This invention relates to a foundation system for a building and to a support stand for use in the foundation system.
Modern methods of construction (MMC) have been developed in recent years to speed construction methods and produce environmentally friendly and sustainable buildings. Examples of MMC's include timberframe, light gauge steel frame (LGSF), structural insulated panel (SIP), cross-laminated timber (CLT)/Xlam, laminated log, passive build and modular build construction methods. However, despite these advances, MMC's are still generally reliant on concrete for their base and cladding.
Accordingly, while many countries suffer from housing, pollution and water challenges and MMC's can assist in addressing such problems, cement is still one of the core materials employed in building a foundation for most builds with consequent negative environmental impacts. For example, concrete alone produces 8% of the world's carbon dioxide emissions. Moreover, along with releasing CO2 into the atmosphere, concrete production is responsible for using vast amounts of water and it has been estimated that during the next 35 years, 2,300-2,800 km3 of water will be withdrawn by the concrete industry—a figure which does not include the water required to clean the cement plants and associated equipment.
Accordingly, concrete is an enormous polluter of the planet while its use in the construction of a typical house
Moreover, the use of concrete, whether in foundations or above ground, impacts on a number of key elements in the construction process such as Time (onsite, extensive programme, sequential process phase reliant, trade counter, curing, drying, weather dependent and modifications), Energy (manufacture, transportation, onsite plant requirements, drying and modifications, Materials (large variety required, high volumes, complex pricing, supply reliant), Labour (intensive, high skill, reliability and high cost), Health & Safety (manual handling, onsite fabrication, complex operations, poor structural integrity, and longer time/higher risk), Land (firm ground required, must be flood free and accessible), Waste (due to poor workmanship, over order risks, under order risks, cut offs, excavations soil disposal, damages, storage and theft.
Many countries such as Ireland also suffer from housing shortages but new home developments generally fall well short of demand with the use of old construction methods contributing significantly to the shortfall by being very labour intensive and time consuming.
In summary, new domestic and commercial building developments, even when using MMC's, still suffer from a number of problems such as being labour intensive, environmentally damaging, weather reliant, skill reliant, and costly while the need to address the sub-structure when considering the environment of the foundation and ground floor can significantly impact on construction in terms of time and cost.
Various systems have been developed to replace concrete foundation systems. For example, steel piles such as auger screw, hammer driven or hydraulic press driven piles can be used in foundation systems together with steel or concrete ring beams. Such pile-type foundation systems are generally used in poor ground conditions and suffer from a number of disadvantages. For example, the materials used are usually made from galvanised steel (which is not considered a green material) and only has a lifespan of 60 to 80 years in the ground. However, loss in structural integrity may occur sooner or later depending on ground conditions such as moisture and acidity/alkalinity. Most steel pile systems also require welding which removes the galvanised coating and can only be painted over on site drastically reducing the corrosion protection so that rust soon develops. Welding also weakens high tensile steel which can lead to structural compromise, is time consuming, requires skilled personnel and can lead to fire risks.
Although pile systems can be quicker than traditional concrete systems, they can also have some added delays e.g. setting out needs to be pin point accurate. Piles can also bend or take longer than expected to reach full penetration. Any piles which don't reach their full depth must also be trimmed back. Accuracy of alignment and levels can be problematical as the pile plates can move when the piles are driven while, in general, such pile systems cannot be adjusted.
In addition, when the piles are driven into the ground they can hit services such as electric gas leading to high risk of injury along and increased costs. As the piles and substructure are firmly anchored to the ground, buildings receive full shockwaves during seismic events that can lead to failure. Piles also require pneumatic or hydraulic hammering which can create dangerous and undesirable noise pollution. Driving piles can also create shock waves in the ground resulting in damage to adjacent buildings due to soil subsidence or water fraction movement.
U.S. Pat. Nos. 5,862,635, 5,595,366, 4,899,497, 5,151,108 and 4,918,891 all describe building support stands for securing buildings to a foundation in which beams can be mounted between the support stands on which the building is formed. However, the known stands are formed from perishable materials such as reinforced concrete and/or steel or are made up of complex interconnected components that must be assembled with brackets, fixings and the like before or during use. In addition, the known support stands require the use of labour intensive and complex fixings to secure the beams to the support stands.
An object of the invention is to overcome at least some of the problems of the prior art.
According to the invention there is provided a foundation system for a building comprising:
Preferably, the beam carrier is threadedly mounted on the pedestal to define a beam carrier height adjustment mechanism on the support stand. More preferably, the beam carrier is threadedly mounted on the pedestal at an insert disposed between the beam carrier and the pedestal. Most preferably, the insert is threaded.
In one embodiment, the beam carrier comprises a substantially horizontal structural beam support plate at each vertical wing.
Preferably, the support stand comprises two or more vertical wings disposed at 90° to each other. Suitably, the support stand comprises three vertical wings disposed at 90° to each other. In one embodiment, the support stand comprises four vertical wings disposed at 90° to each other to define a cruciform shaped beam carrier. Suitably, the wing comprises holes for receiving structural beam fixings.
In one embodiment, the beam carrier comprises an offset beam carrier. Suitably, the offset beam carrier comprises an outside offset beam carrier. Alternatively, or in addition, the beam carrier comprises an inside offset beam carrier.
Advantageously, the offset beam carrier comprises a slot-like or U-shaped channel for receiving a beam.
Preferably, the pedestal comprises a base. Optionally, the base comprises holes for receiving a rod or pin. Suitably, the holes are angled in the base.
In one embodiment, the pedestal comprises a threaded pillar. Preferably, the beam carrier is threadedly mounted on the pillar so that the beam carrier is movable between a raised and lowered position by the beam carrier height adjustment mechanism.
In one embodiment, the support stand further comprises a secondary or fine beam carrier height adjustment mechanism.
Preferably, the support stand comprises a composite polymer material. More preferably, the support stand comprises Nyrim (Trade Mark).
Suitably, the foundation system further comprises at least one structural beam.
Preferably, the structural beam comprises an engineered end for securing the structural beam to the wing. More preferably, the engineered end comprises a mortise-like engineered end for receiving the wing.
Suitably, the structural beam comprises a double structural beam in which each beam is disposable either side of the wing at the engineered ends.
Optionally, the structural beam can be selected from the group consisting of a structural composite lumbar beam, a structural open web double beam, a structural double I-beam, a structural double timber plank/joist/fletch beam and a structural double light gauge steel beam.
Preferably, the foundation system further comprises a deck for a floor structure. More preferably, the deck comprises a cassette type deck.
Optionally, the foundation system comprises a plinth for tying structural beams and/or the floor structure to the ground. Preferably, the plinth is L-shaped. Suitably, plinth comprises air vents.
In another embodiment, the invention also extends to a support stand for supporting a structural beam in a foundation system comprising a pedestal and a beam carrier mounted on the pedestal wherein the beam carrier comprises a wingnut construction defining at least one substantially vertical wing connectable with a structural beam.
Preferably, the beam carrier is threadedly mounted on the pedestal to define a beam carrier height adjustment mechanism on the support stand. More preferably, the beam carrier is threadedly mounted on the pedestal at an insert disposed between the beam carrier and the pedestal. Most preferably, the insert is threaded.
In one embodiment, the beam carrier comprises a substantially horizontal structural beam support plate at each vertical wing.
Preferably, the support stand comprises two or more vertical wings disposed at 90° to each other. Suitably, the support stand comprises three vertical wings disposed at 90° to each other. In one embodiment, the support stand comprises four vertical wings disposed at 90° to each other to define a cruciform shaped beam carrier.
Suitably, the wing comprises holes for receiving structural beam fixings.
Preferably, the pedestal comprises a base. Optionally, the base comprises holes for receiving a rod or pin. Suitably, the holes are angled in the base.
In one embodiment, the pedestal comprises a threaded pillar. Preferably, the beam carrier is threadedly mounted on the pillar so that the beam carrier is movable between a raised and lowered position by the beam carrier height adjustment mechanism.
In one embodiment, the support stand further comprises a secondary or fine beam carrier height adjustment mechanism.
Preferably, the support stand comprises a composite polymer material. More preferably, the support stand comprises Nyrim (Trade Mark).
In a further embodiment, the invention also extends to a method for constructing a foundation comprising employing a foundation system or support stand as hereinbefore defined in the construction of the foundation.
The foundation of system of the invention is an environmentally friendly rapid foundation system that obviates the need for concrete foundations whilst facilitating rapid and sustainable construction of domestic and commercial buildings. The foundation system of the invention is suitable for use with all MMC's including timberframe, light gauge steel frame, structural insulated panel, CLT/Xlam, laminated log, passive build and modular build methods.
The foundation system of the invention is a fast, strong, green and a cost-effective construction method that significantly reduces construction lead times and is up to 8 times faster than traditional cement foundations and reduces CO2 emissions by up to over 90% in buildings' bases by eliminating concrete requirements. Moreover, as concrete is not required, no water is needed saving up to 8,000 of litres of drinking quality water per average house build.
The foundation system of the invention also allows construction on low level land which would usually be considered otherwise unsuitable for construction without considerable civil engineering works in or near flood plains. The foundation system also reduces impact damage to building structures due to floods and diminishes the lateral forces associated with earthquakes whilst also reducing excavation and subsoil waste disposal by up to 100%.
The invention also saves up to 25% of overall build costs, ensures completion in up to 80% less time as a traditional build, improves environmental impact by cleaner efficiencies as no water is required and critically, the foundation system of the invention is not weather dependent unlike conventional construction methods employing concrete foundations.
Accordingly, the foundation system of the invention addresses constraints associated with using concrete for a build foundation as follows:
The height adjustable beam carrier of the wingnut-like support stand of the invention holds and supports structural beams and the load acting on the structural beams. Any suitable structural beams can be employed in the foundation system of the invention such as single structural beams having engineered ends e.g. mortised or slotted engineered ends beam or double structural beams running parallel to each other (side by side). The structural beams are supported on beam support plates on the wingnut like beam carrier and secured to the beam carrier at the vertical wings by simple mechanical fixings such as screws, bolts, dowels and the like.
The foundation system of the invention in combination with an engineered crushed stone base forms a rigid grid foundation/base structure on top of which buildings can be constructed.
The engineered ground is typically ground which has been cleared of its top soil and which is then covered in layer/layers of hard crushed stone aggregate, which is then compacted to the site specific requirements. The engineered ground can be furthered strengthened by the addition of layer/layers of geo grid or geo textile as required by site specific requirements determined by structural design engineers and the like.
As the support stand is formed from a composite engineering polymer material such as Nyrim (Trade Mark), the support stand has longevity and does not corrode or perish in or above ground. The support stand can also be recycled.
The foundation system of the invention also obviates cutting, welding or fabrication on site as all components are fixed with simple mechanical fixings such as dowels or bolts.
The foundation system of the invention can sit directly on the ground and need not be anchored in any way while the support stands dissipate energy through their high flexural strength.
The foundation system of the invention also facilitates quiet construction while the engineered ground requires minimal vibrations so risk of structural damage is greatly mitigated.
The support stand of the invention also enjoys high strength due to its wingnut like configuration e.g. can be rated from 10 tonnes to a maximum load of 20 tonnes which can be scaled up or down as required. In addition, the height adjustability can be varied as required with an adjustability of about 200 mm being typical.
The system of the invention relies on ground pressure to remain anchored but can also be anchored with geogrid followed by crushed stone being placed over the base of the support stand if desired whereas known structures generally require embedding or anchoring. Accordingly, the system of the invention takes advantage of the natural load capacity of a crushed stone base which can be further enhanced by the addition of geogrids or similar if desired.
The foundation system of the invention can be used in the construction of domestic, industrial and commercial buildings such as houses, data centres, pharmaceutical facilities, hospitals, hotels, retail, drive through restaurants, pods, garages, decks, stages, bridges, playground structures and the like.
As shown particularly in
The pedestal 6 has a circular base or pad 9 defining a bottom face 10 for engaging with the ground and an upper top face 11 on which a threaded pillar 12 is centrally mounted on the circular base 9. The threaded pillar 12 is attached to the circular base 9 at a beam carrier height adjustment nut 13. The circular base 9 serves to support the support stand 2 on the ground in use and is also provided with generally circumferentially spaced apart rod or pin holes 14 for receiving elongate rods to fix the circular base 9 to the ground if desired. The pedestal 6 transmits the associated structural loads from its location to the engineered ground below the building 5.
In the present embodiment, the height adjustable beam carrier 7 of the support stand 2 is made up a cruciform horizontal base plate 15. A top face 16 of the base plate 15 defines four horizontal beam support plates 17 disposed at 90° with respect to each other in the cruciform shape so that each beam support plate 17 can support a structural beam 3. Each beam support plate 17 is provided with a beam connector 18 in the form of a web-like vertical uprights or wings 19 to which structural beams can be secured at fixing openings 20 defined in the web-like uprights or wings 19. The beam carrier 7 is further provided with a central bore 21 defined in a substantially cylindrical housing 22 centrally located between the beam support plates 17 and the beam connectors 18 in a wingnut configuration. As shall be explained more fully below, the central bore 21 is configured to receive the sleeve insert 8.
On its underside, the horizontal base plate 15 is provided with reinforcing supports 23 which extend between the base plate 15 and a central housing bottom portion 24 contiguous with the central housing 22. The central housing bottom portion 24 defines a pillar opening 25 for receiving the threaded pillar 12 in the central bore 21.
The beam carrier 7 is placed on the threaded pillar 12 of the pedestal 6 by inserting the threaded pillar 12 in the central bore 21 via the pillar opening 25 with the threaded sleeve insert 8 disposed between the beam carrier 7 and the threaded pillar 12 so that the beam carrier 7 can be moved upwards and downwards with respect to the pedestal 6 in a height adjustable manner. Accordingly, the support stand 2 is provided with a primary beam carrier height adjusting mechanism 26.
As shown in
In the present embodiment, the support stand 2 is cruciform in shape with four beam support plates 17 and associated beam connectors 18. However, in other embodiments, the support stand can have other numbers of support plates 17 and beam connectors such as two perpendicularly disposed support plates 17/beam connectors 18 for supporting perpendicularly disposed structural beams 3 or three support plates 17/beam connectors 18 disposed at 90° to each other for supporting three structural beams 3 at a corner in a grid formation. This is described in more detail in
The support stand 2 serves as the load bearing element between the ground and a building 5 while the pedestal 6 can be a one piece moulded composite polymer consisting of the base 9 and the threaded pillar 12 for supporting the required load. The beam carrier 7 is also a one piece moulded composite polymer. The winged nut configuration of the beam carrier 7 facilitates the carrying of the structural beams 3 in a 90° arrangement allowing for a rapid aligned and level grid structure of beams 3 to be erected.
The support stands 2 can be sized as required to accommodate individual building design requirements.
The support stand 2 is provided with a tool access hole 28 defined in the central housing 22 of the beam carrier 7 to provide access to a tool receiving blind hole 29 defined in the top face of the threaded pillar 12. The tool access hole 28 and the tool receiving bind hole 29 are configured to receive a tool 30, in the form of a square ended tee wrench 30 in the present embodiment, so that rotation of the tee wrench 30 effects rotation of the threaded pillar 12 with respect to the sleeve insert 8 to finely adjust the height of the support stand 2. More particularly, turning of the tee wrench 30 in blind hole 29 causes the threaded pillar 12 to rotate with the base 9 and beam carrier 7 being fixed so that upwards and downwards adjustment will be equal to a difference in thread pitches i.e. 8.4666−6.0=2.4666 mm per revolution.
Accordingly, height adjustment is made possible by the use of two different thread pitches for the threads both right hand on either end of the threaded pillar 12. Accordingly, height change difference per revolution is reduced while mechanical advantage or lifting power is increased.
In the present embodiment, the support stand 2 is further provided with optional elongate fixing rods 32 inserted through the fixing rod holes 14 defined in the circular base 9 of the pedestal 6 of the support stand 2. The fixing rod holes 14 can be angled as required so that the fixing rods 32 converge. The fixing rods 32 can be formed from any suitable material such as steel or basalt fibre which can be driven/hammered down through the angled rod holes 14 in use.
This support stand 2 can be made from any suitable materials such as composite engineering polymers. A preferred polymer is Nyrim (Trade Mark) which can be optionally combined with additional nanoparticles to reinforce the support stand 2 or various fillers such as wollastonite (calcium inosilicate mineral (CaSiO3)). Nyrim (Trade Mark) has a high flexural strength together with anti-fatigue properties so that fatigue failures normally associated with concrete and steel are eliminated.
The support stand 2 can be formed using known manufacturing techniques such as Reaction Injection Moulding (RIM) of the Nyrim (Trade Mark) polymer composite which is a repeatable process that the guarantees the consistency of the support stands 2.
Similarly,
More particularly, the position for each support stand 2 is identified and marked out and each support stand 2 is then placed in its location and height adjusted as required with the primary height adjustment mechanism 26 as previously described. The structural beams 3 are then lifted into place on the support stands 2 and bolted together. Once all the structural beams 3 are bolted together the height of the support stands 2 can be finely level adjusted with the secondary height adjustment mechanism 26 or by adjusting the height adjustment nut 13 with a spanner. Once the structural beams 13 are all level, all connecting bolts can be tightened to recommended torque as required. Once the structural beams 3 are levelled and tightened to the support stands 2, the system 1 is self-aligning and the beam carriers 7 keep the grid formation parallel, perpendicular and aligned.
Finally, the decks 4 are secured to the structural beams to create a floor level on which the building 5 is constructed.
Once constructed, a footpath 47 can be laid around the building 5. Prior to laying the footpath 47, an optional apron-like plinth 45 can be attached to the outer structural beams 3 and/or decks 4 of the building 5 to tie the building to the ground. More particularly, the plinth 45 can be an L-shaped plinth 48 having a vertical wall 49 for attachment to the structural beams 3 and/or the decks 4 and a horizontal wall 50 for abutting the ground on which the footpath 47 can be paid to secure the plinth 48 and the building 5 in position. The vertical wall 46 can be provided with air vents 51 to allow for aeration beneath the building 5 and radon gas escape and the like.
Number | Date | Country | Kind |
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S2018/0511 | Nov 2018 | IE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/081857 | 11/19/2019 | WO | 00 |