Danley™ FAQ's

 Advanced issues found
Why is joint design so important in slab on ground?
The floor is one of the most important parts of the building. In an industrial facility it's the workspace on which all operations take place. Not only is it part of the structure, it is also an integrated part of the materials handling and workflow system. When the floor system becomes damaged it affects the efficiency of the facility and the bottom line profitability of the operation. Managing stress in slab on ground is key to ensuring minimum cracking, curling and warping and joint stability to ensure the lowest cost slab over the lifecycle of the facility.
In addition to structural integrity, why is serviceability such a critical consideration for industrial floor slabs?
he most vulnerable place on an Industrial Floor Slab is at the Joints. Spalling is the critical failure mode at the joint in a slab that will carry lift truck traffic of varying kinds. Spalling damage is the primary cause of reductions in the operating efficiency of industrial facilities contributing to downtime as well as high maintenance and rectification costs over the lifecycle of the floor.
What causes spalling damage at the slab joints?
Spalling is typically a result of curling stress. Differential drying shrinkage between the top and bottom of the slab causes the free edges of the slab panel to lift and lose contact with the base resulting in a cantilever effect at the perimeter of the slab panel. This curling or warping condition allows vertical deflection at the edge of the slab when loaded by the lift truck traffic. Joints break down when the lift truck moves towards the joint, deflecting the edge of the loaded slab down and then bumping into the edge of the adjacent panel causing spalling damage to the edges of the panels as the lift trucks move back and forth over the joint.
What is load transfer?
Load transfer in slab on ground can be described as the transfer of concentrated loads across a joint to an adjacent abutting floor slab. When a wheel load is applied to a slab, the load deflects the free edge of the slab end downwards. When an appropriate load transfer system is used at the joint both the loaded and the unloaded slabs deflect equally, spreading the load across both slab panels while keeping the top edges of the panels level to limit spalling damage.
What is Load Transfer Efficiency?
Load Transfer Efficiency is essentially the measure of the magnitude of reduction in stresses and deflections by a joint utilising appropriate load transfer controls in comparison to a joint where free edges are allowed to deflect.
What is Joint Stability?
Joint Stability is the measure of vertical deflection or movement at the joint created when a load passes over the joint from one adjacent slab panel to the next. Joint Stability measurements of 0.25mm for hard wheeled materials handling equipment and 0.51mm for soft or rubber wheeled materials handling equipment are deemed to provide good service life according to ACI Standards.
How can joint deflection and spalling damage be controlled?
A properly designed dowel system limits the allowable deflection and transfers the load from one slab panel to the next across the joint to minimise the difference in vertical height between the loaded slab and adjacent slab to significantly limit damage and extend the working lifecycle of the floor.
What are F-Numbers (FF and FL)?
The F-Number System is the American Concrete Institute (ACI117) and Canadian Standards Association (CSA A23.1) standard for the specification and measurement of concrete floor flatness and levelness. There are two F-Numbers: FF for flatness and FL for levelness. 'Flatness' relates to the bumpiness of the floor, while 'levelness' describes the local tilt or pitch of the slab. The higher the F-Number, the better the characteristic of the floor. F-Numbers are linear, so an FF 20 is twice as flat as an FF 10, but only half as flat as an FF 40. Industrial slab-on-ground floors are often specified with an FF number and an FL number.
What design standards does Reid Contruction Systems consider?
The Following Standards and Guides are referenced and considered by Reid Contruction Systems when designing and recommending products and systems for use in slab on ground applications: American Concrete Institute ACI360R-10, Guide to Design of Slabs-on-Ground Associated ACI Standards and Reference materials U.K. Concrete Society TR34, Concrete Industrial Ground Floors Concrete Cement and Aggregates Aust. T48, Guide to Industrial Floors and PavementsAS 3600 Concrete Structures AS 1170 Structural Design Actions (LFL) AS 4671 Steel Reinforcing Materials AS/NZS 2425:2015 Bar Chairs in reinforced concrete – Product requirements and test methods AS 3727.1:2016 Pavements - Residential
What is the correct time to Soff-Cut?
The most efficient method of reducing stress in a newly poured slab is with an early-entry Soff-Cut made as soon as the concrete will support the saw and operator. This is generally within 2-3 hours of last pass of power trowel but needs to be assessed by experienced operators on the day of the pour to take into account the ambient temperature conditions and other influences. The purpose of the Soff-Cut is to relieve stress in the slab panel at predetermined locations to create planned cracks and limit unplanned cracking due to drying shrinkage and stress. Saw cut depth should be approx. 1/4 of the slab. It is critical that all joints are activated to relieve the stress and distribute the shrinkage evenly across the slab panel. This will maximise the reduction of stress and minimise the shrinkage and the joint gap at the free edge of the slab.
Why should I use a Plate Dowel over a Round or Square Dowel?
Plate Dowels have a wider cross sectional area than Round or Square dowels creating a wider bearing surface to more evenly distribute load, therefore reducing point loading and stress to lower the risk of concrete cracking or bursting. The PD3™ Dowel Cradle tapered shape allows for the lateral movement of the dowel without the need for plastic sleeves to create cavities. The absence of a plastic sleeve allows direct contact between the steel plate and the concrete therefore providing minimal chance of deflection, greatly reducing the risk of damage to the joint edges.
What grade steel are Danley dowels made from?
All Danley dowels (PD3™ and Diamond™ Plate Dowels, Round & Square) are made from Grade 300 mild steel.
Why use a Dowel Cradle?
The Dowel Cradle wire basket construction ensures the accurate placement and alignment of dowels at the correct centres and height within the slab. This significantly reduces onsite labour costs associated with processing formwork and reduces the risk of dowel placement and alignment error.
What are the advantages to using a PD3™ Plate Dowel?
The patented PD3™ design features a tapered and sleeveless plate dowel that provides world’s best performance in limiting joint deflection to provide superior joint stability. The PD3™ Dowel provides the highest deflection control tolerance in line with ACI Standards recommendations to limit joint spalling, facilitate load transfer and provide the lowest risk of restraint to ensure the best serviceability outcome for the slab design. As drying shrinkage occurs the tapered plate forms a cavity that facilitates lateral movement to eliminate the risk of restraint without the need for a sleeve system. The elimination of the sleeve system ensures that there is direct contact between the concrete and plate dowel with no sleeve interference to provide the highest level of deflection control and therefore superior joint stability and serviceability outcomes. Use of the PD3™ system extends the lifecycle of the floor to provide the highest level of floor efficiency for tenants and the highest return on investment for the asset owner.
What is the RynoBar™?
The RynoBar™ is a patented plastic Travel Bar, or sacrificial retention system pre-fitted to all Danley™ PD3™ Plate Dowel Cradles. Traditionally, a series of deformed steel bars are tack-welded to keep cradles intact whilst in transit to site. Leading engineers and contractors suspect that uncut steel travel bars are the significant factor in flooring failure resulting from restraint (parallel cracking).
How does the RynoBar™ work?
The RynoBar™ is designed to perform 2 core functions: (1) As a travel bar, the RynoBar is tough when it needs to be - ensuring that PD3 cradles are intact during transit and installation on site. (2) The RynoBar™ features an innovate rib-design that auto yields at <1kN in early concrete shrinkage, which does not need to be cut before the placement of concrete. RynoBar saves time and on site labour costs.
Is the RynoBar™ safe to use?
Yes. The RynoBar™ is pre-fitted to all Danley PD3 cradles, in either 6mm, 10mm or 20mm and eliminates the potential risks of cuts and abrasions from the sharp edges which are common place with traditional steel travel bars. The RynoBar™ also eliminates the need to cut travels bars, which in turn significantly mitigates the potential risks of repetitive strain injury.
Do we need to fit the RynoBar™ on to the PD3 cradles before we pour?
No. The PD3 Cradles will be supplied on site with RynoBar travel bars already fitted to every cradle - ready for immediate set-up. Once the set-up is completed in accordance with our installation guidelines, you are ready to pour. Unlike traditional deformed steel travel bars, the RynoBar™ is self-yielding in early shrinkage concrete and will not need to be cut
Where can I purchase the PD3 with RynoBar™?
To locate your nearest Danley distributor or reseller, please refer to the 'Where to Buy' section of our website.
Is there a new item code? Do I need to update my system?
No. There is no change to the item coding or product naming convention for any of the 3 sizes of Danley PD3 Plate Dowel Cradles with RynoBar™. The Danley PD3 is available in Plate Dowel thickness of 6mm, 10mm and 20mm.
How do I go about adding the PD3 with RynoBar™ to my specifications?
We have developed a new set Engineering Specification details (DWG) that can be downloaded from our website. You can also download a technical data sheet from our website.
Do we have to follow the mesh placement guidelines shown in your product details?
These are just guidelines and ultimately, the structural engineer is responsible for deciding the position of the mesh. In our details we put in a typical mesh placement detail which could be used in the absence of any other information, but the structural engineer’s mesh placement detail supersedes any suggestion we make. It is always necessary that the reinforcement is chaired correctly with chairs complying to AS/NZS 2425:2015 to ensure that standing on the mesh does not cause it to bend upwards. Care should be taken how the position of the mesh impacts during construction to ensure that standing on the mesh doesn’t displace the dowel, Hyper ArmourMate top rail or PD3 cradle.
Where can I purchase Danley products and accessories?
To locate your nearest Danley distributor or reseller, please refer to the 'Where to Buy' section of our website.
I am in a rush and need to see if someone can offer an alternative product so I can take an urgent delivery?
lease call our customer service department and they will be happy to offer some suggested alternatives for consideration or direct you to our appropriate representative to call on you to discuss the needs of the project.
Can I send drawings to you and request a take-off?
We are happy to look at drawings and offer recommendations, however we are not able to offer a full detailed take-off.

Danley™ Slab-on-Ground Industrial, Residential, and Pavement Systems have a trusted history spanning over 25 years.