Stay-In-Place (SIP) Formwork
Octaform: Concept of Octaform (Courtesy of Octaform System Inc.)
Octaform: Step 1. Delivery to Site Work Procedures of Octaform (Courtesy of Octaform System Inc.)
Octaform: Step 2. Panel Assembly & Bracing Work Procedures of Octaform (Courtesy of Octaform System Inc.)
Octaform: Step 3. Reinforcing Installation Work Procedures of Octaform (Courtesy of Octaform System Inc.)
Octaform: Step 4. Filling with Concrete Work Procedures of Octaform (Courtesy of Octaform System Inc.)
Figure 1. Octaform: Brunkild, MB tank (Courtesy of Octaform System Inc.)
Figure 2. Amico: Flushing Bay Combined Sewer Overflow Retention Facility Flushing, NY (Courtesy of Amico)
Figure 3. Amico: Berry Street Tunnel Pittsburgh, PA (Courtesy of Amico)
CSS: Circular Carbon Tubes (Courtesy of CSS in UCSD)
CSS: Carbon and E-glass Fiber Reinforced Polymer Deck Panels (Courtesy of CSS in UCSD)
The use of aggregate materials, which are strengthened by a bonding medium or cement, has lasted with the beginning of construction. For many years, the use of various disposable or reusable wood forms for almost all types of concrete forming has been a general forming way. However, wood forming, the most common and previously cost effective option, has been challenged by a result of world wide restrictions on harvesting and the need to utilize a diminishing resource in a highest cost and best use fashion. Also, costs have increased significantly for plywood and dimensional lumber. Recently, reusable wood or metal frames have become popular for concrete construction. Even though these forms are useful in many applications and less wasteful, these forms still provide construction engineers with unsolved problems. That is, these must still be assembled, disassembled, cleaned and removed from the job site and stored. This is a time consuming and costly process made less practical by the inflexible nature of the large panel design. The resulting concrete structure is unfinished both inside and out. Thus, various alternatives to wood have been tested and advanced as viable replacements so far. These include steel, concrete blocks and various vinyl composites, which are removed or remain in place. Among these systems is the conventional Stay-In-Place (SIP) forming system.
Early versions of SIP forming systems did not satisfy designer's expectation due to inflexibility of design and the fact that many raw materials lacked the necessary composition to offer long term cladding of the basic concrete structure as an option. In addition, early SIP products had some barriers from design deficiencies that replaced traditional methodologies with an alternative set of construction challenges. With the recent development of composite materials, SIP system are offering architects and engineers numerous advantages over competitive systems such as maximum flexibility, cost saving, and efficient time control in the various construction field; residential, commercial, industrial building and bridge as well. SIP systems have been applied to various type of project providing various panels composed of synthetic materials such as polyvinyl chloride (PVC), galvanized coiled sheet steel, fabricated steel, carbon/epoxy thin shell and so on for the specific requirement of each project. The Octaform Wall System™ for building construction, AMICO Stay-form for multi-pose construction, and Carbon Shell System (CSS) in University of San Diego for bridge construction are introduced.
The Octaform Wall SystemTM
The Octaform Wall System™ consists of various PVC panels, connectors and strengtheners that connect together to form a water and fire-resistant vinyl protective shell that encapsulates the concrete, reinforcing steel and insulation. The design of the Octaform Wall System offers the flexibility to configure in straight lines, curves or circles quickly and easily. The forms stay permanently in place, eliminating the need to install additional cladding on the outside or inside of the building.
AMICO Stay-form is fabricated from hotdipped galvanized coiled sheet steel of 26 ga. thickness for standard grade material at 27" x 97" finished sheet size and of 25 ga. sheet for heavy grade material at 27" x 97 " finished sheet size allowing the subsequent formation of solid sheet V-Ribs of 3/4" depth running parallel to the length of sheet and spaced 3-7/8" apart. Construction joints are easily made with Stay-form. Either side of Stay-form provides a substantial key for bonding abutting pour faces-especially so when the mix is of sufficient viscosity to cause small protrusions of the pour to project through the mesh to the opposite side causing such surface irregularities as to provide a made-to-order key for the pour interface. Consequently, no chipping or other joint preparation is necessary. To erect a partition of Stay-form, side adjoining sheets should be lapped and wire-tied at approximately 6" O.C (On Center). with 16 ga. soft galvanized tie wire. End adjoining sheets should be lapped 2" and lap should occur over a support. If an end lap should occur between supports, such lap should be of 4 inches length. End laps, of course should be secured with wire-tying just as side laps. Due to the relatively light-gage material of which Stay-form is fabricated, sheets may be readily cut lengthwise with hand shears and cross-wise by initially snipping the ribs along the path of the cut and bending the sheet at the cut to open up the ribs. Then the grid web between the cut-ribs can be readily cut with hand shears. Openings to accommodate conduit and rods may be made with an "X" cut at the center of conduit entry. The ribs of Stay-form may be placed in either a vertical or horizontal position dependent on the orientation of the supporting structure but in any event, best results are obtained when the ribs are placed so that they project in the direction towards the first pour.
Carbon Shell System (CSS) in University of California, San Diego
The CSS technology is licensed to Composite Solutions, Inc. (CSI) for use in designing and constructing innovative building and bridge structures that are seismically resistant and affordable. The carbon shells perform like conventional steel reinforced beams but contain no steel rebar. They are made of lightweight carbon fiber-reinforced polymers (CFRPs) that are assembled and filled with concrete at the construction site. The shells, which are long, hollow tubes, act as SIP forms designed to replace rebar and conventional temporary formwork for constructing concrete girders and columns. The modular bridge system utilizes carbon and e-glass Fiber-Reinforced Polymer matrix (FRP) composite components in conjunction with conventional construction materials. The bridge consists of a two span continuous system with a beam-and-deck superstructure. The development of the new bridge system is based on the carbon shell system technology in which carbon/epoxy tubes filled with lightweight concrete serve as structural elements. The girders consist of carbon reinforced concrete in which the carbon tube serves as external reinforcement and formwork for the infill concrete. The structural slab is composed of modular E-glass deck panels weighing about one-fourth of a conventional reinforced concrete deck. The beam-and-slab bridge superstructure is thus composed of longitudinal carbon shell girders connected across their tops with a fiberglass composite deck.
The Octaform Wall SystemTM
- Versatile system and flexible designs
- Fast to learn and easy to use
- Economic transportation and installation
- Lower energy costs and greater reliability
- Fewer repairs and lower maintenance costs
- Continuous slab or wall forming over joist supports
- Easy to form due to multiple configurations to accommodate curves, angles, and corners
- Excellent support for concrete
- Easy cut to size and easy penetrating
Carbon Shell System
- Little effort or manpower because of being manufactured off-site and putting into place
- Time and cost saving due to the eliminated rebar work
- Economic installation due to light weight of composites
- Greater durability with reduced long-term maintenance
The Octaform Wall SystemTM
This system has been used for various construction project; residential, commercial, and Bruntankild, MB tank (Figure 1)
This system was used for bulkheads with keyways in base mat pour in Montgomery Point Lock and Dam Project, Rosedale, MS. The lock and dam is 175 feet wide and 1200 long and will require 250,000 cubic yards of concrete. In Flushing Bay Combined Sewer Overflow Retention Facility Project (Figure 2), this system was applied to bulkhead (90,000 sq. ft. of Stay-form ) for 6 ft thick heavy mat slabs with inverted keyways and water stops. In Berry Street Tunnel, Pittsburgh, PA (Figure 3), Stay-form was used as a backstop for the shotcrete applications. Stay-form was attached on the outside of the tunnel to truss girders and after an application of welded wire mesh prior to the application of the shotcrete.
Carbon Shell System
This system was presented as an as an alternate to the Kings Stormwater Channel Bridge by the California Department of Transportation (Caltrans). The carbon shell alternate bridge design consists of a 20.1m (66 ft) two-span continuous beam-and-slab type bridge with a five-column intermediate pier.
- Initial cost for form design and installation can be higher than that of conventional forming systems.
- Lack of familiarity for installation and maintenance by practicing engineers may cause higher cost and lower productivity than expected.
- More specified form design is required
- Service and maintenance contract between an original system supplier and a form installer a can be required, if they are different.
Points of Contact
- Dave Richardson, Director for Octaform Systems Inc. Suite 520, 885 Dunsmuir Street, Vancouver, BC, Canada, V6C 1N5. Phone: (604) 408-0558, 1-888-786-6282 Fax: (604) 408-0595 Email: email@example.com Website: http://www.octaform.com
- Gary Maylon, Product Manager for Amico Stay-form. Alabama Metal Industries Corporation, 3245 Fayette Avenue, Birmingham, AL 35208. Phone: (205) 787-2611, (800) 366-2642 Fax: (205) 786-6527 Email: firstname.lastname@example.org Website: http://amico-stayform.com
- Gilbert A. Hegemier, Associate Professor of Structural Engineering in University of California, San Diego. The Department of Structural Engineering, 9500 Gilman Drive, La Jolla, CA 92093-0085 Phone: (858) 534-4280· Fax: (858) 534-6373 Email: email@example.com Website: http://www.structures.ucsd.edu/index.php?page=structural_engineering/people/faculty/hegemier
- Octaform System Inc. Website: http://www.octaform.com
- Amico Stay-form. Website: http://amico-stayform.com
- Carbon Shell System in University of California, San Diego. Website: http://www.structures.ucsd.edu
- Zhao, L et al. (2000) "Preliminary Evaluation of The Hybrid Tube Bridge System" Web sources: http://www.dot.ca.gov/hq/esc/earthquake_engineering/Research/modgirde.pdf
- Bakht, B and Chu, K. (1997). "Testing of Reinforced Concrete Stay-In-Place Formwork for Deck Slab" Annual Conference of The Canadian Society for Civil Engineering, May 27-30.
- Hooks, J (2001). "Innovative Materials for Bridges of The 21st Century" 46th International SAMPE Symposium May 6-10.
Neither the Construction Industry Institute nor Purdue University in any way endorses this technology or represents that the information presented can be relied upon without further investigation.