange on the M5 is the Koeberg interchange, connecting the M5 with the N1. The merging of lanes at this interchange used to result in multi-kilometer stop/start queues approaching the interchange on the M5.

Elevated freeway upgrade

In 2008, work began to upgrade the Koeberg interchange with elevated freeways joining the M5 and the N1. The elevated freeway from the N1 onto the M5 was completed in June 2010 in time for the 2010 FIFA World Cup, while the other direction was completed in November 2011.

At the end of 2011, Google maps street view of this interchange showed the progress of the work on the interchange in stages by combining images over time and connecting them underneath existing bridges. This enabled the viewer to experience a form of virtual reality during multiple points in the construction phase.[4][5][6][7][8]

Design

The elevated freeways embody some innovative design features and principles. For example: The elevated freeways had to be built without disrupting the daily flow of some 200 000 vehicles. The existing roads and bridges had already used up the available land into which to expand. The intersection is hemmed in by a canal, railway reserve, power transformer, and industrial buildings etc. Thus the possibility of overlaying the existing structures with a bypass had to be envisioned. It had to be a system that could fit into the existing interchange. Oval reinforced concrete pillars with "T" pieces atop, standing on foundations supported by concrete piles, could fit into the spaces between existing roads and bridges. These could in turn support post-tensioned concrete "U" beam spans, cast on the ground and lifted into place by crane. The road deck would be cast on top of the "U" beams. Five beams between each "T" topped pillar allowing for a double lane road deck. The beams resting on each side of the "T" piece support, are connected to each other and the deck by a concrete end which resists lateral-flexing of the deck between-beams.

The roadway on both elevated freeways narrows from a double lane to a single lane at the point where it connects with the existing N1 and the M5 motorways. At this point, the elevated freeway presents the motorist with a down-hill slope to encourage acceleration. The elevated freeway feeds into its own lanes on both of these existing freeways allowing acceleration and preventing congestion.

"U" beam spans

The "U" beams would have sloping sides like a "V" with a flat bottom. The forces at the centre of the span cause lateral inward compression at the bottom of the "V" and lateral outward compression transmitted into the deck as tension. The longitudinal tension, at the bottom of the "V" and at the centre of the span, is absorbed by potent post tensioned cable embedded in the concrete. Each beam rests on its ends, on purpose designed steel plates, which accommodate expansion and contraction and transmit the weight of the span into the "T" pieces atop the oval pillars.

The roadway deck would extend beyond the edge of the outer beams and be lined with pre-cast crash barriers.

Box girder bridges

Box girder bridges were conceived, designed and built to span the railway reserve and the long stretches over the outbound N1 carriageway and the Northbound M5 carriageway as it approaches the N1. These had to be supported by scaffolding in the case of the end bridges and by "I-beam" steel trusses in the case of the railway reserve spans. The railway reserve also includes the height of the electrification services. This height added to the height of the "I-beam" steel trusses, the scaffolding on top of the trusses and the height of the box girder bridge is the determining factor in the extraordinary height of the new elevated freeway, which at its highest point is at the same height as the 5th story of the adjacent old mill building.

During construction of the end box girder bridges, the traffic had to be diverted round the supporting scaffolding. This was especially inconvenient on the outbound carriageway of the N1 where speed was severely reduced, adding heavily to congestion.

Construction

Where the roadway deck extended beyond the edge of the outer beams, this would be made possible by the use of wooden triangular supports temporarily bolted to the outer beams and covered with concrete shutter-boards. The beams themselves would have pre-cast holes to accommodate the bolts holding the triangles in place.

"U" beams

Each "U" beam, weighing 80 metric tonnes, would be cast on the ground at a nearby designated temporary factory area between the N1 and the railway reserve. Each beam would be a specific length and be designated to be placed in the exact place for which it was designed. The beams would be cast on a set of reusable foundations and steel moulding panels supported by steel jacks. The beams would be transported on the ground by a purpose-built pair of 12 wheeled trucks, made of welded steel "I-beam" frames, each attached to the end of a concrete span "U" beam and then towed a short distance to the construction site by a conventional diesel mechanical horse.

Pillars

Each pillar and its "T" piece would be treated as a project in its own right. Purpose-built steel mouldings would be reused for each pillar and each pillar would be constructed in stages. The mouldings would be moved by cranes. Where the underlying ground was "soft", steel reinforced concrete piles would be driven into the base of the foundation hole and the upper protruding ends incorporated into the foundation.

Crash Barriers

The pre-cast crash barriers lining the edge of the deck would also be manufactured nearby using purpose made steel moulds. They would be bonded into place by having re-bar-steel loops protruding from both the edge of the road deck and also from the bottom of the barrier section. These loops would mate together when the barrier was placed and be affixed there by injecting concrete into the space between the deck and the barrier, permanently bonding the protruding loops together. Subsequently, a concrete guard rail would be cast on top of the crash barrier.

The Roadway deck

The deck would be constructed like any other reinforced concrete deck with the exception that the shuttering is designed to remain in place permanently and there is no use of scaffolding to support the shuttering. Pre-cast lip and groove formations on the upper edges of the "U" beams were designed to accommodate a thick Masonite type of shuttering board which would bear the weight of a man walking on them. The beams themselves provide a safe walk way for workers to access the section of road deck being constructed, during construction. When the steel reinforcing rod framework has been completed over the shuttering, a ready-mix concrete is pumped up from a mixer parked on the underlying roadways. This concrete is spread over the shuttering and reinforcing steel work and allowed to cure. Finally the deck is covered with a conventional asphalt macadamised tar and granite chip surface and marked with paint.

References

  1. ^ "Western Cape Department: Transport and Public Works". provincialgovernment.co.za. Retrieved 2021-04-11.
  2. ^ "RDDA SOUTH AFRICAN NUMBERED ROUTE DESCRIPTION AND DESTINATION ANALYSIS". NATIONAL DEPARTMENT OF TRANSPORT. May 2012. Retrieved 25 March 2021.
  3. ^ "WCPP 2018/2019 Annual Report" (PDF). Western Cape Department Of Transport and Public Works. 2018–2019. Retrieved 11 April 2021.
  4. ^ "Sign in - Google Accounts".
  5. ^ "Phase 1 of Koerberg interchange complete". IOL. 2010-06-07.
  6. ^ "Creamer Media Login".
  7. ^ Bruce, Sutherland. "Koeberg Interchange". City of Cape Town. Retrieved 30 December 2011.
  8. ^ Saied, Solomon. "asphaltNEWS" (PDF). SABITA. Retrieved 30 December 2011.

See also