Jan 06

Construction Details (Typical)

Base of Wall

Fig 14.1 Hebel PowerBlock work on Stiffened Raft Slab Edge Foundation (elevation)

Fig 14.2 Hebel PowerBlock work showing infill block to slab rebate (elevation)

Fig 14.3 Internal Load Bearing Hebel PowerBlock work on stiffened raft slab foundation (elevation)

Fig 14.4 Concrete PowerBlock Sub-Floor Detail (elevation)

Fig 14.5 Roof Top to Plate Fixing to Hebel Wall – Strap (elevation) – for aulted/cathedral roofs

Fig 14.6 Roof Top to Plate Fixing to Hebel Wall – Strap (elevation) – for typical trussed roof

Fig 14.7  Strap Fixing to Hebel Walls (isometric – typical trussed roof)

Fig 14.8  Double Brick Sub-Floor Detail (elevation)

Fig 14.9 Ring Beam Internal Non-Loadbearing Wall (elevation)

Top of Wall

Fig 14.10 Internal Hebel Load Bearing Wall and Timber Floor Frame Junction (elevation)

Fig 14.11 Truss Spanning Over Non-Load Bearing Hebel Walls (elevation)

Fig 14.12 Timber Truss/Joist Fixed to Hebel Walls (elevation)

Fig 14.13  Tiled Roof Eve and Hebel Wall Junction (elevation)

Fig 14.14  Vaulted Ceiling & Roof Top Plate Fixing To Hebel  Wall (elevation)

Wall Junctions

Fig 14.15  External Wall and Internal Partition Wall Junction  (plan)

Fig 14.16  External Corner with Control Joint (plan)

Control Joints

Fig 14.17  Control Joint detail (elevation)

Fig 14.18 Typical Bond Beam Control Joint – elevation

Fig 14.19 Typical Control Joint – plan 

Fig 14.20 Typical Ring Beam Control Joint – elevation

Fig 14.21 Hebel PowerBlock work Typical Movement Joint Detail (elevation)

Fig 14.22 Hebel PowerBlock work Typical Movement Joint Detail (plan)

Fig 14.23 Built-in Column Detail (plan)

Fig 14.24 Built-in Column Detail (elevation)

Floors

Fig 14.25 Non-Load Bearing Hebel PowerBlock Wall and Hebel Floor Panel Detail (elevation)


Fig 14.26 Loadbearing Hebel PowerBlock Wall and Floor Panel Junction Detail (elevation)

Fig 14.27  Loadbearing Hebel PowerBlock Wall and Timber Floor Frame Junction Detail (elevation)

Fig 14.28 Timber Floor Support Detail (elevation)

Fig 14.29  Hebel Flooring Panels using Ring Anchor Construction on Load Bearing Interior Wall (elevation)

Fig 14.30 Ceiling Support Detail A (elevation)

Fig 14.31  Ceiling Support Detail B (isometric)

NOTE: Refer to section 7.12 of the Hebel Technical Manual for the full set of Details on the Floor Panel System.

Balcony and Deck

Fig 14.32  Balcony Detail (elevation)

Fig 14.33  Balcony Detail (elevation)

Fig 14.34  Deck Connection Detail (side elevation)

Fig 14.35 Deck Connection Detail (front elevation)

Stairs

Fig 14.36  Stairwell (isometric)

Fig 14.37  Stair Tread Set-Out (isometric)

Fig 14.38 200mm wide x 50mm thick Hebel PowerBlocks adhered to walls on their ends to provide support for treads (isometric)

Openings

Fig 14.39 Steel Door Frame (Internal or External) to Hebel Wall Fixing (plan)

Fig 14.40  Steel Door Frame (Internal or External) to Hebel Wall Fixing (plan)

Fig 14.41  Timber Door Frame (External) to Hebel Wall Fixing (plan)

Fig 14.42  Timber Door Frame (Internal) to Hebel Wall Fixing (plan)

Fig 14.43  Aluminium Window Frame – Window Sill Detail (elevation)

Fig 14.44 Aluminium Window Frame – Window Jamb Detail (elevation)

Fig 14.45  Aluminium Window Frame – Window Head Detail (elevation)

Fig 14.46 Lintel Installation  

(a) Elevation

(b) Section

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Jan 06

Hebel Construction Details – Tie-down

Required only if specified by design /project engineer.

Fig 15.1: Strip Footing, Double Brick Sub-Floor

Fig 15.2:  Strip Footing, Concrete Power Block Sub-Floor

Wall Length(mm) Min. No. of N12 Bars Ultimate Racking Capacity (kN)
150mm PowerBlock

250mm PowerBlock

900 2 5 6
1200 2 8 8
1800 3 16 18
2400 3 24 25
3000 4 36 38
3600 5 45 46
4800 6 54 56
6000 7 63 66

Tie down rods/engineering restraints must be embedded into the footing and pass up through the sub floor and into the Hebel PowerBlock work.

Table 15.1 Top-Plate & Hold-Down selection

Wind
Classification
Top Plate & Hold-Down
Tile Roof Sheet Roof
N1 A / B / C B / C
N2 A / B / C D / F
N3 D / F D / F
N4 D / F D / F
N5 E / G E / G
N6 E / G E / G
C1 D / F D / F
C2 E / G E / G
C3 E / G E / G
C4 G G
Legend
A 90×45 F7 timber top plate / 700mm deep strap @ 1200mm ctrs.
B 90×45 F17 timber top plate / 1700mm deep strap @ 2400mm ctrs.
C 90×45 F17 timber top plate / Ф12mm rod @ 2400mm ctrs.
D 90×45 F17 timber top plate / Ф12mm rod @ 1200mm ctrs.
E 90×45 F17 timber top plate / Ф12mm rod @ 900mm ctrs.
F 100x50x3.0 RHS top plate / Ф12mm rod @ 2400mm ctrs.
G 100x50x3.0 RHS top plate / Ф12mm rod @ 1200mm ctrs.

Fig 15.3 Hold Down Detail for Reinforced Bracing Walls

Table 15.2 provides ultimate racking capacities of reinforced 150mm and 250mm Hebel PowerBlock walls. The reinforcement is N12 bar or 12mm threaded rod at nominal 1000mm centres. The reinforcement must be tied to the footings and wall top plate through the bond beam.

Walls resisting racking forces should be evenly distributed within a house and spaced at a maximum of 8.0m. Ceiling and floor diaphragms must be adequately tied to walls to ensure transfer of forces through to the footings.

For more information about bracing, refer to Section 6.11 of the Hebel Technical Manual.

Fig 15.4 Roof Top to Plate Fixing to Hebel Wall – Strap (elevation)

Top Plate Hold-Down

Two tie-down methods are provided in this design guide.

1. Strap – 30×0.8mm cut into inside face of external wall min. 700mm deep.
2. 12mm threaded rod continuous from footing through bond beam to top plate.

Fig 15.5 Roof Top Plate Fixing to Hebel Wall-Tie-Down Rod (elevation)

Three top plates options are provided in this design guide:

1. 90×45 F7 timber
2. 90×45 F17 timber
3. 100x50x3.0 RHS

The type of hold-down method and spacing depends on the top plate, roof type/span, and wind classification. Refer to Table 15.1 for specifications. For high wind areas, the bracing design is likely to require tie-down rods which will drive that as the hold-down method.

Table  15.2 Reinforced Wall – N12 Bars at Nom. 1000mm CTRS

Wall
 Length
 (mm)
Min. No. of
 N12 Bars
Ultimate Racking Capacity (kN)
150mm PowerBlock 250mm PowerBlock
900 2 5 6
1200 2 8 8
1800 3 16 18
2400 3 24 25
3000 4 36 38
3600 5 45 46
4800 6 54 56
6000 7 63 66

Base of Wall

Fig 15.6 Hebel PowerBlock work on Stiffened Raft Slab Edge Foundation (elevation)

 Fig 15.7  Concrete PowerBlock Sub-Floor Detail (elevation)

 Fig 15.8  Double Brick Sub-Floor Detail (elevation)

Fig 15.9 Ring Beam Internal Non-Loadbearing Wall (elevation) (No tie down – as specified by design engineer)

Top of Wall

Fig 15.10 Roof Top Plate Fixing to Hebel Wall – Tie-Down Rod ( elevation)

Fig 15.11 Internal Hebel Load Bearing Wall and Timber Floor Frame Junction (elevation)

Wall Junctions

Fig 15.12  External Wall and Internal Partition Wall Junction  (plan).

Fig 15.13  External Corner with Control Joint (plan)

Control Joints

Fig 15.14 Control Joint detail (elevation)

Fig 15.15 Typical Bond Beam Control Joint – elevation (Location where no tie down required – as specified by engineer)

Fig 15.16 Typical Ring Beam Control Joint – elevation (Location where no tie down required – as specified by engineer)

Fig 15.17 Typical Control Joint – plan 

Fig 15.18 Hebel PowerBlock work Typical Movement Joint Detail (elevation)

Fig 15.19 Hebel PowerBlock work Typical Movement Joint Detail (plan)

Fig 15.20 Built-in Column Detail (plan)

Fig 15.21 Built-in Column Detail (elevation)

Appendix A – Carpet Installation

Panel Surface Preparation

Sweep the floor surface to remove debris and loose

particles. Expose all surface blemishes such as chips, cracks, gaps, ridges or the like. Fill all unacceptable locations with an appropriate and compatible patching compound such as Hebel Patch or levelling compound as required.

Ensure panels are then dry.

Carpet Smooth Edge Installation

Installation of Carpet Smooth Edge (Gripper) is to be in accordance with AS/NZS 2455.1:1995.

Installation of carpet gripper prior to laying carpet requires the use of specifically selected nails or course threaded screws. Standard fixings supplied with the carpet gripper are not suitable for fixing to Hebel PowerFloor panels. Carpet gripper strips are available without factory supplied nails. For carpet gripper installation near the panel edge, only glue is recommended. If relying on glue only, the carpet can not be stretched until the glue is set after approximately 24 hours.

Table A.1 – Carpet Smooth Edge Fixings

Fixing Type Description Application
Method
Installation Notes
Twist Nails 51mm dome
head twist nail
Coil Nail Gun
(Refer to Fig A.1)
The head of the twist nail
should finish flush with
the surface of the gripper
strip
Screws Type 17 point
– course thread
No. 8g x 50mm
– Countersinking
screw
Makita 6834
Auto Feed
Screwdriver
(Refer to Fig A.2)
The head of the twist nail
should finish flush with
the surface of the carpet
gripper strip
Screws Type 17 point Trimhead deck
Screw.
4.2 x 50mm
4.2 x 65mm
Quickdrive auto feed The head of the screw
should be flush with the
smooth edge

Fig A.1                       Fig A.2

Underlay Installation

Minimum medium duty underlay is to be used. No other special requirements.

Carpet Installation

As per carpet manufacturer’s guidelines.
No other special requirements.

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