Cost of structural steelwork

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Cost is a fundamental consideration in the selection of structural frame material and form, which is a key early decision in the design process. This selection should be based on project specific costings, and the challenge to the cost consultant is to recognise and reconcile fluctuations in material prices in relation to returned tender price data all in the context of limited available design information during early estimates.

This article outlines a number of key cost drivers that must be considered in order to make steel frame rates project specific, and provides guidance on current cost ranges for different building types and locations. Through the identification of the key factors relevant to each project and the adjustment of typical rates accordingly, the accuracy of budget structural steel estimating can be significantly improved.

The information presented here is based on a series of articles written by Gardiner & Theobald LLP, and published in Building Magazine from October 2011 to October 2016. This has been developed further with information from a series of articles written by AECOM, also published in Building Magazine, from 2017 onwards.

               Costing Steelwork-18.jpg


Main articles: Cost planning through design stages, Cost comparison study

               K1 Fig3.png
Complex service routing through and between steel beams

For most projects, the decision on the frame material choice and form happens early in the design process, often on the basis of early design principles, limited information and budget costings. Once selected, the frame material is unlikely to change, as to do so can have significant programme implications from the consequential impact on the design of other major elements, such as cladding, service installations etc.

While the decision on frame type for most developments will not be based on cost alone, it is nevertheless a key consideration in the decision making process and it is vital to support informed decision making with realistic cost information at this early stage, before refining during the detailed design stages. This is a challenging task as the cost of structural steel may fluctuate through the economic cycle, and reconciling material price information with returned tender prices is not always straightforward. Steel frame costs are also heavily affected by project specific key cost drivers, such as programme, access, spans and building form, making accurate adjustment of recently tendered rates or cost models difficult.

For those with limited previous experience of steel framed construction, the unique characteristics of the sector may not be immediately apparent. Anecdotal stories point to design decisions being made on the basis of non or poorly adjusted historic steel rates, suggesting that the complexities of the industry and the significance of key cost drivers are not necessarily widely understood.

Steel’s high market share for multi-storey buildings of around 65% and a review of recent industry trends highlights the importance of maintaining current, market tested cost advice for structural steelwork. Through a consideration of a number of key factors and consultation with the market and supply chain, budget structural steel estimating can be quickly and successfully tailored to specific projects.

[top]The importance of realistic steel pricing

As the selection of frame material is a key design decision and impacts on so many related building elements – foundations, finishes, wall to floor ratio and cladding to name but a few – once the decision has been made and design has progressed, it is disruptive and generally abortive to make fundamental changes to the frame type or form. To do so would involve going back over design stages already completed and will involve most of the design disciplines. Where there is a programme to be maintained, this is almost impossible to achieve. Therefore, although the period of time to identify and select the best value frame is not a long one, it should not be rushed.

By its very nature therefore, the decision is commonly based on outline design proposals, with a limited amount of information available to the cost consultant.

Where the initial budget estimates of steel frame costs are not realistic, the wrong frame solution can be selected at a higher cost of not only the frame but potentially also the related building elements. It can also have an effect on buildability, logistics and the construction programme, as the frame construction is a critical path activity.

[top]Making the most of the available information

At the early design stages of any project, cost models, benchmarks and historic cost data are key tools used by cost consultants in the estimating of all building elements. At this stage, elemental costs, including that of the structural frame, will usually be expressed as a rate per m² based on the Gross Internal Floor Area (GIFA).

Typical cost ranges for different frame types can be developed through cost models, and there are some indicative ranges given as part of this article, but how should one pitch the rate for any specific project?

Rather than arbitrarily using the highest rate of a range, it is key to interrogate and understand what those rates buy and how the standard ranges can be adapted to suit project specific factors. To do this most accurately, the cost consultant needs to ask relevant questions of the design team and to speak to the supply chain to use this information effectively. This will build a picture of the current and short term future market, rather than relying on indices to adjust benchmark or historic rates.

[top]Key cost drivers

A number of factors can be considered to have a key impact on the price of structural steel frames. These ‘key cost drivers’ can be reviewed as part of the following groups:

[top]Function, sector and building height

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A typical low eaves industrial shed

Different building functions across different sectors have varying typical frame costs due to their different usages of the created floor space. The usage of the building will influence the design loadings considered by the structural engineer and the building function will also result in different requirements for clear spans and floor-to-floor heights. This means that the average weight of the steel frame will vary between building types. For example, a low eaves industrial ‘shed’ building could have a frame weight of 40kg/m² GIFA, while a city centre office with a long spanning grid to avoid a forest of columns could have a weight of 90kg/m² GIFA.

A requirement for fewer columns will lead to longer spanning beams and heavier steel sections, which can increase the overall weight of the frame and therefore the cost range for the building. Clearly, these factors need to be considered when determining the rate for the structural frame for early estimates. Confirmation of the design assumptions and principles with the structural engineer is essential to clarify this.

It is also important to remember that the rate per m² is based on gross internal floor area, which will not account for variances in floor-to-floor heights. If for a specific project these are outside the normal range utilised in cost models, a higher or lower rate should be considered to tailor indicative rates to the project.

[top]Form, site conditions and complexity

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Complex structural steelwork at Cabot Circus, Bristol
(Image courtesy of S.H.Structures Ltd.)

The complexity of the structure is closely related to building form and function, as well as specific site conditions. The building form will have an impact on the regularity of the structural grid, and the need to introduce non-standard sections, a wide range of different sections and connections in order to achieve structural stability.

Complex structural solutions, such as transfer structures, and fabricated beams may also need to be introduced to overcome project specific features or restrictions such as retained facades, adjacency of other buildings, ground conditions and so on.

The inclusion of non-standard sections will also increase the overall frame rate as fabrication costs are higher. Complex connection details may also impact on installation costs, tolerances and interfaces.

[top]Location, logistics and access

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A congested city centre site, Park House, London
(Image courtesy of Severfield plc.)

The location of a project is a key factor in price determination and indices are available to enable the adjustment of cost data across different regions. The variances in these indices, such as the BCIS Indices, highlight the existence of different market conditions in different regions, which must not be overlooked.

Not only is the geographic location of the site an important consideration, site specific features also need to be reviewed. While the designed frame solution of two buildings may be very similar, the logistics and access arrangements will vary significantly between a city centre congested site and an easily accessible, isolated business park or industrial estate site, or even between alternative city centre sites.

Working in city centre or occupied areas can mean restrictions to working hours, noise, deliveries and craneage, all of which influence installation costs and can result in an extended on site programme. As the frame construction is generally a critical path activity, any increase to the construction programme will have an associated impact on project cost.

[top]Programme, risk and procurement route

Accurate forecasts of steel frame costs are challenging due to the uncertainty of general economic conditions and the fluctuation of material prices experienced in the UK steel industry through the economic cycle.

Construction sector sentiment reached near record highs recently and general business sentiment continued to rise as the UK economy reopened more. Improving construction workload powers this optimism. However, significant supply-side issues around workforce constraints and materials procurement also muddy the waters in the belief that everything is due to higher output levels across all sectors. Activity is expected to remain busy in the second half of 2021 as consumer demand returns across a larger number of economic sectors. Business sentiment conditions therefore are likely to remain elevated as a mix of expected and real improved sales and revenue occur over the remainder of 2021. But real risks remain of further bumps in the road from the pandemic, and a potential return of restrictions in some form should events deteriorate again. What will become clearer is the proportion of the rebound that is from the short-term cyclical spike, and that which is driven from the strength of underlying demand and structural factors propelling economic activity.

After faltering in early 2021, construction output regained momentum and took another leg up in the second quarter, according to the latest data from the Office for National Statistics (ONS). This helped return new work output levels towards pre-pandemic totals but was still about 5% shy of this milestone. Underscoring the undulating nature of the rebound, all work construction output volume declined for the fourth month in a row with the release of July’s data.

Across the UK, the private housing and infrastructure sectors led the way in output rebounds. Infrastructure workload continued its strong growth trend out of 2020, and now clearly surpasses its pre-pandemic levels. Within this sector, electricity, gas, and communications utilities work all recorded strong rates of growth over the two-year period from the start of 2019. In a further sign of construction industry durability, the largest sector by volume – private housing – has now recovered a substantial part of the ground lost during 2020. The commercial and private industrial sectors are still some way off returning to a pre-pandemic level.

Tender price trends
AECOM’s composite index for building costs – comprised of materials and labour inputs – increased by 8.5% in the 12-months to Q2 2021. This is a headline figure, aggregating many different materials classifications and which masks a wider range of inflation rates for individual items. The largest increases continued to be in metals and timber products, especially those which are imported. A rolling quarter-to-quarter change for the composite index at June 2021 recorded a movement of 2.6%. The month-on-month change at June for materials only was 0.91%, equivalent to 11% annualised approximately. This underlines the notably elevated rate of input cost inflation currently.

Labour rates are increasing healthily again, after dipping last year in response to lockdowns and impaired demand for site trades and skills. Year-on-year change of broadly 8% for a collection of site trades is the current headline rate for wage inflation. However, similar to materials classifications, this does not convey the broader range of wage inflation for the different trades that make up the headline figure. Steelwork trades and bricklayers are seeing wage inflation of 15-20% over the year to Q2 2021, although this figure is influenced by the dip in wages at the same time last year. Nevertheless, it highlights the strength of demand for key trades.

Tender price inflation
Quarter 2017 2018 2019 2020 2021 2022 2023
1 110.9 113.2 117.9 120.4 120.0 126.5 131.2
2 111.3 113.6 118.3 121.0 122.2 127.7 132.5
3 112.2 115.4 119.3 119.1 123.7 128.8 133.9
4 112.6 117.3 119.8 119.1 125.3 130.0 135.3

Aecom Tender Price Index: 2015 = 100

An aggregate measure of tender prices increased by 1% in the 12 months to Q2 2021. A denominator calculation effect influences this rate of change as Q2 2020 was the point at which tender prices peaked, according to AECOM analysis. Provisionally, Q3 2021 sees an approximately 4% increase over the year from Q3 2020 to Q3 2021. There is clear momentum now to increase prices in response to better output and demand for construction services, and also address the acute pressure to recover significantly higher input cost trends over the latter parts of Q1 and Q2 2021. Overwhelmingly, trades that involve metals saw the steepest price rises in the last quarter. Materials input cost inflation is the largest driver of tender price rises but is also pushed higher by labour rate increases.

Not all of the materials cost inflation is transferred into tender prices at the moment, because not all of it can be without some impact to competitive positioning. Price changes will take longer to secure than the quick changes to input costs experienced over the first half of the year. Some of the input cost inflation is absorbed at various stages along the supply chain. But the high cost inflation adds commercial pressure to the supply chain, and is difficult to sustain over an extended period without creating problems for company financial management.

AECOM’s baseline forecast for tender prices are a 4% increase from Q3 2021 to Q3 2022, and 4% from Q3 2022 to Q3 2023. Risks are to the upside across the first 12-month period and with upside risks again over the second 12-month forecast period. The baseline forecast scenario sees a continuation of the incomplete economic recovery. Significant inflationary pressures will remain.

[top]Components of the structural frame cost

In addition to understanding the cost drivers discussed above, it is also important to appreciate the different elements that make up the overall cost of the structural frame, their typical relative proportions and the interrelationship between them.

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Breakdown of costs of steel frame for a typical multi-storey commercial building

It is often assumed that a frame with the minimum tonnage will also have the lowest cost. However, as the figure (left) shows, the raw material cost typically accounts for only 30-40% of the total frame cost, with fabrication costs also accounting for 30-40%. For more complex frame designs, with higher proportions of non-standard sections, complex connections or specialist systems with higher fabrication requirements, the overall rate per tonne is likely to be higher than for a standard frame.

The construction of the steel frame typically accounts for around 10-15% of the total frame cost. It is therefore necessary to consider whether there are features of the proposed building that would significantly affect the erection cost as this will see a corresponding impact on the total cost of the frame. The extent of repetition, piece count, the type of connections to be used and access can all have a significant impact on the cost of constructing the frame.

[top]Current cost

This article seeks to give some current indicative cost ranges for structural steel frames for three key building types:

All of the costs include allowances for a concrete core. The rates have been developed from cost models of the different building types and for each the average weight of the structural frame has been given.

As already highlighted, before using such ‘standard ranges’ it is important to confirm the anticipated frame weight and variables such as the floor-to-floor heights with the design team to determine whether they are above or below the average and to adjust the rate used accordingly. Similarly, all of the other key cost drivers of complexity, site conditions, location, function, logistics, programme and procurement strategy should be considered in turn.

[top]Low rise and short span buildings

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Low rise, short span building
Rhyl New School

Low rise buildings with a regular, short span structural grid are typical features of business park offices and teaching facilities. A key feature of these buildings is flexibility, particularly for speculative business park developments that need to appeal to as many potential occupiers as possible.

The buildings often need to be easily subdivided into smaller units and have large floorplates, typically are two to four storeys and have floor-to-floor heights of 3.75-4m. These buildings will typically have a uniform grid of 6-9m that provides largely column-free space and relatively high floor-to-floor heights.

The lack of complex steel structures needed to construct the regular grid contributes to keeping the average steel frame weight down, typically 50-60kg/m2 including fittings, but this category can cover a lot of building types and functions. This central assumption therefore needs to be reviewed with the design team. Due to the low rise nature of these buildings, the fire protection requirements are not as onerous as for high rise developments and 30-60 minute fire protection would be considered standard.

More detailed information on the key cost drivers for low rise and short span buildings is available in a related article on Cost planning - Education buildings

[top]High rise and longer span buildings

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Multi-storey city centre project, Snow Hill 2, Birmingham
(Image courtesy of Kloeckner Metals UK Westok and Caunton Engineering Ltd.)

High rise construction (10-15 storeys) is a typical feature of city centre construction. These buildings will often require longer structural grid spans to achieve more open space in the lettable floor areas, increasing the weight of the steel frame. To maximise floor-to-ceiling heights and increase flexibility for the building fit out, cellular beams may be adopted with openings through the web for the distribution of services.

City centre buildings are generally constructed on existing confined or irregular sites, which influence the building form and is likely to prevent the use of a regular column grid and may result in alterations to floor plates on the upper storeys.

In mixed-use schemes, transfer structures may reduce the wider grids of office or retail areas at lower levels to a more rationalised residential grid on upper floors.

All of these factors contribute to a higher average weight of the steel frame, typically 75-90kg/m² including fittings and, along with the increased complexity, result in significantly higher structural frame cost ranges than for the simpler, more regular low rise buildings.

The rate range given in the cost table below is generally applicable for buildings up to about 15 storeys; tall buildings above 15 storeys start to have fewer comparables in terms of benchmarks and are likely to have a much higher proportion of complex elements, non-standard sections sections and complicated logistics, especially when constructed on tight city centre sites. The rate range for tall buildings can be 15-20% higher than the top of the standard range.

More detailed information on the key cost drivers for high rise and longer span buildings is available in a related article on Cost planning – Multi-storey offices

[top]Industrial buildings

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A high eaves industrial shed
(Image courtesy of Caunton Engineering Ltd.)

Industrial buildings can cover a range of uses, including warehouses, non-food retail, science parks and distribution centres. The most common building form is a single storey warehouse with varying proportions of office space on a first floor mezzanine level. The traditional structural frame for an industrial building is a steel portal frame, as flexibility of the internal space is a priority, necessitating regular column spacings and long spans for a clear internal area.

There can be variants on the standard frame design, however. For example, a steel portal frame incorporating northlights would need consideration when adjusting the standard cost ranges. The use of a northlight frame can increase the frame cost by as much as 30%.

Fire protection requirements may also be considered as part of industrial building frame costs. The most common situation in which fire protection is required in single storey buildings is where it is necessary to satisfy boundary conditions; this is a project-specific factor that will need some liaison with the design team. Generally however, single storey buildings do not require fire protection.

Another key factor in determining the frame cost of industrial buildings is the storey height of the warehouse space. While the gross internal floor area may be the same, the weight of the steel frame of a high eaves, single storey industrial building will be higher than for a low eaves building, resulting in a higher overall frame cost per m² GIFA.

Typical structural steel frame weights for low eaves buildings (6-8m high) are about 30-40kg/m² overall of GIFA, including fittings and about 40-50kg/m² for high eaves buildings (10-13m high). However, ranges for high eaves buildings are generally wider than for low eaves buildings as they can have a much higher proportion of upper floor areas, across as many as 3 mezzanine levels; the frame rates for these buildings therefore need to be looked at carefully on an individual basis.

[top]The cost table

The table below represents the costs associated with the structural framing of the three building types expressed as a cost/m2 on GIFA, and also provides some indicative cost information on floor types and fire protection.

Table of indicative cost ranges (Q3, 2021) based on Gross Internal Floor Area (GIFA)
Type GIFA Rate (£/m2)
BCIS Index 100
Frame Low rise, short spans, repetitive grid / sections, easy access (55kg/m2 steelwork) 127 - 155
High rise, long spans, easy access, repetitive grid (90kg/m2 steelwork) 214 - 242
High rise, long spans, complex access, irregular grid, complex elements (110kg/m2 steelwork) 242 - 286
Floor Composite floors, metal decking and lightweight concrete topping 73 - 114
Hollowcore precast concrete composite floor with concrete topping 114 - 161
Fire protection Factory applied intumescent (60 minutes resistance) 16 - 23
Factory applied intumescent (90 minutes resistance) 19 - 33
Portal frames Large span single storey building with low eaves (6 - 8 m) 95 - 123
Large span single storey building with high eaves (10 - 13 m) 108 - 149

To use the table:

  1. Identify which frame type most closely relates to the project under consideration
  2. Select and add the floor type under consideration
  3. Add fire protection if required

For example, for a low rise, short span building with a composite metal deck floor and 60 minutes fire resistance, the overall frame rate (based on the average of each range) would be:
£141.00 + £93.50 + £19.50 = £254.00 per m² GIFA

The rates should then be adjusted using location indices; the table provided below contains a selection of indices as published and updated by the BCIS.

Table of BCIS location factors (at Q3, 2021)
Location BCIS Index Location BCIS Index
Central London 128 Nottingham 104
Manchester 102 Glasgow 92
Birmingham 96 Newcastle 92
Liverpool 97 Cardiff 94
Leeds 93 Dublin+ 103

+Aecom index

[top]Cost planning through the design stages

Main article: Cost planning through design stages

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Integration of services with cellular steel beams
(Image courtesy of FABSEC Ltd.)

A key component of the cost of any building type is the frame which, for multi-storey buildings, accounts for approximately 10% of the overall building cost. The accuracy of any costing exercise depends on the level of design information on which it is based. As the design develops and more information becomes available, so the extent to which the cost can be detailed increases.

RIBA Stage 1 - 2
The budget set at the early stages of the design needs to reflect the final build cost despite limited information being available. This means rates used during this phase need to include items which are not yet quantifiable.

At this critical stage in the project much of the decision making on the frame construction method takes place. The steel frame design is represented as a relative weight (kg/m2) as opposed to a framing layout with beam sizes. Costs and rates based on a kg/m2 design intent should consider the following:

  • The steelwork quantity based on Gross Internal Floor Area (GIFA) or relative areas that the steel frame covers, which will depend on the building type and loading requirements.
  • How the kg/m2 benchmarks against similar buildings.
  • If the quantity of steel (kg/m2) accounts for fittings and steel-to-steel connections or whether an additional allowance needs to be made.
  • The potential mix of steel members: columns, beams, fabricated/sections, etc.
  • Consideration of the fire protection method and fire rating.
  • Non-standard details such as cantilevers and transfers.
  • The erection and lifting strategy and whether there will be a need for some members to be erected with mobile rather than tower cranes.

In addition, typical items that would not be covered in primary steelwork (kg/m2) but which will need to be considered include:

  • Secondary steelwork including framing to risers, lifts and cladding.
  • Connections to concrete or existing structures.

Following consideration of all of the above a ‘blended all in’ rate is then derived and applied to the calculated kg/m2. These rates will then be reviewed against similar projects and steel frame types which provide analysis against benchmarks.

Market testing should also be sought through consultation with steelwork contractors to ensure the accuracy of rates, forming a credible foundation for the steelwork costings to be developed in the subsequent design stages.

RIBA Stage 3-4
As the design progresses, technical information from the structural engineer on the proposed frame will become available, allowing a more accurate and developed quantification of the frame cost, which will now include a piece count and review of the design evolution.

Other information likely to become available at this stage includes:

The developing steel frame design can then be broken down into four components:

  • Main members: primary supports that carry the loads, such as beams, columns and trusses
  • Secondary members: those carrying specific loads
  • Fittings and connections: bracing, stiffeners and the joints that transfer forces between the structural elements
  • Miscellaneous items such as temporary steelwork, metal decking to composite floors, stairs, riser decking, external core angles, tower crane grillages, and stubs for BMU tracks.

It is still important at this stage in the design process to continue to determine and redress what has not been included within the drawings and ensure that these missing elements are taken into account. For example the extent of secondary members should not be overlooked as these can account for a significant proportion of the overall steel piece count and cost.

To calculate the cost of the structural frame, each of the components noted above will have a rate per tonne applied and then totalled. This rate should include the raw materials, fabrication, construction, fire protection, engineering and transport costs.

There are risks and limitations in cost planning steelwork based on a simple rate per tonne as this does not take into account specific features such as long-span beams, cranking or tapering, curvature of steel, hollow sections, cantilevers, irregularity of grid, back propping and movement connections, all of which may require an adjustment to the basic applied steelwork rate.

[top]Cost comparison study

Main articles: Cost comparison studies

In November 2011, the BCSA and Tata Steel commissioned Gardiner & Theobald (G&T), Peter Brett Associates (PBA) and Mace Group to undertake an impartial study of current construction practice for multi-storey office construction to provide cost and programme guidance for Quantity Surveyors and design teams. PBA identified and designed representative framing solutions for two typical office buildings (Building 1 - A business park office, and Building 2 - A city centre office). G&T provided cost information for each frame option and Mace considered buildability, logistics and programme. PBA also carried out a cradle-to-cradle embodied carbon assessment on Building 2. The costs were regularly updated by G&T through to October 2016, and published quarterly in Building magazine as the ‘Steel Insight’ series. The last update of this study is available here.

Later in 2016, the BCSA and Steel for Life commissioned AECOM to provide impartial cost guidance applicable to a broad range of construction professionals. Published quarterly in Building magazine, ‘Costing Steelwork’ is a series in which AECOM provides guidance on the key elements of costing structural steelwork. These articles examine the key cost drivers for different sectors and provide up-to-date cost ranges for various frame types that can be used as a comparative cost benchmark.

The series comprises studies into office, education, residential/mixed-use, retail and industrial buildings, and a key feature is a series of building type specific cost comparisons based on actual buildings. The buildings selected were originally part of the Target Zero study conducted by a consortium of organisations including Tata Steel, AECOM, SCI, Cyril Sweet and BCSA in 2010 to provide guidance on the design and construction of sustainable, low and zero carbon buildings in the UK.

The cost comparisons presented in the ‘Costing Steelwork’ series update the cost models developed for the Target Zero project, and provide up-to-date costs for the alternative framing solutions considered for each of the five building types.

[top]Office building

               One Kingdom Street-1.jpg
One Kingdom Street

The building used for the cost model is a multi-storey office structure; One Kingdom Street, London. The project is located in the Waterside regeneration area near Paddington railway station in Central London. This Grade A office building was completed in 2008.

The building’s key features are:

  • 10 storeys, with two levels of basement
  • Typical clear spans of 12m x 10.5m
  • Three cores - one main core with open atrium, scenic atrium bridges and lifts
  • Plant at roof level

Two structural options for the office building were assessed; a steel frame comprising fabricated cellular steel beams acting compositely with a lightweight concrete slab on a profiled steel deck, and a 350mm thick post tensioned concrete flat slab with a 650 x 1050mm perimeter beam.

The full building cost plans for each structural option have been reviewed and updated to provide current costs at Q3, 2021. The costs, which include preliminaries, overheads and profit and a contingency, are summarised in the table below.

Table of key costs (£/m2 GIFA), for City of London Office Building (Q3 2021)
Elements Steel cellular composite Post-tensioned concrete flat slab
Substructure 90 95
Frame and upper floors 498 475
Total building 3,174 3,252

The analysis shows that the cost of the steel composite solution is 4% higher than the post-tensioned concrete flat slab alternative in terms of the frame and upper floors, but 2% lower on a total building basis. The lighter frame weight and the increased speed of erection results in reduced foundations and a quicker programme. The reduced timescale is the main reason for the overall building cost to be less in the steel composite option.

[top]Secondary school building

               Knowsley School-1.jpg
Christ the King Centre for Learning, Knowsley, Merseyside

The building used for the cost model is the Christ the King Centre for Learning a secondary school in Knowsley, Merseyside.

The building’s key features are:

  • Three storeys, with no basement levels
  • Typical clear spans of 9m x 9m
  • 591m2 sports hall (with glulam frame),
  • 770 m2 activity area and atrium
  • Plant at roof level

Three structural options for the building were assessed; a steel frame with 250mm hollowcore precast concrete planks and a 75mm structural screed, an in situ 350mm reinforced concrete flat slab with 400 x 400mm columns, and a steel frame acting compositely with a 130mm concrete topping on structural metal deck.

The full building cost plans for each structural option have been reviewed and updated to provide current costs at Q3, 2021. The costs, which include preliminaries, overheads and profit and a contingency, are summarised in the table below.

Table of key costs (£/m2 GIFA), for Merseyside secondary school (Q3 2021)
Elements Steel and precast hollowcore planks In situ concrete flat slab Steel composite
Frame and upper floors 336 287 305
Total building 3,558 3,524 3,495

The comparative costs highlight the importance of considering total building cost when selecting the structural frame material during design. The concrete flat slab option has a marginally lower frame and floor cost compared with the steel composite option, but on a total building basis, the steel composite option has a lower overall cost (£3,495/m2 compared with £3,524/m2). This is because of lower substructure and roof costs and lower preliminaries resulting from the shorter programme.

[top]Distribution warehouse

               ProLogis Park-1.jpg
DC3 distribution warehouse, ProLogis Park, Stoke-on-Trent

The building used for the cost model is a distribution warehouse on ProLogis Park in Stoke-on-Trent.

The building’s key features are:

  • Warehouse: four-span, steel portal frame, with a net internal floor area of 34,000m2
  • Office: 1,400m2, two-storey office wing with a braced steel frame with columns.

Three structural options for the building were assessed; a steel portal frame with a simple roof solution, a hybrid option, consisting of precast concrete columns and glulam beams with timber rafters, and a steel portal frame with a northlight roof solution.

The full building cost plans for each structural option have been reviewed and updated to provide current costs at Q3, 2021. The costs, which include preliminaries, overheads and profit and a contingency, are summarised in the table below.

Table of key costs (£/m2 GIFA), for Stoke-on-Trent distribution warehouse (Q3 2021)
Elements Steel portal frame Glulam beams and purlins supported on concrete columns Steel portal frame with northlights
Warehouse 109 163 127
Office 157 197 157
Total frame 111 165 129
Total building 800 865 839

The steel portal frame option provides the optimum build value at £800/m2, with the glulam option being the least cost-efficient. This is primarily due to the cost premium for the structural members required to provide the required spans, which are otherwise efficiently catered for in the steelwork solution. The consequence of having a hybrid option is that the component elements are from different suppliers, which contributes to the increases in cost.

The northlights option is directly comparable with the portal frame in relation to the warehouse and office frame; the variance is in the roof framing. There is significantly more roof framing to form the northlights. The additional costs beyond the frame are related to the glazing of the northlights and the overall increase in relative roof area.

[top]Supermarket building

               Asda Supermarket-1.jpg
Asda supermarket, Stockton-on-Tees

The building used for the cost model is an Asda supermarket in Stockton-on-Tees, Cleveland.

The building’s key features are:

  • Total floor area of 9,393m2 arranged over two levels
  • Retail area based on a 12m x 12m structural grid.

Three structural options for the building were assessed; a steel portal frame on CFA piles, glulam timber rafters and columns on CFA piles, and a steel portal frame with a northlight roof solution on driven steel piles.

The full building cost plans for each structural option have been reviewed and updated to provide current costs at Q3, 2021. The costs, which include preliminaries, overheads and profit and a contingency, are summarised in the table below.

Table of key costs (£/m2 GIFA), for Stockton-on-Tees supermarket (Q3 2021)
Elements Steel portal frame Glulam timber rafters and columns Steel portal frame with northlights
Structural unit cost 165 202 186
Total building unit cost 2,909 2,954 2,920

The steel portal frame option provides the optimum build value at £2,909/m2, with the glulam option the least cost-efficient. The increased cost is due to the direct comparison of the steel frame solution against the glulam columns and beams/rafters. A significant proportion of the cost for the building is in the M&E services and fit-out elements, which effectively reduce the impact of the structural changes to the overall building.

The northlights option is directly comparable with the portal frame in relation to the main supermarket frame; the variance is in the roof framing as there is significantly more roof framing to form the northlights. The additional costs beyond the frame are related to the glazing of the northlights and the overall increase in relative roof area.

[top]Residential / mixed-use building

Holiday Inn tower, MediaCityUK, Manchester

The building used for the cost model is the Holiday Inn tower located in MediaCityUK, Manchester. Phase one of MediaCityUK started in 2007 and completed in 2011.

The building’s key features are:

  • 67m-high, 17-storey tower including 5 office floors and 8 hotel accommodation floors
  • Total floor area of 18,625m2 arranged over two levels
  • Approximate plan dimensions of 74m x 15.3m
  • Columns located on a 6.35m x 2.6m x 6.35m grid spaced at 7.5m.

Three frame options were considered to establish the optimum solution for the building, a steel frame with Slimdek floors, a concrete flat slab and a steel composite deck on cellular beams (offices) and UCs used as beams (hotel).

The full building cost plans for each structural option have been reviewed and updated to provide current costs at Q3 2021. The costs, which include preliminaries, overheads and profit and a contingency, are summarised in the table below.

Table of key costs (£/m2 GIFA), for Holiday Inn tower, MediaCityUK, Manchester (Q3 2021)
Elements Steel frame with Slimdek floors Concrete flat slab Steel frame with composite deck on cellular beams (offices) and UCs used as beams (hotel)
Structural unit cost 602 460 411
Total building unit cost 3,221 3,058 2,981

The steel frame with composite deck provides the optimum build value at £2,981/m2.

However, it is important to note some project-specific factors influencing the decision to use a Slimdek solution for the actual, and hence the base case, building structure. The Holiday Inn tower building is connected to an adjacent studio block between floors one and seven. The long-span requirements for the studio could only be achieved using steel and therefore it was preferable to use a steel structure for the tower block to facilitate the integration of the two structures. Speed of construction was also important for the tower block, and this integration gave programme benefits relative to concrete solutions.

The mixed-use tower block was originally designed with the lower floors as residential accommodation. Key design considerations for the hotel/residential tower block were floor depth and acoustic performance, and hence a Slimdek design was chosen. It was not possible to achieve the required floor depths using a cellular steel beam solution with downstands. The decision to change the residential accommodation to office floors was taken only at a very late stage of the project; this, coupled with the time constraints for the project, precluded redesign of the tower block and hence the original Slimdek design was constructed.

The base case building structure is therefore a relatively unusual solution reflecting the constraints imposed by the wider MediaCityUK development and the concrete flat slab and steel composite frame are arguably more typical solutions for a building of this type.

[top]Market share trend in UK multi-storey construction

               Market share.png
Market shares in the total UK multi-storey buildings market (1980 to 2020)

Steel continues to be overwhelmingly the structural framing material of choice for multi-storey non-residential buildings, according to the latest survey from independent market research consultants Construction Markets.

The survey, commissioned by BCSA and Steel for Life, is the latest in a series going back to 1980 and is thought to be the biggest of its type in the UK, involving 750 interviews with construction specifiers. The results show that steel frames continue to have a dominant 64.7% share of the multi-storey buildings market. The survey also shows that the market contracted by 22.6% in 2020, with the overall floor area constructed in all multi-storey buildings reducing to 5,813,000m², which is 38.1% of the size of the market at its peak of 2008, when it was 15,266,000m².

Headline figures for the market share in the total multi-storey buildings market:

  • 64.7% - Steel
  • 19.6% - Concrete
  • 7.9% - Load bearing masonry
  • 4.5% - Precast concrete
  • 3.3% - Timber

The survey also shows that steel now has a 73.8% share of the multi-storey offices market, and a 60.7% share in the ‘other multi-storey buildings’ sector, which includes retail, education, leisure and health.

This high market share is due in part to the key cost advantages of steel framing:

Column-free floorplates
Steel framing is an economic means of providing long spans without the requirement for intermediate columns, thus creating increased open-plan space which is advantageous to office building letting.

Tenant alterations are considerably less complex with steel-framed buildings, particularly major alterations such as the introduction of internal accommodation stairs or double-height spaces.

Offsite manufacture
This results in a reduction in on-site labour, which as a consequence reduces health and safety risks.

Services integration
The integration of services within the structural elements of buildings leads to economies in the construction by reducing the floor-to-floor height, which has a double benefit of reducing the external cladding required and also reducing heat loss through the envelope. In multi-storey buildings, service integration can allow extra floors to be provided within the same overall building height.

The reduced weight of a steel-framed building has a beneficial effect on the foundation design. It allows the building to be constructed over restricted load areas such as railway station boxes and transfer structures.

Steel frame installation and its ability to be pre-manufactured offers programme advantages due to certainty of delivery and speed of installation.


‘Costing Steelwork’ series (April 2017 onwards):

‘Steel Insight’ series (October 2011 – October 2016):

[top]See also

[top]External links