Featured Project: Maluti-a-Phofung IDZ – Infrastructure

Description: Construction of services and infrastructure for the Maluti-a-Phofung Industrial Development Zone / Industriqwa Industrial Estate, at Maluti-a-Phofung near Harrismith in the Free State. The Tshiame IDZ will focus on automotive, clothing and agro-processing activities. CIDB 9: R130 Million Plus.

Status: Tender

Industry: Infrastructure

Region: Harrismith

Sector: Public

Value: R 100 million+

Timing: 2017 onwards.

Notes: The Closing Date for DTA 624564 has been extended to 13 April 2017. A Copy of the Site Attendance Register has been requested via email, awaiting a response.

If you are a valued Projects subscriber, you can find more details click here

About Bianca Warwick

I had the privilege of joining the Leads 2 Business content team in January 2012. I work in the exciting Projects department, following the progress of construction developments in KwaZulu-Natal and the Free State.

Featured Tender: Rehabilitation of road P175/1 from Potchefstroom to Vanderbijlpark road (Gauteng Border) approximately (12) kilometres

Contract Number: PWR85/13 – Department of Public Works and Roads

Description: Tenders are invited for: Rehabilitation of road P175/1 from Potchefstroom to Vanderbijlpark road (Gauteng Border) approximately (12) kilometres. Name of institution: Department of Public Works and Roads. Place where goods, works or services are required: Potchefstroom to Vanderbijlpark.

Industry Sector: Road + Institutional

Industry: Infrastructure

Region: North West

Site Inspection: A compulsory briefing session will be held on: Date: 25 May 2017 at Time: 10:00. Venue: Willows Garden Hotel, No. 82 Goven Mbeki Avenue, Potchefstroom.

Closing Date: 09 June 2017 at 11:00

Restrictions: Department Of Public Works & Roads, Mmabatho, Gate House. Documents will be available from 15th May 2017 at a non-refundable fee of R300.00 payable at department offices or at Bank Name: Absa, Account Name: Nw-Department Of Public Works & Roads, Account No.: 4085956856, Branch Code: 634540, Ref No.: Company Name And Project No.

If you are a valued Tender subscriber, Click to here for more information

About Roxanne Mustard

My Name is Roxanne Mustard and I started working at Leads 2 Business in September 2016. My role in the Leads 2 Business team is as a Regional Content researcher in the Projects Department.

Did you know #DYK – The difference between various road surfaces

posted in: Did You Know 8

The difference between various road surfaces

Asphalt, Gravel, Concrete and Pavers, but many countries use certain material depending on the area conditions and climate, despite concrete roads having some major advantages. Concrete and Asphalt are more commonly used. Learn about the advantages and disadvantages of the different road paving surfaces in this article.

 

Asphalt:

One of the most popular types of construction ever since its inception in the early 1920’s is asphalt paving. In this construction technique, a layer of asphalt is laid on top of an equally thick gravel base. Advantages of this form of road construction are that the pavement proves relatively easy to repair and maintain as well. However, asphalts is known to be significantly less durable and stronger than most other choices and isn’t the best for the environment either. Polypropylene and polyester geosynthetics have also been used for this purpose and in some northern countries, a layer of polystyrene boards have been used to delay and minimise frost penetration into the subgrade.

Depending on the temperature at which it is applied, asphalt is categorised as hot mix, warm mix, or cold mix. Hot mix asphalt is applied at temperatures over 300 °F (150°C) with a free-floating screed. Warm mix asphalt at temperatures of 200-250 °F (95-120°C), resulting in reduced energy usage and emissions of volatile organic compounds. Cold mix asphalt is often used on lower volume rural roads, where hot mix asphalt would cool too much on the long trip from the asphalt plant to the construction site.

An asphalt concrete surface will generally be constructed for high-volume primary highways having an average annual daily traffic load greater than 1200 vehicles per day. Advantages of asphalt roadways include relatively low noise and relatively low cost compared with other paving methods. Disadvantages are less tensile strength than concrete, the tendency to become slick and soft on hot weather and a certain amount of hydrocarbon pollution to soil and groundwater or waterways.

In 1960’s, rubberized asphalt was used for the first time, mixing crumb rubber from used tires, with asphalt. While a potential use for tires that would otherwise fill landfills and present a fire hazard, rubberized asphalt has shown a greater incidence of wear in freeze-thaw cycles in temperate due to non-homogeneous expansion and contraction with non-rubber components. Also, application of rubberized asphalt is more temperature-sensitive and in many locations can only be applied at certain times of the year. Study results of the long-term acoustic benefits of rubberized asphalt are inconclusive. The initial application of rubberized asphalt may provide 3-5 decibels (dB) reduction in tire-pavement source noise emissions; however, this translates to only 1-3 decibels (dB) in total noise level reduction (due to the other components of traffic noise). Compared to traditional passive attenuating measures (e.g. noise walls and earth berms), rubberized asphalt provides shorter-lasting and lesser acoustic benefits at a typically much greater expense.

 

Concrete:

 

Concrete is another popular choice for roadways, though it is typically only used for local roads and not other types of construction. Concrete surfaces (specifically, Portland cement concrete) are a created mix of Portland cement, coarse aggregate, sand and water. In virtually all modern mixes there will also be various admixtures added to increase workability, reduce the required amount of water, mitigate harmful chemical reactions and for other beneficial purposes. In many cases, there will also be Portland cement substitutes added, such as fly ash. This can reduce the cost of the concrete and improve its physical properties.

The material is applied in the freshly mixed slurry and worked mechanically to compact the interior and force some of the cement slurries to the surface to produce a smoother, denser surface free from honeycombing. The water allows the mix to combine molecularly in a chemical reaction called hydration.

There are three major types of concrete road surfaces – jointed plain (JPCP), jointed reinforced (JRCP) and continuously reinforced (CRCP). The distinguishing feature between the three being the joint system that is used to help prevent cracks from forming. Jointed plain concrete pavements contain joints to control the location of all the expected shrinkage cracks. The concrete cracks at the joints and not elsewhere in the slabs. Jointed plain pavements do not contain any steel reinforcement. However, there may be smooth steel bars at transverse joints and deformed steel bars at longitudinal joints. The spacing between transverse joints is typically about 15 feet (4.6m) for slab 7 to 12 inches (180 to 300mm) thick. Jointed reinforced concrete pavements contain steel mesh reinforcement (sometimes called distributed steel). In jointed reinforced concrete pavements, designers increase the joint spacing purposely and include reinforcing steel to hold together intermediate cracks in each slab.

The original pavement was laid in the 1950’s and has been significantly altered since.

Something to know about:

  • Durability and maintenance free life: Concrete roads have a long service life of forty years, whereas asphalt roads last for ten years. Moreover, during this service life concrete road do not require frequent repair or patching work like asphalt roads.
  • Vehicle consumes less fuel when running over a concrete road, consumes 15-20% less fuel than that on asphalt roads. This is because of the fact that a concrete road does not get deflected under the wheels of loaded trucks.
  • Resistant to automobile fuel spillage and extreme weather: Unlike asphalt roads, concrete roads do not get damaged by the leaking oils from the vehicles or by the extreme weather conditions like excess rain or extreme heat.
  • Greener process: Asphalt (bitumen) produces lots of highly polluting gases at the time of melting it for paving. Also, less fuel consumption by the vehicle running on a concrete road means less pollution.
  • Saving of natural resources: Asphalt (bitumen) is produced from imported petroleum, the reserve of which is becoming reduced drastically. On the other hand, concrete (cement) is produced from abundantly available limestone.

 

Pavers:

A paver is a paving stone, tile, brick or brick-like piece of concrete commonly used as exterior flooring. In a factory, concrete pavers are made by pouring a mixture of concrete and some type of colouring agent into a mould of some shape and allowing to set. They are applied by pouring a standard concrete foundation, spreading sand on top, and then laying the pavers in the desired pattern. No actual adhesive or retaining method is used other than the weight of the paver itself except edging. Pavers can be used to make roads, driveways, patios, walkways and other outdoor platforms.

 

Gravel:

A gravel road is a type of unpaved road surfaced with gravel that has been brought to the site from a quarry or stream bed. They are common in less-developed nations, and also in the rural areas of South Africa. In New-Zealand and other Commonwealth countries, they may be known as ‘metal roads‘. They may be referred to as ‘dirt roads’ in common speech, but that term is used more for unimproved roads with no surface material added. If well constructed and maintained, a gravel road is an all-weather road.

 

Sources:

https://globalroadcom/road-construction

https://en.wikipedia.org/wiki/Road_surface

https://pixabay.com/en/road-asphalt-freeway-route-travel-691127/

https://en.wikipedia.org/wiki/Road

https://commons.wikimedia.org/wiki/File:Hex_pavers_sliding_to_Hudson_W60_jeh.jpg

https://pixabay.com/en/photos/gravel%20road/

If you are interested in becoming one of our subscribers, please visit our website.
To view notes with screenshots on how to use our website, please visit our Wiki site.
To view more articles, please visit our blog.

About Devika Suresh

I started at Leads 2 Business in January 2010 (12 Years ago). I am presently Deputy HOD of L2Q. I started in the Daily Tenders Bills department and worked my way up to the L2Q department.

L2B Blog: Reporting for Dummies (Part 2)

 

Your Online Footprint:

 

A. Online Activity – This details your overall usage statistics, such as how many searches you have performed, items you have viewed, downloaded, monitored or annotated, you can search up to 3 months.

By clicking on the blue links, you will be able to view the specific Projects / Tenders viewed or monitored over the period selected.

 

B. Site Engagement – provides a graph showing the number of searches performed on the site and the number of Leads that have been tagged within the time period chosen, not exceeding 3 months.

By clicking on the headings, you can expand the categories to see the searches performed and you can choose to perform that specific search again, or to display the date, name of tag and item tagged.

 

C. Project Engagement – This details your engagement with Project Leads. Informative graphs illustrate your Industry focus, what stage of the project lifecycle is beneficial to your business, which geographical area you target and the allocation of potential revenue values across the projects you monitor, can be searched for the last 3 months.

 

D. Tender Engagement: This details your engagement with Tender Leads. Informative graphs illustrate your Industry focus, which geographical area you target and the allocation of potential revenue values across the tenders you monitor. You can search for up to 3 months.

 

E. Vendor Engagement: This details your engagement with the Requests for Quotes you have received from Buyers on our site. It showcases the Requests you have responded to by pricing online /offline or declining to price. You can perform a search for three months.

By clicking on the headings, you can expand the various categories to see the specific instances where you have priced online, submitted your intension to price, declining to price or not responded to a RFQ.

 

F. Buyer Engagement: This details your engagement with Bills of Quantity you have sent using our electronic pricing distribution system for up to a range of 3 months.

With regards to all the graphs, you have the ability to download the graph to the following formats: png, jpg or pdf. You can also annotate the graphs with your own notes and observations and open the graphs to full screen.

 

Part 3 of Reporting for Dummies coming soon…

About Cecile Van Deventer

I joined the L2Q Team in 2006, as a L2Q Support Assistant and have been the HOD since 2010. I supervise L2Q Bills, Daily Tender Bills, Control Lists and Directory.

Potholes and Pitfalls in civil engineering contracts

Potholes and Pitfalls in civil engineering contracts

Potholes… an infrastructure issue that deserves a whole blog to itself! How often during your travels (be it your annual drive down to your favourite holiday spot, or your daily route to work) do you face the inconvenience of roadworks? I think all of us experience this from time to time. It goes on for months, sometimes even years. Finally, the works are completed and we breathe a sigh of relief. No more queues of traffic or uneven road surfaces, no more narrowing down to one lane. Phew! At last. A few weeks down the line…. a POTHOLE!!?? The blame gets shifted around quite a bit between all the parties involved in the contract, but where does the problem really lie?

 

I must admit. This blog title planted a new “anxiety seed” in my brain, and I found myself trying to put on a civil engineer’s shoes (figuratively, not literally).
I follow the progress of numerous infrastructure projects (but not pothole repairs!) in the department that I work in – the Projects Department. Or more affectionately known as the PP office. A few months (usually about 3 months) after a Tender is advertised for a civil engineering contract, we follow up with the relevant contacts in order to obtain the awarded civil engineering company’s details. We then contact the civil engineer and follow the design process, then the tender and construction progress, until the Project is complete. We do not delve too deep into the issues that may be presented during or after the life-cycle of the project, however, we do try to ascertain if or how those problems will affect the time frame of the development.

 

During my research for this topic, and on more than one occasion, education and training seemed to be a major area of concern when looking at civil engineers in the public sector. South Africa’s public sector appears to have very few professionally registered civil engineers and some of the engineers are placed in positions without possessing the required skills and experience. This could lead to errors in proposals when tendering for contracts and can have serious consequences.

 

Numerous failed infrastructure projects throughout South African history must surely be making things a bit more difficult for companies to win civil contracts. I would imagine that quality standards have been raised in order to improve public health and safety. These standards would hopefully be imposed on both engineering and construction firms, as both (among other professionals) are just as important in the quality of the completed project.

 

One example of a failed project is the collapse of the P166 bridge over the N4 in Mpumalanga in 2009. The beams collapsed and blame was shifted between a speeding truck which caused vibrations while travelling under the bridge, to vibrations caused by jackhammers and manufacturing errors. Another concern was the amount paid for the beams – it was substantially lower in comparison to what other engineers said the beams would usually cost. Sub-standard materials constitute a huge issue and can end in disaster.

 

The Foreshore Freeway Bridge in Cape Town is a well-known incomplete road structure. The bridge was designed in the 60s, and in the early 70s construction commenced. Construction was halted in 1977, apparently due to a lack of funding. However, rumour has it that there was an error in calculations during the design phase and that the two ends of the bridge would fail to meet!

By Flickr user Paul Mannix – https://www.flickr.com/photos/paulmannix/552103944, CC by 2.0, https://commons.wikimedia.org/w/index.php?curid=46305687

 

Perhaps one of the most spectacular bridge collapses in the world was that of the Tacoma Narrows Bridge (also nicknamed Galloping Gertie) in the USA, over 76 years ago due to strong winds. The design of the suspension bridge did not allow wind to pass through the sides, causing the bridge to sway and eventually collapse. It only stood for about 4 months after completion before disaster struck. Lessons have been learned and the way in which future suspension bridges are designed, have changed. The parts of the bridge that plunged into Puget Sound have formed a man-made reef, which is protected by the National Register of Historic Places. Click here to see the video, and to see where the bridge got its nickname.

By Barney Elliott; The Camera Shop – Screenshot taken from 16MM Kodachrome motion picture film by Barney Elliott, Fair use, https://en.wikipedia.org/w/index.php?curid=23093518

 

Project failures, such as the ones I have mentioned above, can cast a dark shadow over the industry – an industry which is partly responsible for ensuring that our country’s infrastructure withstands time, utilising taxpayer’s money in a responsible manner. It is critical that we recognise the importance of skilled civil engineers and that employees of the profession look to improve their skills if given the opportunity.

 

Don’t get me wrong, we have some excellent civil engineering structures on our continent. The Maputo / Catembe Bridge, a 680m suspension bridge standing 60m over the water between Maputo and Catembe, is just one example to prove that:

 

Sources:
https://www.businesslive.co.za/fm/features/2017-03-16-cracks-in-the-walls/

http://www.lowvelder.co.za/index.php…news&Itemid=98

https://en.wikipedia.org/wiki/Tacoma_Narrows_Bridge

https://en.wikipedia.org/wiki/Foreshore_Freeway_Bridge

http://journals.co.za/docserver/fulltext/civeng/24/2/civeng_v24_n2_a13.pdf?expires=1493899313&id=id&accname=guest&checksum=2EB4C398FA20074700668F139373D9BDhttp://www.africaranking.com/top-10-longest-bridges-africa/3/

About Bianca Warwick

I had the privilege of joining the Leads 2 Business content team in January 2012. I work in the exciting Projects department, following the progress of construction developments in KwaZulu-Natal and the Free State.

Featured Project: Setlabotsha Mine Project, Mpumalanga

Description: Anglo Operations proposes the development of the Setlabotsha Mine located near Standerton in the Lekwa Local Municipality and the Gert Sibande District Municipality in Mpumalanga Province. The proposed Setlabotsha project will involve the extraction of coal by means of underground mining methods. The coal resource will be accessed by two new shafts and the coal will be transported via a new overland conveyor to the existing new Denmark Colliery. No processing will take place at the Setlabotsha shaft complexes.

Status: Procedural

Industry: Infrastructure

Region: Mpumalanga

Sector: Private

Value: R 100 million+

Timing: 2017 onwards

Notes: Anglo has appointed SRK Consulting as the Independent Environmental Assessment Practitioner to undertake the environmental authorisation process for the proposed project. The Scoping Report was submitted to the DMR in December 2016 and they are currently evaluating the Report. DMR Ref MP 30/5/1/2/2 1015 EM

If you are a valued Projects subscriber, you can find more details click here

About Marlaine Andersen

Leads 2 Business Advertising Co-ordinator and Digital Designer

Featured Tender: Upgrading from Gravel to Surface Standard of Road 479 from Khunotswana Village Towards N4 at Tweefontein

Contract Number: PWR127/14 – Department of Public Works and Roads

Description: Department of Public Works and Roads Mmabatho invites tenders for Upgrading from Gravel to Surface Standard of Road 479 from Khunotswana Village Towards N4 at Tweefontein approximately Six (06) Kilometres.

Industry Sector: Road

Industry: Infrastructure

Region: North West

Site Inspection: A compulsory clarification meeting with representatives of the Employer will take place at Khunotswana Tribal Hall on 18 May 2017 starting at 10:00.

Closing Date: 02 June 2017 at 11:00

Restrictions: It is estimated that tenderers should have a cidb contractor grading of 7CE. Preferences are offered to tenderers who 7CE or higher. Telephonic, Telegraphic, Telex, Facsimile, Emailed and Late Tenders will not be accepted. Tenders may only be submitted on the tender documentation that is issued. Requirements for sealing, addressing, delivering, opening and assessment of Tenders are stated in the Tender Data.

If you are a valued Tender subscriber, Click to find more details about Upgrading from Gravel to Surface Standard of Road 479 from Khunotswana Village Towards N4 at Tweefontein

About Claire Donaldson

I started working at Leads 2 Business in February 2005, and have served as Head of Department of Daily Tenders from 2007 until the present. I oversee both the Daily Tenders South Africa and Africa Departments.

Did you know #DYK – Cost to build Roads

Cost to build Roads

Cost to build Roads

What is a road?

 

A road is a thoroughfare, route, or way on land between two places that has been paved or otherwise improved to allow travel by foot or some form of conveyance, including a motor vehicle, cart, bicycle, or horse) https://en.wikipedia.org/wiki/Road which costs a vast amount of money to build

 

The question “Cost to build Roads” was ignited from Trevor Manual’s speech to CESA (Consulting Engineers South Africa) dated 08 October 2009 (#throwback) where he had mentioned the high cost of building of roads in South Africa.

 

Please Click on link to view the speech: http://www.cesa.co.za/cesaway_presentations/Trevor_Manuel_%20Speech.pdf

Flanders Drive Intersection – Mt Edgecombe:

This is a very difficult question to answer as road construction costs may vary as there are many factors to consider when building a road, please view the list below:

  • Design
  • Amount of environmental mitigation required
  • Terrain
  • Soil Conditions
  • Type of Roads
  • Width of Roads
  • Road Standards
  • Machine and Labour Costs
  • Skill of operators and labours
  • Accommodation
  • Contractors operating cost (such as fuel, labour, interest rates, insurance)
  • Traffic Management
  • Safety Aspects of pedestrians, detours
  • Time available to complete the task
  • Time of the year
  • Construction materials used
  • Availability of materials (shipping material outside the province vs using local materials)

“Road construction techniques are similar throughout the world, you can possibly achieve cost estimates once the main conditioning factors have been identified, by applying figures from similar Road construction projects. For reasons of comparing costs, it is advisable to break down labour and machine costs into different elements. The following breakdown is suggested: Surveying, staking the alignment and clearing right of way; formation of the road; rock blasting; Draining facilities (ditching, culverts); Crushing gravel; Gravelling, grading and compacting; Construction and environment protection works (bridges, retaining structures and soil stabilisation works). The cost of construction; Miscellaneous works (such as transport, delivery and minor earthworks; Projects servicing costs). Once the costs have been calculated for the different elements, unit costs (costs per m, per square m, per piece of construction work) should be developed to facilitate in estimating costs in future road projects and for comparative purposes. http://onlinecivilforum.com/site/index.php/2016/10/27/road-estimate-excel-sheet/

 

What does 1 km of road cost to build in South Africa? Up to R25 million per km according to CSIR (this information is sourced from the link below if you beg to differ please let us know): http://www.answers.com/Q/What_does_1km_of_road_to_build_cost_in_south_africa

 

The question still remains to be answered why are the construction cost of roads still so high and are they paved with “gold”?

 

For your information from OUTA (Organisation undoing Tax abuse): Please see Paper on High Pricing, Collusion and Capture of National Road Construction.

 

Please click to view active (Road) Projects currently on our system:

About Pauline Rainbird

I have been working at L2B since March 2011 and my current position is Deputy Head of Department - Africa. When I am not working I am either riding my bicycle or spending time with my dogs.

Industry Event: African Utility Week + Indutec 2017 + Hostex 2017

1. Event:

African Utility Week

 

Date:

16 May 2017 – 18 May 2017

Site visits on 19 May 2017

 

Event location:

CTICC, Cape Town, South Africa

 

Event Description:

The 17th annual African Utility Week is the only global meeting place, conference and trade exhibition for African power and water utility professionals. African Utility Week offers a unique networking opportunity for engineers, stakeholders and solution providers alike.

 

Contact:

Exhibition space/sponsorships:
Loudon Cito, Business Development Manager

Tel: +27(0)21 700 3564
E-mail: loudon.cito@spintelligent.com

and

Conference passes/submit a paper:
Natalie Bacon, Senior Conference Producer

Tel: +27(0)21 700 3585
E-mail: natalie.bacon@spintelligent.com

 

Event Website:

African Utility Week

 

 

2. Event:

Indutec 2017 incorporating PVP Live & WaterTec Conference

 

Date:

17 May 2017 – 19 May 2017 from 10:00 – 16:00

 

Parking:

Security monitored parking is available in an open air opposite the venue as well as behind Hall 5. The cost per day is R20

 

Event location:

Gallagher Convention Centre, 19 Richard Drive, Midrand, Johannesburg, 1685

 

Event description:

The largest and most comprehensive African Tradeshow dedicated to the Industries involved in the Conveyance of Liquids, Gases & Slurries.

 

Contact:

Tel: +27 11 783 7250
Email: info@indutecafrica.com

 

Event Website:

Indutec 2017

 

 

3. Event:

Hostex powering Food and hospitality Africa and IFEA 2017

 

Date:

07 May 2017 – 09 May 2017

Sunday to Monday, 09:00 – 17:00

Tuesday, 09:30 – 16:00

 

Event location:

Gallagher Convention Centre, Johannesburg

 

Event description:

Hostex powering Food and Hospitality Africa and IFEA 2017 is the largest Pan-African food, drink and hospitality trade expo. It is the ultimate melting pot for the foodservice, hospitality, catering, retail and wholesale industry and leverages the synergies, size and scale of two industry heavyweights, namely the 30-year-old Hostex and innovative IFEA expos.

 

Contact:

Nick Sarnadas (Event Director)

Tel: +27(0)11 835 1565

 

Event Website:

Hostex powering Food and hospitality Africa and IFEA 2017

About Eldary Carpenter

I have been with Leads 2 Business for 5 years and absolutely love working for such a dynamic company. I started off as a Content Researcher in the Tenders Department before being promoted to Customer Relations.

L2B Blog: 5 Ingredients in the Constructions of a Road

5 Ingredients in the Constructions of a Road

5 ingredients in the Construction of a Road

Have you ever baked a cake and realised you forgot to add the flour or the baking powder? What tends to happen? Your cake flops or does not rise. Building a road is similar, but a lot more complex. There are so many ‘ingredients’ and important aspects that need to be considered before and during the construction of a road.

The first step to constructing a road would be planning. Your engineer/consultant would come on site and decide what type of road will be built and what materials would be used to construct the road. This will all depend on how much traffic will occupy this road. Even the simplest of roads can take up to months or possibly even years for the planning of the road. The engineer will need to evaluate many factors such as the environmental impact of the road, the availability of materials needed to construct the road, will the road be safe and, the most important factor, the cost of the road. These plans will be written into a final proposal where the consultants will need to evaluate these plans. Meetings will take place with all parties concerned and all the pros and cons will be discussed in vast detail. Without proper planning and careful consideration of all these factors, there is a chance that the foundation will collapse.

Shortly after careful planning and long and tedious meeting’s the plan will either be approved or rejected. We are going to assume that the planning was approved. The next step would be the construction of the actual road.

Ingredients used to construct a road:

 

1. The standard Foundation:

Bulldozers and graders, which are two types of machinery, will be used to flatten the ground surface. This ground layer will make up the bottom layer of our road

(https://commons.wikimedia.org/wiki/File:Afghan_engineers_work_on_a_road_construction_project_in_Panjwa%27i_district_at_Forward_Operating_Base_Shoja_in_Kandahar_province,_Afghanistan,_March_28,_2013_130328-A-PV892-022.jpg)

 

2. Gravel:

The gravel will be added in layers where a roller machine will be used to roll over this surface to ensure that the surface is compact and flattened

https://commons.wikimedia.org/wiki/File:Gravel_small_stones.jpg

 

3. Drainage facilities:

Drainage facilitates play a huge role in ensuring that the road is safe at all times from water backlogs. We are not able to control the weather and for this reason, we need to ensure that the road never gets saturated and water-logged. Firstly it is not safe for drivers on the road and secondly, the road will soon disintegrate and start deteriorating over time. Examples of drainage facilities would be drain and storm water sewers.

https://commons.wikimedia.org/wiki/File:Storm_drain_pipe_(crop).JPG

Once the foundation is complete and compact and has been inspected by the consultant, it is time to pave the road!

4. Asphalt / Bitumen

Asphalt uses an oil based substance called bitumen to make sand and crushed rock stick together like a glue-like substance. The asphalt is heated to +- 300 Degrees Fahrenheit (148,88 Degrees Celsius), where it

will be transported to the site where the construction team will spread the mixture evenly across the smooth gravel service. The mixture is rolled over the gravel surface where it will form a solid layer on the top.

https://commons.wikimedia.org/wiki/File:AF-asphalt-laying-machine.jpg

 

5. Concrete Slabs

The finishing touches will be the concrete slabs that are laid on the side of the roads. Workers will pour liquid concrete into a steel mould called forms. A finishing machine is used to shake these moulds to ensure the mixture is distributed evenly for an even finish. The concrete slabs are laid alongside the road where incisions in the road are made to allow the concrete to expand and contract depending on the temperature, this will ensure that the road does not crack

https://www.google.co.za/search?q=Concrete+Slabs&source=lnms&tbm=isch&sa=X&ved=0ahUKEwi7xaKyytXTAhVCwBQKHZTXCEIQ_AUIBigB&biw=1600&bih=751&dpr=1#tbs=sur:fc&tbm=isch&q=laying+Concrete+Slabs+for+a+road&imgrc=szGP9Kx5Ii-zkM:

 

Every day we take our course of life, may it be a trip to the shop or work and take for granted these roads that we drive on. Most people think they just appeared or are set up overnight by machinery. The planning and work that goes into these roads are far more complex than most can imagine.

 

Sources used:

http://wonderopolis.org/wonder/how-do-you-build-a-road

https://en.wikipedia.org/wiki/Road

 

About Roxanne Mustard

My Name is Roxanne Mustard and I started working at Leads 2 Business in September 2016. My role in the Leads 2 Business team is as a Regional Content researcher in the Projects Department.

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