Light Steel Beam Steel Floors

Steel-MAX has designed a special range of stumps specifically to suit the Lite Steel Beam (LSB) flooring system.

Stump bases are in the form of a U-shaped bracket for multi-position and multi-angle connection to footings. Special moment base plates are available for mezzanine floors, and where maximum bracing stability is required.
Stump tops are designed to fit any wall thickness tube and are telescopically height adjustable to 75mm. They have vertical fin plates to suit 150mm, 200mm, 250mm and 300mm LSB bearers. They provide maximum support and hold down through the bearer’s web, giving the bearers lateral stability.

For more information on LSB flooring systems and installation, see Steel-MAX LSB Floor Details.

Supported Stump Systems

90mm stump system

Downloads

Stramit Steel-MAX Floor Framing System (ZIP)

Capacities

Steel Stump Tubes

Minimum grade C350.

SHS	Max. height
89×2.0	= 3.0m
89×3.5	= 4.0m
89×5.0	= 4.8m
89×6.0	= 5.5m

Stump tops to steel stump tubes

Connection	Shear capacity Vu
2×14-20 Teks	14.7kN
4×14-20 Teks	29.4kN
8×14-20 Teks	58.8kN
16×14-20 Teks	117.6kN
20×14-20 Teks	147.0kN
1 / M12 bolts	24.2kN
2 / M12 bolts	48.4kN

Minimum stump top and post Yield Stress fy = 300 MPa; Minimum bolt Yield Stress fy = 400MPa. Notes:

All shear capacities are governed by the screw/bolt shear capacity.
Calculations based on a minimum post wall thickness of 2.0mm.
Tek screws to be installed in accordance with the manufacturer’s specifications
Screws and bolts may be combined to achieve reduced shear capacities, using the appropriate reduction factors for each connection type.

Stump top to LSB bearer connection

Minimum stump top, fin plate Yield Stress fy = 300 MPa; Minimum bolt Yield Stress fy = 400MPa.

Wall brackets to LSB bearer connection

Connection	Shear capacity Vu
2×14-20 Teks	9.2kN
4×14-20 Teks	18.4kN
6×14-20 Teks	27.6kN
1 / M12 bolts	10.2kN
2 / M12 bolts	20.4kN

Design based on 2 / M12 chemset injection anchor fixing of bracket to core filled masonry wall of 15MPa. Notes:

All shear capacities are governed by the hole capacity of the LSB’s web and not the screw/bolt shear capacity.
Calculations based on a minimum web thickness of 1.5mm, minimum Tensile Strength (fu) = 490MPa and minimum Yield Stress (fy) = 380MPa.
Tek screws to be installed in accordance with the manufacturer’s specifications
LSB members to be fully restrained against lateral displacement of both flanges and twisting about the longitudinal axis.

Bracing brackets

Connection	Bracing capacity
4×14-20 Teks	15kN ( 12mm rod )
M16 bolt	22kN ( 16mm rod )

Moment base plates

100x100x4.0 Moment Base Plates have an ultimate bending moment capacity of 5.2kNm, subject to the following:

Must be fixed to a footing or slab with a minimum compressive strength of 25MPa with 4 / M12 chemset anchors, fixed with a minimun distance between the centre of the bolt and the edge of slab of 50mm.
The supporting structure should be assessed by the project engineer to ensure that it is structurally capable of withstanding both the moment and vertical loads expected.
The Moment sleeve must be fixed to the supported post with a No.10 Tek screw in each of the four faces of the sleeve.
The gap between the sleeve and the supported post must be adequately sealed to prevent moisture ingress between the two members.

Other Information

1. SMART STUMPS

Steel-MAX has designed a special range of stumps specifically to suit the LiteSteel Flooring System.

STUMP TUBE:

The stump tube is 89×89 or 90×90 Gal. SHS and will vary in wall thickness to suit load requirements.

STUMP BASES:

Stump bases are in the form of a “U” shaped bracket, for multi-position and multi-angle connection to footings.
Special “Moment Base plates” are available for mezzanine floors and where maximum bracing stability is required.

STUMP TOPS:

Stump tops fit any wall thickness tube and are telescopically height adjustable up to 75mm.
They have vertical “fin plates” to suit 150, 200, 250 & 300mm LSB bearers.
They provide maximum support and hold-down, through the bearer’s web, giving the bearers lateral stability.
Special screw adjustable tops are also available and are particularly useful for reactive soil conditions.
Multi-top stumps are also available for applications where bearers can be joined at “T” intersections and 90 deg corners.

POST SLEEVES:

Post sleeves may be used to carry bearers which need to be fixed to the face of a verandah post, or a higher stump which continues up to support a different level floor, such as in split levels.

2. BRACING:

“U” shaped bracing brackets are connected to stumps and bearers, to carry either 12mm or 16mm threaded bracing rod, to form sub-floor cross bracing sets. They yield up to 15 kN or 22 kN capacities respectively. 3. CONNECTORS:-

“L” fixed angle brackets may be used at 90 deg member connections in a variety of applications.
- They are also useful when connecting trimmers around stair voids.
Hinged “H” brackets can be used at angled connections, similar to the “L’ brackets.
Joist connector brackets are in the form of an angle, which are usually fixed vertically to the webs of both the bearers & joists.
- They help support both members and provide good hold-down and lateral stability to joists.
- They are available in 200mm and 295mm lengths.

4. DURABILITY:

Refer also to the LiteSteelBeam web site as well as the Steel-MAX corrosion protection recommendations.

5. TECHNICAL SUPPORT:

Contact Steel-MAX via the web site, email, phone or fax; or ask your LiteSteel representative.

6. ENGINEERING:

Engineering design and certification is provided by H.R. Design Group P/L (Hunt Robinson Engineers) for the Steel-MAX products for use with the LiteSteel Floor Framing System. A copy of the standard letter of certification is available from the Steel-MAX web site. Both LiteSteel Technologies and Steel-MAX do not provide individual job certification, footing or sub-floor bracing designs, or certificates of compliance. These are generally site specific and should be provided by the project engineer. 7. JOB DESIGN:- Use the Pryda LiteSteel Beam Selector software to determine the most suitable LSB member sizes for your project, or ask your LiteSteel representative for assistance from Steel-MAX to offer a floor design solution for your project, including all necessary Steel-MAX companion products to complete the floor system.

8. FIXINGS:

Refer to the Steel-MAX load capacity tables on page 18, (provided by the H.R. Group) and have your project engineer specify your individual job requirements. However; for uniformly loaded domestic applications, consider the following as a guide only :- Stump bases to stump tube = 6 / 14 g hex teks ( 3 in each face ) Stump tops to stump tube = 8 / 14 g teks up to 8 m2 of floor area carried by the stump, then 1 / screw per m2 or 1/M12 bolt per 5 m2 of area extra over the first 8 m2. Sleeves to tube = 8 / 14 g teks per sleeve. Bracing brackets = 4 / 14 g teks per bracket for 12mm rod and 1 / M16 bolt per bracket for 16mm rod. “L” & “H” connector brackets = 8 / 10 g teks for joist to bearer connections and 8 / 14 g teks for bearer to bearer connections. Joist connector brackets = use 6 / teks per brackets ( 3 in each member ) Use 10 g. teks for 200mm brackets and 14 g. teks for 295mm brackets.

9. AVAILABILITY:

All necessary Steel-MAX “Companion products” to the LiteSteel Floor Framing System are available from your participating LSB supplier, or by contacting Steel-MAX Distribution by calling (07) 3831 5444 or Mob: 0438 748 381 Fax: 07 3831 5666 email distribution@steelmax.com.au

10. APPLICATION DETAILS:

The information contained within this document or any other provided by Steel-MAX does not represent, form or replace LiteSteel Technologies’ official documentation, relating to the LiteSteel Floor Framing System. All information shown, enclosed and contained within this and associated documents represents suggested methods of using Steel-MAX components in conjunction with LSB sections and may not suit your particular job requirements and application. We offer design solutions as a suggestion, for the consideration of the customer and his project engineer. It is imperative that the customer’s project engineer looks at the suggested details and either incorporates them into his whole job structural design, or alters them to suit his requirements, for the project. It is always possible that there could be influencing elements within the structure, that we are not aware of, which could effect and alter the following suggested details and information