v2018.1RC
Better Partners. Better Products. Better Outcomes.
Design Manual
TABLE OF CONTENTS
REDICOR™ REPRESENTATIVE CONTACT INFORMATION.......................................................................................REDICOR™ SYSTEM OVERVIEW...................................................................................................................................................... DESIGN TEAM QUICK REFERENCE...............................................................................................................................SIZING AND MODULARIZATION...................................................................................................................................................... FORM WALL THICKNESS......................................................................................................................................................... MODULE CONFIGURATION................................................................................................................................................ MODULE JOINT ELEVATIONS........................................................................................................................................... COMPOSITE MODULE CONFIGURATIONS.........................................................................................................FINISHES.................................................................................................................................................................................................................STAIRS......................................................................................................................................................................................................................OPENINGS.................................................................................................................................................................................................ALTERNATE FRAMING...............................................................................................................................................................................STRUCTURAL..................................................................................................................................................................................................... REINFORCEMENT................................................................................................................................................................................. REDICOR™ SPECIFIC REBAR PLACEMENT PATTERNS............................................................................. CORNER REINFORCEMENT................................................................................................................................................. OPENING REINFORCEMENT................................................................................................................................................ SPECIAL STRUCTURAL WALLS (SEISMIC APPLICATIONS).................................................................... FOUNDATION CONNECTION.......................................................................................................................................... FLOOR AND ROOF CONNECTIONS....................................................................................................................... STANDARD EMBED CONNECTION TABLES.................................................................................................... STANDARD CONNECTIONS FOR SLABS............................................................................................................. STANDARD CONNECTIONS FOR STEEL BEAMS.......................................................................................... STEEL BEAMS TRANSFERRING AXIAL LOADS................................................................................................. OPEN WEB STEEL JOISTS AND JOIST GIRDERS...........................................................................................CONSTRUCTION............................................................................................................................................................................................FORM SYSTEM INSTALLATION.......................................................................................................................................................... REBAR AND CONCRETE PLACEMENT.................................................................................................................... CONCRETE PLACEMENT RATE.......................................................................................................................................... CONCRETE MIX RECOMMENDATIONS................................................................................................................ TEMPORARY CONSTRUCTION LOADS...................................................................................................................PRODUCT SPECIFICATION GUIDE................................................................................................................................................CODE OF STANDARD PRACTICE................................................................................................................................................
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Vulcraft reserves the right to change the design or details of its products without notice. The information in this catalog is presented for general information only and is not to be used or relied upon for any application without complete review of the proposed application and without a complete review by a licensed professional architect, engineer, designer or other qualified professional.
Vulcraft assumes no liability whatsoever for the accuracy or completeness of the information contained herein.
Vulcraft makes no representation or warranty of any kind, either express or implied, respecting any information contained in this catalog including, but not limited to, the accuracy, completeness or suitability of such information for any particular purpose or use.
In addition, Vulcraft expressly disclaims any liability for incidental, special, consequential or punitive damages including, but not limited to, loss of profits or loss of use arising out of this catalog or its use.
Vulcraft’s liability, warranties and other obligations with respect to its products are set forth in the Terms and Conditions of Sale provided to Buyer in connection with the provision of such products.
As used herein, references to Vulcraft include its parents, affiliates and subsidiaries.
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ABOUT US
Nucor’s MissionNUCOR IS MADE UP OF MORE THAN 20,000 TEAMMATES WHOSE GOAL IS TO TAKE CARE OF
OUR CUSTOMERS. WE ARE ACCOMPLISHING THIS BY BEING, THE SAFEST, HIGHEST QUALITY, LOWEST COST, MOST PRODUCTIVE and MOST PROFITABLE, STEEL AND STEEL PRODUCTS
COMPANY IN THE WORLD. WE ARE COMMITTED TO DOING THIS WHILE BEING CULTURAL AND ENVIRONMENTAL STEWARDS IN OUR COMMUNITIES WHERE WE LIVE AND WORK. WE ARE
SUCCEEDING BY WORKING TOGETHER.
Taking care of our customers means all of our customers: Our Employees, Our Shareholders, and the people who purchase and use our products.
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RediCor™ SALES REPRESENTATIVES
Glenn ElrodSales ManagerP: 402.644.8520E: [email protected]
Ryan AndersonProject ManagerP: 402.644.8525E: [email protected]
Jim FreibergSales RepresentativeP: 303.921.7289E: [email protected]
Paul JohnsonDesign Build SupervisorP: 402.844.2581E: [email protected]
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RediCor™ SYSTEM OVERVIEW
GENERAL SYSTEM DESCRIPTION
The RediCor™ Form System is a stay-in-place modular steel form system engineered to simplify and accelerate on-site construction of cast-in-place reinforced concrete. The form system is designed to support light construction loads, which allows floor and roof framing members to be erected prior to concrete placement. With review of design from the specifying professional, reinforced concrete cores formed with RediCor can also be an easy to construct alternative to masonry cores.
FEATURES OF THE FORM SYSTEM
• Factory built, high tolerance, steel construction • Rapid, simplified erection procedure • Erection of form system can be concurrent with erection of building framing • Horizontal reinforcement steel installed at the factory • Rapid field installation of vertical reinforcement facilitated by guide fixtures • Stairs pre-installed at the factory, providing safe early trade access to building floors • Form system is designed by Vulcraft to support limited construction loads prior to placement of concrete; typically self-weight of the framing member plus a 20 psf construction live load. • RediCor™ modules do not require stripping • Corrugated steel surface can be left exposed or clad with almost any architectural material • Available for forming cast-in-place reinforced concrete cores ranging in thickness from 8” to 20” • Contact Vulcraft for LEED information.
DESIGN TEAM QUICK REFERENCE
The following is a quick reference for the building design team when specifying the RediCor™ Form System. The specifying professional(s) is responsible for producing drawings and specifications which define the requirements for the core walls and stairs in the final constructed form.
The structural drawings or specifications should include:
•Elevations for all core walls, dimensioned for all geometry and annotated with required demands on the cores. Vulcraft will then proportion the steel accordingly at prescribed spacing to avoid conflicts with the form system. If a specific reinforcement ratio is required beyond what is required for applied loading only, i.e. drift or displacement, the specifying professional shall provide required reinforcement ratios to be included in the core design.
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•Details of all special reinforcing elements including headers and boundary elements (the design of these elements will be submitted at approval and designed by Vulcraft)
•Nominal thickness of core walls. This is the design thickness required by the specifying professional’s wall design. Typical thicknesses would be 8”, 10”, 12”, 14,” 16”, 18”and 20” nominally. Due to the 1” steel deck skins of the form system, walls will have an out-to-out dimension of 10”, 12”, 14”, 16”, 18”, 20”, and 22” respectively.
•Core elevations must clearly define rough opening sizes and locations. If no rough opening is provided, 1” will be added to each side of the opening.
•Definition of the top of foundation walls supporting the core walls.
•The preferred connection between core walls and foundation walls. If welding is not available on site, contact Vulcraft for a weldless alternative. Final embed and connection design will be performed by Vulcraft.
•All loads at the connection between the core walls and foundation walls. These loads are used to design the connection at the foundation. Loads must be broken down per load type (dead, live, construction live, etc.) and indicated as unfactored loads. The specifying professional provides all gravity, shear, tension, and compression loads into the core.
•End reactions for all beams and other floor or roof members framing into the concrete core. These loads must represent the end reactions on the core during the occupied life of the building and must be broken down into their load types. Refer Figures 1 and 2 for an example of how loads should be communicated on contract documents to Vulcraft for proper design and detailing of the concrete core walls and associated connection material.
•End reactions for all beams and other floor or roof members framing into the core prior to the slab placement on floor and roof levels. (Construction loading to be supported by RediCor™.)
•All loads and deflection limits required for structural design of stairs and handrails
The architectural drawings must include:
•Any geometry of the stair cores not defined by the structural drawings
•Stair layouts including stair type, rise, run, and plan dimensions
•Handrail requirements including type of rail, finish, and standoff from wall
RediCor™ SYSTEM OVERVIEW
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FIGURE 2: EMBED LOADS
The specifying professional provides all loads broken into tension/compression, shear, and gravity as unfactored loads, and provides temporary construction loads to the core prior to concrete placement in form system or on slabs.
RediCor™ SYSTEM OVERVIEW
SIZING AND MODULARIZATION
FORM WALL THICKNESS
The RediCor™ Form System has a width of 1” on each face of wall including the form corrugations. The form itself and the concrete in the corrugations should not be considered as part of the structural capacity of the core. Therefore, shear walls formed using the RediCor™ Form System must have a plan dimension 2” thicker than the wall thickness required by the structural design of the core.
FIGURE 3: REDICOR™ FORM WIDTH
TABLE 1: AVAILABLE REDICOR™ WALL THICKNESSES
Representative RediCor™ Wall Thicknesses
Nominal Thickness Overall Thickness8” 10”10” 12”12” 14”14” 16”16” 18”18” 20”20” 22”
Note: Contact a RediCor™ Representative to discuss the availability of wall thicknesses which are not represented within this table
Vertical Rebar
Lattice Column
Horizontal Rebar
Truss
Vulcraft 1.0C Galv. Steel Deck
10”
8”
1”
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SIZING AND MODULARIZATION
MODULE CONFIGURATION
A typical RediCor™ module is a four-sided box. The height of the module is determined by Vulcraft, and is approximately one half story height. Please confirm the suitability of something other than a four sided box with your Vulcraft representative prior to preparing contract documents.
Module plan dimensions are determined by the specifying professional.
The maximum size of a single module is controlled by shipping regulations and fabrication capabilities. The standard maximum module size is 8’ x 15’ x 32’. Note that local shipping regulations may superseded these maximum dimensions. For cores exceeding these plan dimensions, compound modules spliced together on site may be an option. Please contact a Vulcraft representative for more information.
FIGURE 4: STANDARD MAXIMUM MODULE DIMENSIONS
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MODULE JOINT ELEVATIONS
Vulcraft determines module joint locations. Joint elevations typically occur several inches below the top of concrete elevation.
When both stair and elevator cores occur in a building, the typical practice is to splice the elevator core modules at the same levels as the stair core modules.
SIZING AND MODULARIZATION
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COMPOSITE MODULE CONFIGURATIONS
Composite plan shapes and plan dimensions exceeding single module shipping limitations can be achieved by combining module shapes on site. Contact a Vulcraft representative for availability and recommendations.
FIGURE 4: POTENTIAL COMPOSITE MODULE SHAPES, CONTACT A VULCRAFT REPRESENTATIVE FOR MORE INFORMATION
SIZING AND MODULARIZATION
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FINISHES ATTACHMENT METHODS
Furring Strips
Wood or steel furring strips can be used with the RediCor™ Form System. Typical attachment methods (masonry screws, shot pins, etc.) can be used. If screwed fasteners are to be used to install materials prior to concrete placement, avoid placing fasteners in the same vicinity of rivets. This prevents screws from impacting the form structure. Though furring strips may be attached prior to concrete placement, the finishes themselves (such as gypsum board) must not be installed until after concrete placement. This will prevent unnecessary loads on the unfilled form system and damages to interior finishes during concrete placement.
Masonry Ties
Masonry ties can be attached to the RediCor™ Form System in the same manner as if it where a typical CIP wall. Because the form system includes a stay-in-place internal steel structure, installing drilled fasteners may be difficult. Therefore, powder-actuated fasteners are recommended.
Direct Attachment
Certain finishes can be attached directly to the RediCor™ Form System. These include gypsum wall board, wood or metal paneling, or any other finish that does not require furring strips on other anchors. After concrete placement, masonry screws may be used. Adhesives can also be used. Ensure any adhesives used are compatible with galvanized metal.
Unfinished (Galvanized Steel Deck)
The RediCor™ Form System can be left bare in both interior and exterior conditions if no finish is required or if the metal deck finish is desired.
As stated in the features of the form system, virtually any cladding material may be applied to the interior or exterior surface of the form. When cladding is to be applied to the interior of the core, the cladding thickness must be taken into account when determining all stair dimensions.
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STAIRS
Metal Grating
Both stair treads and landings can be produced from Nucor Grating and pre-installed in the RediCor™ Form System at the factory. Any of Nucor’s Grating Profiles can be used to fabricate the stair system.
Metal Pan with Concrete Fill
Metal pan stairs can be installed at the factory, this includes the stair pans and metal deck for the landings. Once in place, the concrete can be placed in the stair system along with the rest of the concrete on the project. The stair pans allow workers to access the upper floors as soon as the cores are placed, reducing the need for lifts or ladders.
Vulcraft offers two standard stair and landing types: metal pan stairs and metal grating stairs. Structural design of the stairs, landings, and their connection to the core is by Vulcraft. All dimensions, loads, and serviceability requirements needed for the structural design of the stairs and landings must be supplied to Vulcraft by the specifying professional. If other types of stairs are desired or required for your project, please contact a Vulcraft representative.
Handrails and Guards
Vulcraft offers pipe or tube balustrades and handrails. Structural design of the handrail system is provided by Vulcraft. All dimensions, loads, and serviceability requirements needed for design of the handrail system must be supplied to Vulcraft by the specifying professional.
Stairs and handrails fabricated by others may also be installed in the RediCor™ Form System. However, any connections that require modifications of the standard RediCor™ form must be provided as soon as possible in the design process to be considered in the design and fabrication of the form system.
NOTE: ALL LIFE SAFETY AND DIMENSIONAL REQUIREMENTS OF STAIR DESIGN IS THE RESPONSIBILITY OF THE ARCHITECT OF RECORD.
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OPENINGS
Doors & Windows
Door and window openings will be formed with stay-in-place light gauge galvanized metal that is attached to the form system. Door and window frames can be welded or attached with fasteners to the form system. The RediCor™ Form System is not designed to carry any loads from doors or windows. All doors and windows should be installed after concrete is placed and cured. If modifications to the typical openings are required, Vulcraft must be made aware as soon as possible in the design process so that changes can be made prior to form construction.
Openings During Construction
At large wall openings, Vulcraft provides temporary bracing for dimensional stability during shipping and erection. These temporary braces are removed after concrete placement and may be returned to Vulcraft for recycling or disposed of in an appropriate manner.
Dimensions Required for Fabrication
Openings in the RediCor™ Form System can be specified in the same manner as if they were in a typical concrete wall. A rough opening size must be provided to Vulcraft, If no rough opening is provided, 1” will be added to each side of the opening.
Opening Locations
All rough openings must be a minimum of the overall wall thickness from the outside corner of the core. Placing openings closer causes issues with fabrication of the form system. For example, an 8” nominal (10” out-to-out) RediCor™ form would require openings to be placed a minimum of 10” from the outside corner of the form system.
Openings Required for Other Trades
Any openings in the core walls required for other trades (i.e. fire sprinklers, electrical, plumbing, HVAC, etc) must be addressed in the same manor as for a standard-formed CIP wall. Any sleeves, conduits, or additional fireproofing are not provided by Vulcraft.
The structure of the RediCor™ Form System must not be damaged or removed prior to placement of concrete. However, drilling through or removing portions of the steel deck skin and internal form components is acceptable after concrete has cured. If requested, Vulcraft can indicate locations on the core that can be field cut for other trades.
NOTE: Braces to be removed after concrete placement
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ALTERNATE FRAMING
Floor and Roof Framing Within Core
Typically, shear cores within buildings are located at stairways and elevators. However, the construction of a shear core lends itself to many other uses as well, such as:
•Storage Rooms
•Storm Shelters
•Panic Rooms
At the option of the buyer, Vulcraft can supply steel framing and steel deck (composite or form deck) for floors on the interior of the cores. Framing types available include open web steel joists and structural steel beams. All roof and floor framing must be designed and specified by the specifying professional. End reactions of this framing must be provided to Vulcraft by the specifying professional to allow embedded connections to the core wall to be designed by Vulcraft.
SLOPING ROOF CONDITIONS
The RediCor™ Form System may be modified to accommodate sloped roof conditions as shown in the below detail. All parts supplied by Vulcraft are designed by Vulcraft. The specifying professional must provide all loads required for design.
FIGURE 5: SLOPING ROOF AT TOP OF CORE
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STRUCTURAL INFORMATION
The RediCor™ Form System is intended to act as a form for cast-in-place reinforced concrete cores. These cores play an important role in both gravity and lateral force resisting systems of a building. The RediCor™ Form System is best suited for low to mid-rise building construction, especially for buildings such as hotels, apartments, and offices.
Reinforced Concrete Shear Core Design Principals
ForcesReinforced concrete shear cores play an important role in transferring in-plane, lateral forces to the building foundation. Such forces are typically caused by wind or seismic activity. Reinforced concrete shear cores also add stiffness to the building system and resist vertical loads from floor and roof framing.
Design Standards and Building CodesThis document cites various ACI standards and the IBC for reference purposes only. The specifying professional must use the same standard of care when specifying a RediCor™ formed shear core as he or she would with any other reinforced concrete shear core. All applicable building codes and standards must be followed.
Material SpecificationsIt is recommended that the maximum aggregate size of concrete mixes used within the RediCor™ Form System not exceed ¾”. The design of the concrete mix and specification of concrete compressive strength is by Vulcraft.
ReinforcementThe RediCor™ Form System provides a simplified rebar installation process. Reinforcement for the concrete shear core is designed and specified by Vulcraft and factory built to match those specifications. Horizontal bars are installed in the factory, and vertical bars are shipped cut-to-length and installed by hanging at the top of each module in the field.
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Be aware of a few limitations for rebar mat placement: • The RediCor™ Form System can accommodate either a single or double mat of rebar at the exterior faces of the walls. A single, centered mat is not currently an option. • Vertical bars must be spaced at 8” or 16” increments. • Horizontal bars must be spaced at 4” increments. • The images below depict the reinforcing zones for an 8” and 12” RediCor™ formed shear wall. • From the images below, it is apparent that the ¾” cover for #11 and smaller bars required by ACI 318 will be maintained. • Note, reinforcement zones below are not adequate for below grade applications. The RediCor™ Form System is not currently recommended for below grade construction.
FIGURE 6: REINFORCING ZONES FOR 8” AND 12” WALLS
STRUCTURAL INFORMATIONREINFORCEMENT
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The rebar placement patterns below are recommended for use with the RediCor™ Form System.
Note: Due to form system limitations, vertical rebar must be spaced at increments of 8” o.c.
TABLE 2 - TYPICAL VERTICAL REINFORCEMENT BAR PATTERNS
Note: Due to form system limitations, horizontal rebar must be spaced at increments of 4” o.c.
TABLE 3 - TYPICAL HORIZONTAL REINFORCEMENT BAR PATTERNS
Typical Vertical Reinforcement Bar Patterns
Bar Size SpacingBar Area
(in2)
Area of Steel PerHorizontal Linear Foot of Wall
Single Mat Double Mat#4 1'-4" 0.20 0.15 0.30
#5 1'-4" 0.31 0.23 0.46
#6 1'-4" 0.44 0.33 0.66
#7 1'-4" 0.60 0.45 0.90
#8 1'-4" 0.79 0.59 1.19
#4 8" 0.20 0.30 0.60
#5 8" 0.31 0.46 0.92
#6 8" 0.44 0.66 1.32
#7 8" 0.60 0.90 1.80
#8 8" 0.79 1.19 2.37
Typical Horizontal Reinforcement Bar Patterns
Bar Size SpacingBar Area
(in2)
Area of Steel PerVertical Linear Foot of Wall
Single Mat Double Mat#4 1'-4" 0.20 0.15 0.30
#5 1'-4" 0.31 0.23 0.46
#6 1'-4" 0.44 0.33 0.66
#7 1'-4" 0.60 0.45 0.90
#8 1'-4" 0.79 0.59 1.19
#4 8" 0.20 0.30 0.60
#5 8" 0.31 0.46 0.92
#6 8" 0.44 0.66 1.32
#7 8" 0.60 0.90 1.80
#8 8" 0.79 1.19 2.37
STRUCTURAL INFORMATIONREBAR PLACEMENT PATTERNS
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STRUCTURAL INFORMATIONREINFORCEMENT
CORNER REINFORCEMENT
In lieu of the traditional 90-degree hooked reinforcement bar, Vulcraft provides a 180-degree hooked reinforcement detail as shown below:
FIGURE 7: STANDARD 180° HOOK REINFORCEMENT DETAIL FOR CORNERS
SEE TABLE ON PAGE 22 FOR MAXIMUM REINFORCING BAR SIZE PER WALL THICKNESS
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STRUCTURAL INFORMATIONREINFORCEMENT
Maximum Rebar Size (standard mat) Based on Wall Thickness and Cover Requirements
Wall ThicknessMinimum Cover
Requirements Maximum Rebar Size
8”
3/4” 6
1” 6
1 1/2” 5
10”
3/4” 8
1” 8
1 1/2” 7
12”
3/4” 8
1” 8
1 1/2” 8
Notes:
1. Considers transverse reinforcement with standard 180-degree hooks per ACI 318-14 Table 25.3.1
TABLE 4 - MAXIMUM HORIZONTAL REINFORCING BAR SIZE PER WALL THICKNESS
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OPENING REINFORCEMENTReinforcement around openings, such as windows and doors is by Vulcraft. RediCor™ form components are installed for the purpose of concrete forming only and shall not be considered to provide reinforcement around openings during the life of the structure. In some cases, steel angle walers will be required to accommodate the reinforcement and ensure the strength of the formwork. These walers must be removed after concrete is placed.
STRUCTURAL INFORMATIONREINFORCEMENT
FIGURE 8: REMOVABLE FORM WALERS REQUIRED FOR SOME HEADER REINFORCEMENT CONDITIONS
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FIGURE 9: EXAMPLE OF HEADER REINFORCEMENT DETAILS THAT CAN BE ACCOMMODATED BY THE REDICOR™ FORM SYSTEM
STRUCTURAL INFORMATIONREINFORCEMENT
SEE TABLE ON PAGE 25 FOR MAXIMUM REINFORCING BAR SIZE PER WALL THICKNESS
HEADER REINFORCEMENTFor headers over openings, The RediCor™ Form System can accommodate reinforcement that consists of a single or double layer of horizontal bars confined by stirrups. Bend diameters and extension lengths shall comply with minimums given by ACI 318. Header reinforcement will arrive on-site installed as required by the core design.
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STRUCTURAL INFORMATIONREINFORCEMENT
Maximum Rebar Size (Headers) Based on Wall Thickness and Cover Requirements
Wall Thickness
Minimum Cover Requirements
Vertical Stirrup Size#3 #4 #5 #6
8”
3/4”
Max
imum
Hor
izon
tal
Reba
r Siz
e
#6 #6 #5 -
1” #5 #5 - -
1 1/2” - - - -
10”
3/4” #8 #8 #7 -
1” #7 #7 #7 -
1 1/2” #6 #6 #6 -
12”
3/4” #8 #8 #8 -
1” #8 #8 #8 -
1 1/2” #8 #8 #8 -
Notes:
1. Considers transverse reinforcement with standard 180-degree hooks per ACI 318-14 Table 25.3.12. All headers with less than 1 1/2” cover require removable angle walers on outside of form3. Where “-” is indicated, rebar will not fit due to internal form work structure and/or thickness of wall
TABLE 5 - MAXIMUM HEADER REINFORCING BAR SIZE PER WALL THICKNESS
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FIGURE 10: TYPICAL WELDED PLATE FOUNDATION CONNECTION
STRUCTURAL INFORMATIONCONNECTIONS
SPECIAL STRUCTURAL WALLS (SEISMIC APPLICATIONS)The RediCor™ Form System is currently under development for use with boundary elements as required for special detailing requirements. At this time, the RediCor™ Form System cannot accommodate the special reinforced boundary zones at the corners and openings of reinforced concrete shear cores qualifying as special reinforced concrete shear walls by ACI 318.
FOUNDATION CONNECTIONThe vertical reinforcement at the bottom RediCor™ module of each core is connected to the building foundation using a welded plate connection, contact Vulcraft for a weldless alternative if necessary. In either case, Vulcraft furnishes the design and embedded materials required to make the connections. Embed plates or alternates are installed by the foundation contractor. All loads at this connection must be provided to Vulcraft by the specifying professional for design of this connection.
The bottom of the RediCor™ base module is supported nominally 6” above the top of the foundation level by adjustable leveling pedestals built into the module. The 6” space between the module and the foundation allows access for physically making the attachment between the embedded portion of the connection set in the foundation and the vertical reinforcement in the RediCor™ wall. After this attachment is complete, the concrete contractor provides temporary form material (typically plywood or dimensional lumber) to enclose the 6” space prior to placement of the first lift of concrete.
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
FLOOR AND ROOF CONNECTIONSThe design of floor and roof framing connections is provided by Vulcraft as part of the RediCor™ package. The specifying professional must provide loads at all beams, joists, shelf angles, etc. framing into the core. Loads must be unfactored and broken down by load type (gravity, shear, lateral) Calculations can be provided upon request.
The RediCor™ Form System is designed to support limited construction loads prior to concrete placement. Recommended maximum construction loads and a description of how the specifying professional can calculate these loads are as follows. For loads exceeding these, please consult a Vulcraft representative to assess your individual need. • Shelf angles: self-weight of angle and any metal decking attaching to the angle plus a 20psf vertical construction live load (400plf maximum vertical construction load) • Beam or joist connections: Self-weight of the beam or joist and any metal decking attached to it plus a 20psf vertical construction live load (2000 lb maximum single vertical construction end reaction spaced a minimum of 5’ o.c.) • Note: in no case should floor slabs be placed nor should heavy materials unrelated to RediCor™ installation be stored on the floors prior to concrete placement in the form system
The specifying professional may choose to indicate a preferred type of connection (i.e. shear tab, double clip angle, etc). Coordination with Vulcraft may be necessary for specific details. Some detailing limitations exist when specifying the RediCor™ form system. These limitations include the following: • Due to the fact that the RediCor™ form system is load bearing for limited construction loads prior to concrete placement, embed plates for steel framing must be sized to span between internal RediCor™ form trusses.
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
STANDARD EMBED CONNECTION TABLESThe images and tables that follow describe RediCor™’s typical standard embedded connections for use with the RediCor™ Form System. Vulcraft reserves the right to provide alternate materials and connections that meet the specified load requirements for the project
TABLE 6 - REDICOR™ TYPICAL EMBED CAPACITIES
RediCor™ Typical Embed Capacities
Edge Conditions Embed TypeWall
Thickness
Factored LRFD Shear
(K)
Corner(Reference Details for
Edge Dimensions)
A4
8"
17.0
A5 21.0
A6 25.5
A7 29.9
A4
10"+
18.5
A5 23.5
A6 28.0
A7 33.0
Center(Reference Details for
Edge Dimensions)
A4
8"
61.0
A5 66.0
A6 70.5
A7 74.5
A4
10"
69.0
A5 74.0
A6 78.5
A7 83.5
A4
12"
75.0
A5 81.0
A6 86.0
A7 91.5
Notes:
1. Based on ACI 318-14 Chapter 172. A108 3/4” dia. welded headed studs, 5 5/8” effective depth3. f’c = 4000 psi 4. Not applicable to Seismic C, D, E, F5. NW Concrete (145pcf)6. 1/2” A36 Plate7. Load assumed concentric with bolt group8. Review Figures 11 & 12 for assumed concrete edge distances, reduced edge distances will reduce the capacity of the embedded connection
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
FIGURE 11 - TYPICAL EMBED PLATES AND H.A.S. LOCATIONS FOR CONNECTION OF FLOOR AND ROOF FRAMING TO CORE , “CORNER
CONDITION” CONCRETE EDGE LIMITATIONS FOR TABLE 6. NOTE THAT THE 19” MIN ALLOWS FOR A 4’ 0” O.C. BEAM SPACING.
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
FIGURE 12 - CENTER CONDITION CONCRETE EDGE LIMITATIONS FOR TABLE 6
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
STANDARD CONNECTIONS FOR SLABS (AND SLABS SUPPORTED BY METAL DECK)
Vulcraft provides the connection design of the angle supporting the slab/deck to the core. The specifying professional must provide all loads that must be transferred into the concrete core for connection design. Loads provided must represent the end reactions on the core during the occupied life of the building and must be broken down into their load types (i.e. gravity, shear, lateral, construction load, etc) Vulcraft is responsible for the connection design of the slab to the angle or slab to core wall. This includes the design of connecting items such as headed anchor studs and deformed bar anchors (DBA) into the floor slab.
FIGURE 13 - TYPICAL SHELF ANGLE DETAIL FOR FLOOR OR ROOF DECK SUPPORT
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
TABLE 7 - LOAD CAPACITIES FOR TYPICAL REDICOR™ SHELF ANGLES
RediCor™ Shelf Angle Capacities (f’c = 4000psi, NW concrete)
Anchor Material
Bolt Diam, in
Bolt Spacing, in
Bolt hef, in
Vertical Uniform Load on Outstanding Angle Leg (Factored for LRFD), klf
ASTM F1554 Gr 36
5/8 24 4 2.5
5/8 18 4 3.4
5/8 12 4 3.9
ASTM F1554 Gr 55
5/8 24 4 2.9
5/8 18 4 3.5
5/8 12 4 3.9
Notes:
1. L4x4x3/8, 50ksi angle assumed for all conditions2. 8” thick walls assumed for all conditions3. Edge anchor assumed at 4.5” min from edge of wall
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
FIGURE 14 - TYPICAL SHELF ANGLE DETAIL FOR SHEAR TRANSFER FROM SLAB TO ANGLE USING DEFORMED ANCHOR BAR INTO SLAB
STANDARD CONNECTIONS FOR STEEL BEAMS
Vulcraft provides the connection design of the steel beam to the core. The specifying professional must provide all loads required for connection design. Loads must be provided as unfactored and broken down by load type.
The following tables and figures are examples of the typical beam to core connections that will be provided by Vulcraft. The specifying professional may request a preferred connection type.
Vulcraft will specify the grade and diameter of bolts. Bolts will not be be supplied by Vulcraft.
SLAB TO CORE CONNECTIONS FOR SHEAR TRANSFER
When project shear values require additional attachment of slab to the core, the following details are recommended for use with the RediCor™ Form System. All materials supplied and pre-installed by Vulcraft, including the shelf angle and anchors embedded into the core wall, are designed by Vulcraft. The specifying professional must supply all loads required for design. Loads must be supplied as unfactored and broken down by load type. Any materials not supplied by Vulcraft must be designed by the specifying professional.
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
TABLE 8 - CAPACITIES FOR SHEAR TAB CONNECTIONS FOR W-SHAPED BEAMS
Shear Tab Connections for W-Shaped Beams
Member Depth Rows of Bolts Length of Tab (in)
Max Factored Permanent End
Reaction (Factored for LRFD), k
W8 2 6 29k
W10 2 6 29k
W12 3 9 48k
W14 3 9 48k
W16 4 12 67k
W18 4 12 67k
W21 5 15 85k
W24 6 18 97k
W27 7 21 115k
W30 8 24 130k
Notes:1. All capacities calculated with no beam cope2. Capacities do not include strength of embed plate and HAS
FIGURE 15 - SHEAR TAB FOR W-SHAPED BEAMS
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FIGURE 16- DOUBLE CLIP ANGLE CONNECTION FOR W-SHAPED BEAM,
STRUCTURAL INFORMATIONEMBED CONNECTIONS
TABLE 9 - CAPACITIES OF TYPICAL DOUBLE CLIP ANGLE CONNECTIONS FOR W-SHAPED BEAMS
Double Clip Angle Connections for W-Shaped Beams
Member Depth Rows of BoltsLength of Clip
Angles (in)
Max Factored Permanent End
Reaction (Factored for LRFD), k
W8 2 6 26k
W10 2 6 27k
W12 3 9 47k
W14 3 9 54k
W16 4 12 74k
W18 4 12 82k
W21 5 15 121k
W24 6 18 152k
Notes:1. All capacities calculated with single bottom flange cope to accommodate field installation.2. Capacities do not include strength of embed plate and HAS.
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
FIGURE 17 - SINGLE CLIP ANGLE CONNECTION FOR W-SHAPED BEAM
TABLE 10 - CAPACITIES FOR TYPICAL SINGLE CLIP ANGLE CONNECTION FOR W-SHAPED BEAM
Single Clip Angle Connections for W-Shaped Beams
Member Depth Rows of BoltsLength of Clip
Angles (in)
Max Factored Permanent End
Reaction (Factored for LRFD), k
W8 2 6 21K
W10 2 6 21K
W12 3 9 39K
W14 3 9 39K
W16 4 12 59K
W18 4 12 59K
W21 5 15 78K
W24 6 18 97K
W27 7 21 115K
Notes:1. All capacities calculated with single bottom flange cope to accommodate field installation.2. Capacities do not include strength of embed plate and HAS.
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
STEEL BEAMS TRANSFERRING AXIAL LOADS
Steel beams designed to transfer axial tension or compression loads, commonly referred to as drag struts, should be connected to core walls only at the centerline of the opposing core wall. Vulcraft provides the connection design, including design of any studs or rebar required within the core walls to drag the axial forces into the core. The specifying professional must supply all loads required for connection design. Loads should be provided as unfactored and separated by load type (shear, gravity, tension/compression).
Connection of two drag struts at 90 degrees to each other at a common corner may be impractical due to extreme rebar congestion. Contact a Vulcraft representative to discuss feasibility when required.
OPEN WEB STEEL JOISTS AND JOIST GIRDERS
Vulcraft provides connection design of the steel joist to the core. The specifying professional must provide all loads required for connection design. Loads must be provided as unfactored and separated by load type.
The images and tables below describe typical seated connections provided by Vulcraft. Note that capacities for each connection vary depending on the joist series type. This is due to the eccentricity of the end reaction which is affected by the maximum bearing length available based on the typical joist seat depth for each joist series (max bearing length is typically 4” for a k-series joist and 6” for a long span joist). Joists were assumed to have a ½” hold-back from the face of the embed plate, and to bear as far on to the angle seat as possible (minimum top chord extension length assumed).
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STRUCTURAL INFORMATIONEMBED CONNECTIONS
FIGURE 18 - UNSTIFFENED SEATED CONNECTION FOR JOIST
Unstiffened Angle Seat Connection for Joists
Angle Support Size Max Factored Permanent End Reaction (Factored for LRFD), k
K-series joist LH-series joist or Joist Girder3 1/2 x 3 1/2 x 3/8 5.3K INADEQUATE BEARING LENGTH
4 x 4 x 1/2 10.2k INADEQUATE BEARING LENGTH
5 x 5 x 5/8 13.0k 17.4k
6 x 6 x 3/4 13.0k 27.3k
6 x 6 x 1 25.3k 41.3k
Notes:
1. Assumes 1/4” fillet weld on both vertical legs of angle seat to embed plate2. Calculations per AISC Construction Manual 15th Ed.3. Values in table are for connection capacity only, loads may exceed maximum end reactions for listed joist series
TABLE 11 - CAPACITIES FOR UNSTIFFENED ANGLE SEAT CONNECTION FOR JOIST OR JOIST GIRDER
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FIGURE 19 - TYPICAL STIFFENED SEATED ANGLE CONNECTION FOR OPEN WEB STEEL JOISTS
TABLE 12 - STIFFENED SEATED ANGLE CONNECTION CAPACITIES FOR OPEN WEB STEEL JOISTS
Stiffened Angle Seat Connection for Joists
Angle Support Size Stiffener Thickness
Max Factored Permanent End Reaction (Factored for LRFD), k
K-series joist (or short bearing LH) LH-series joist
3 1/2 x 3 1/2 x 3/8 3/8" 8.7k INADEQUATE BEARING LENGTH
4 x 4 x 1/2 1/2" 16.7k INADEQUATE BEARING LENGTH
5 x 5 x 5/8 1/2" 24.0k 32.3k
6 x 6 x 3/4 3/4" 25.3k 41.3k
Notes:
1. FY Stiffener = 50ksi2 Assumes 1/4" fillet weld on both vertical legs of angle seat to embed plate3. Assumes 1/4” fillet weld stiffener to angle seat4. Calculations per AISC Construction Manual 15th Ed. 5. Values in table are for connection capacity only, loads may exceed maximum end reactions for listed joist series
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COORDINATION WITH BUILDING FRAMING3D Building Information Models (BIMs) are available for coordination during the detailing process. Please consult a Vulcraft representative for more information on file types and approximate schedules for receiving BIMs.
FORM SYSTEM INSTALLATIONThe following section covers typical handling and erection procedures for the RediCor™ Form System. These instructions will also be included on the detail drawings provided for each RediCor™ project. Always review all notes included on the RediCor™ detail drawings for each specific project as requirements and instructions may vary on a case-by-case basis.
HOISTINGThe installer is responsible for providing rigging necessary for hoisting. Rigging must be attached only to the designated lifting lugs on the modules. Lifting cables and/or slings shall always be arranged such that the angle of the cable is no less than 45 degrees from horizontal.
FIGURE 20: TYPICAL LIFT LUG DETAIL
STORAGEWhen modules are stored on site, support each module above ground surface on wood dunnage. Place dunnage at a minimum of 4 locations either directly beneath outside corner struts or directly beneath lattice column bases.
CONSTRUCTION
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ERECTION PROCEDURES1. Before erecting the base module of each core, accurately establish and mark the location of the core wall lines on the foundation below the core. The base module will include threaded rod connectors at each of its corners which allow the base module to be leveled and provide attachment to the foundation during construction. Establish the plan locations of these connectors using the dimensions from the Vulcraft provided detail drawings. The dimensional tolerance for core wall locations is plus or minus 1/16” in any horizontal direction.
2. Hoist the base module and place it on the foundation, carefully aligning the foundation connectors with the layout marks. Check the top elevation of each corner of the module. Adjust the double nuts at the threaded rod connectors, if needed, to bring the top of the module to the exact elevation as shown on the Vulcraft provided detail drawings. Weld the threaded rods to the embed plates as indicated in the Vulcraft provided detail drawings.
3. Install and weld the lattice column base connections as indicated in the Vulcraft provided detail drawings.
4. Tighten double nuts at threaded rod foundation connectors.
5. Install vertical reinforcement bars as indicated in the Vulcraft provided detail drawings. At the base module, these vertical reinforcement bars must be attached to the foundation before concrete is placed in the base module.
6. Before installing each subsequent module, check all module bearing surfaces and interior cavity for cleanliness. Clean if necessary. Verify that vertical reinforcement bars have been placed in the supporting module. Hoist each module and lower it onto the previous module, using the alignment guides at each corner of the module to bring the module into alignment. Install Install vertical reinforcement steel before erecting the next module.
CONSTRUCTION
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FIGURE 21 - TYPICAL THREADED ROD FOUNDATION CONNECTOR
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7. At each floor level, check horizontal and vertical alignment of module prior to placement of concrete and connection of any floor framing.
8. Before using any RediCor™ stairs for construction access, install permanent panel railing or temporary railing or temporary barriers necessary for compliance with applicable safety regulations. Vulcraft does not supply temporary railings or barriers.
9. Remove temporary braces at openings in core walls only after concrete has been placed within the form wall and has reached 75% of its specified 28-day strength.
CONSTRUCTION
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REBAR AND CONCRETE PLACEMENT
INSTALLATION OF HORIZONTAL REBARVulcraft provides horizontal rebar to meet the design requirements set forth by the specifying professional’s provided loading in the structural drawings and specifications. Horizontal rebar is installed by Vulcraft in the factory. All modules arriving on site will have horizontal rebar pre-installed.
INSTALLATION OF VERTICAL REBARVulcraft provides vertical rebar to meet the requirements set forth by the specifying professional’s provided loading in the structural drawings and specifications. Vertical rebar is supplied in pre-cut segments that must be installed at the top of each Vulcraft form module prior to concrete placement. Each vertical rebar segment is supplied with a small hook on one end for simple installation into guides at the top of each module.
CONSTRUCTION
A vertical rebar segment’s length will exceed the height of its module in order to form a non-contact lap splice with the vertical rebar segment in the module below. It is important to plan concrete lifts to allow for installation of vertical rebar segments above. Vulcraft detail drawings include an elevation guide to aid in this planning process.
INSTALLATION INSTRUCTIONS1. Install vertical reinforcement steel before erecting the next module.
2. When installing vertical rebar, ensure the bottom of the rebar passes through the same rebar pocket as the top of the rebar.
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FIGURE 22 - EXAMPLE CONCRETE PLACEMENT ELEVATION GUIDE
INSPECTION OF REBARRediCor™ modules arrive on site with steel deck skins and horizontal rebar pre-installed. When special inspections of rebar are required by code, an inspector may visit the factory during manufacture of the modules and prior to skin installation, or the inspector may view the rebar from the opening at the top of each module on site.
CONSTRUCTION
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PLACEMENT RATEPlace concrete using recommendations of ACI “Manual of Concrete Practice”, latest edition, sections ACI 304R and 304.2R, as applicable. The RediCor™ Form System is designed for a maximum form pressure of 900psf.
Place concrete in 6-foot maximum lifts, allowing sufficient time between lifts for concrete to solidify to the extent that fluid pressure is relieved from form walls. Alternatively, place concrete in 4-foot maximum lifts at a maximum placement rate calculated according to formulas set forth in ACI 347 to produce a form pressure of no more than 900 pounds per square foot. Vulcraft does not calculate or provide placement rates.
CONCRETE MIX RECOMMENDATIONSConcrete and concrete mix design is provided by Vulcraft. Due to the specialized construction of the form system, the maximum aggregate size will not exceed ¾” to ensure proper concrete cover on rebar.
TEMPORARY CONSTRUCTION LOADSRediCor™ Forms are designed and manufactured to support vertical construction loads of limited magnitude prior to placement and cure of concrete. After a lift of concrete has been placed and has achieved 75% of its specified 28-day strength, all loads on that portion of the wall and below should be considered to be resisted by the reinforced concrete wall alone with no contribution from the form system.
Prior to concrete achieving 75% of its specified 28-day strength, the maximum safe construction loads which can be applied to any beam connection point or shelf angle will be shown on the elevation views of the detailed drawings supplied by Vulcraft.
WARNINGS1. Do not erect core modules on foundations until foundation concrete has achieved 75% of its specified 28-day strength.
2. The maximum height to which core modules may be stacked without concrete having been placed within the form and achieved 75% of its specified 28-day strength is typically 3 module heights high (this height will vary per project, please consult project- specific, detail drawings provided by Vulcraft).
3. Do not place any concrete on floor or roof slabs supported by the core until concrete within the form walls has been placed to at least the top elevation of the slab and has achieved 75% of its 28-day strength.
4. Do not use the RediCor™ Form System as a brace for plumbing or stabilizing the building framework. Steel framing and concrete formwork shall be independently braced for stability.
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5. Do not stack heavy construction materials or equipment unrelated to RediCor™ on floor or roof areas supported by RediCor™ form modules prior to placement of concrete within the form wall to at least the top elevation of the floor or roof and having reached 75% of its specified 28-day strength.
6. Do not modify any aspect of the RediCor™ Form System or Vulcraft supplied stairs without the written direction of Vulcraft. Unauthorized modification will nullify the Vulcraft product warranty.
7. Construct temporary rails and barriers as needed to comply with applicable safety regulations. Employ fall protection systems where rail and barrier systems are not feasible. Vulcraft does not supply temporary rails, barriers, or fall protection devices.
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PRODUCT SPECIFICATION
Specifier Notes: This guide specification is written in Construction Specifications Institute (CSI) 3-Part Format in accordance with the SI Construction Specifications Practice Guide, including Master Format, Section Format, and Page Format.
This section must be carefully reviewed and edited by the Architect or Engineer to meet the requirements of the project and governing building code. Coordinate this section with Division 01, other specification sections, and the drawings. Delete all Specifier Notes after editing this section.
Section numbers and titles are based on Master Format 2014 Update.
SECTION 03 11 13MODULAR STAY-IN-PLACE METAL FORM SYSTEMS
PART 1 GENERAL
1.1 RELATED DOCUMENTS
A. Drawings and general provisions of contract, including General and Supplementary Conditions and Division 01 specification sections apply to the work of this section.
B. The Work under this section shall be subject to all applicable provisions of the state and local building and safety codes and other codes and standards referenced in this specification.
C. In case of conflict among documents, including architectural and structural drawings and specifications, notify the Architect prior to submitting proposal. In case of conflict between the structural drawings and specifications, the structural drawings shall govern. All references shall be latest edition.
1.2 WORK INCLUDED
A. Extent of work is shown on the drawings, including schedules, notes and details which show size and location of formed concrete walls.
B. Furnish RediCor™ modular stay-in-place metal form systems for cast-in-place concrete construction. Modular permanent systems include, but are not limited to, the following:
1. Metal wall forms, factory assembled into modules for shipment to the project site.
2. Designs, shop drawings and assembly instructions as required for proper performance and field assembly of the form systems in accordance with
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PRODUCT SPECIFICATION
performance requirements established by this specification and the project drawings.
3. Concrete reinforcing complete with required supports, spacers and related accessories.
4. Anchors, plates, and inserts required for attachment and/or support of structural and/or architectural precast concrete, structural steel or other materials and furnished under other specifications.
5. Anchors, plates, and inserts required for attachment of the metal form systems to the foundation.
6. Connection materials and fasteners for joining of adjacent form modules during construction.
7. When modular permanent metal form systems include pre-fabricated metal stairs, furnish stairs, landings and railings of style selected by Architect from among manufacturer’s standard styles. To the maximum extent practical, stair and landings shall be factory-installed within the modules prior to shipment. Stair railings shall be shipped loose for field installation.
1.3 RELATED WORK SPECIFIED ELSEWHERE
A. Division 03 – Concrete
B. Division 05 - Structural Steel 1.4 REFERENCE STANDARDS
A. ACI 347R - Guide to Formwork for Concrete
1.5 QUALITY CONTROL
A. Design formwork under direct supervision of a Professional Structural Engineer experienced in design of concrete formwork and licensed in the State in which the Project is located.
1. The manufacturer is responsible for in-house quality control, including workmanship and materials. 2. The manufacturer shall maintain records of in-house inspections and documentation of materials incorporated into the form systems.
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PRODUCT SPECIFICATION
1.6 SUBMITTALS
A. Submit shop drawings and special instructions in accordance with the following:
1. Submit (3) copies of each shop drawing. Reproducible copies of contract documents shall not be used as shop drawings. Shop drawings shall be reviewed by Contractor prior to submission. Drawings shall bear Contractor’s approval stamp accepting responsibility for coordination of dimensions shown in the contract documents, quantities and coordination with other trades. Drawings not bearing contractor’s stamp may be rejected at the discretion of the Architect or Structural Engineer. One copy will be returned with Architect/Engineer comments. Allow 14 calendar days in the Structural Engineers office for review of shop drawings.
B. Shop drawings shall include the following:
1. Overall dimensions of each form module.
2. Dimensional locations of all module splice locations.
3. Dimensional locations and sizes of all openings.
4. Detail drawings of all concrete reinforcement bars and their placement.
5. When stairs are provided, detail drawings of all stairs and railings.
6. Detail drawings of all foundation embeds, and placement drawings for same.
7. Identification marks as required for field assembly.
8. Limitations on the height of concrete lifts.
PART 2 PERFORMANCE REQUIREMENTS
2.1 DIMENSIONS
A. Form modules shall be manufactured to the overall dimensions shown on the drawings. Openings for doors, windows, and other penetrations shall be provided according to the sizes and locations shown on the drawings. The manufacturer shall designate module joint locations to facilitate manufacture, shipping and installation operations.
B. When stairs are provided, stair layout dimensions, including rise, run, and landing sizes, shall conform to the dimensions shown on the project drawings.
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2.2 DESIGN CRITERIA
A. Forms shall be designed to safely withstand a maximum form pressure of 900 psf equivalent fluid pressure caused by the placement of concrete.
B. Individual form modules shall be designed to be self-supporting during loading, shipping and erection. Form Modules shall be designed to be self-supporting when stacked vertically 3 modules high prior to and during placement of concrete. Additionally, forms shall be capable of safely supporting the following minimum construction forces, acting alone or in combination, prior to and during placement of concrete:
1. A wind load of 15 psf applied normal to any exterior face.
2. A uniform load of 100 pounds per linear foot applied vertically downward at the top surface of the module.
3. A uniform load applied vertically downward at the top surface of any shelf angle equal to the weight of the floor deck being supported plus a 20psf construction live load.
4. A point load acting vertically downward at each framing connection point equal to the weight of the framing member and floor deck being supported plus a 20psf construction live load.
5. When stairs are provided, each stair and landing shall be capable of safely supporting a load of 500 lbs.
C. Reinforcing steel shall be proportioned and assembled to satisfy the steel reinforcement ratio for each structural element as required by the structural drawings.
D. Anchors, plates, and inserts required for attachment and/or support of structural framing members shall be designed to support the reactions shown on the structural drawings.
E. When required to satisfy these requirements for temporary strength and stability, temporary bracing, installed at the factory to the maximum extent practical, shall be provided by the manufacturer.
F. When stairs are provided, the load bearing elements of all stairs and railings shall be designed to support loads required by the applicable Building Code.
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2.3 MATERIALS
A. Reinforcing Steel Bars:
1. ASTM A615, Grade 60, except as noted otherwise on drawings. Welding reinforcing bars not permitted except where specifically indicated.
2. All reinforcing required to be welded shall conform to ASTM A-706, Grade 60.
B. Metal form systems:
1. Commercial quality steel sheet, plate and shapes.
PART 3 EXECUTION
3.1 GENERAL
A. Delivery, Storage and Handling
1. Deliver, store, handle and erect form systems in exact accordance with manufacturer’s latest published requirements, specifications, and shop drawings.
B. Contractor coordinate sequencing, schedule, shop drawings, fabrication, delivery, and installation.
3.2 CONCRETE PLACEMENT
A. Place concrete in strict accordance with “Standard Specifications for Structural Concrete,”ACI 301, and manufacturer’s written instructions.
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CODE OF STANDARD PRACTICE
GENERAL
In this document, the seller refers to Vulcraft, the manufacturer and distributer of the RediCor™ Form System. The buyer refers to the party that receives, orders, and pays for the RediCor™ Form System. The relationship between the buyer and the seller is defined by the signed purchase contract. Though only one of the following directly pays the seller, all are involved in the buyer’s side of the equation:
The OwnerThe Specifying Professional (Engineer/Architect)The General Contractor/Construction ManagerThe Steel FabricatorThe Steel ErectorThe Foundation ContractorThe Concrete ContractorManufacturers of roof or floor framing materials
Other trades that may be involved include:
The Mechanical ContractorThe Elevator ContractorThe Electrical ContractorThe Fire Sprinkler Contractor
ESTIMATES
The buyer shall provide a set of plans which show the work required in enough detail to produce an accurate estimate. The following information must be included:
1. Elevations for all core walls, dimensioned for all geometry including rough opening sizes and locations 2. Definition of the tops of foundation walls supporting the core walls 3. Definition of all members framing into the core at floor and roof levels a. Preferred connection types when applicable b. All vertical and horizontal loads for connection design (framing member to core) 4. All loads that must be transferred at the connection between the core walls and foundation walls 5. Stair layouts including rise, run, and plan dimensions 6. Preferred stair type (i.e. metal pan stairs) when applicable 7. Preferred handrail type when applicable 8. All loads and deflection limits required for stair and handrail design 9. All loads required for core design
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The typical scope of estimated work includes the following:
1. Stay in place steel formwork modules for all reinforced concrete cores 2. All rebar required within the reinforced concrete core a. Horizontal rebar will be provided installed within the form modules b. Vertical rebar will be provided loose for field installation 3. Design and material to provide connections between floor and roof framing members and the reinforced concrete core 4. Design and material to provide connection between the RediCor™ formed core and the foundation walls below 5. Metal stairs and handrail, when applicable a. To the maximum extent possible, metal stairs and landings will be provided attached to the core modules b. Handrails are to be field installed 6. Design of the reinforced concrete core based on loads provided by the specifying professional.
The following are not included in the typical scope of estimated work, but may be included at the request of the purchaser at the time of the estimate:
1. Pre-installed furring strips for drywall 2. Pre-installed flat steel embed plates for connection of elevator rails (*note: Vulcraft does not provide design, material, or recommendations for elevator rails, brackets, or inserts.) All loads required to be transferred to the core wall by the flat steel embed plates must be supplied to Vulcraft. All locations and dimensions of flat steel embed plates must be supplied to Vulcraft. 3. Pre-installed elevator hoist beams (*note: Vulcraft does not provide design of elevator hoist beams) . Sizes and locations of hoist beams must be supplied to Vulcraft. End reactions of elevator hoist beams must be supplied to Vulcraft for design of embedded connections.
All construction phase activity, including site storage and erection, is by the buyer or his agents.
SHOP DRAWINGS
Prior to fabrication of the RediCor™ form modules, the seller will submit detailed shop drawings to the buyer for review by the buyer and any other necessary reviewer such as the specifying professional(s) or general contractor. Fabrication does not begin until the drawings are returned with final approval from the buyer.
The building plans and specifications supplied to the seller by the buyer are assumed to be accurate unless written notice is provided to the contrary. When discrepancies between plans and specifications are noted, the strictest interpretation shall be govern.
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Vulcraft detailed shop drawings for approval will include the following:
1. Elevations of the core including module joint lines and rough opening sizes 2. Plan views of the core showing dimensions and locations relative to the specifying professional’s defined building grid 3. Elevations of the core including rebar placement and necessary splices 4. Connections for all roof and floor framing members, including a representation of the construction loads and permanent loads the connections were designed to resist 5. Shelf angles and their connection to the form and core, including a representation of the construction loads and permanent loads they were designed to resist 6. Details of the foundation to core connection 7. Details of the stairs and handrails, when applicable, including locations, dimensions, and members sizes meeting the specifying professional’s design intent
RESPONSIBILITIES OF THE BUYER
The following is a discussion of the division of responsibilities between the numerous parties on the buyer’s side of the buyer/seller relationship.
The Owner: The owner initiates the process and defines requirements for the building including building type, usage, and features. The owner is responsible for hiring the specifying professional and general contractor/construction manager.
Specifying Professional: The specifying professional is the architect/engineer responsible for designing the building to the owner’s requirements as well as to the appropriate codes and regulations. This party prepares plans and specifications with enough detail that other parties can understand the labor and material required for their scope of work (ref. Estimates in the General section above for more information regarding drawing and specification requirements for the RediCor™ Form System.) The specifying professional is responsible for reviewing and approving shop drawings. This approval is for ensuring conformity with the design intent, and does not approve deviations from the original specifications nor ensure dimensions or fit-up. The structural engineer of record (SEOR) provides all loads being transferred into the core for Vulcraft’s delegated design of the core.
General Contractor: The general contractor carries out the building construction process to completion. This party is responsible for clearly dividing work amongst sub-contractors.
Steel Fabricator: The steel fabricator supplies fabrication and erection drawings of steel frame work for the building. In the context of the RediCor™ Form System, some coordination between the steel fabricator and the seller will be required for connection locations and details of steel members framing into the core.
Manufacturers: Other manufacturers, such as those manufacturing steel deck and joists,
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supply fabrication and erection drawings for their products. In the context of the RediCor™ Form System, some coordination between these manufacturers and the seller may be required when a manufacturer’s product frames into the core.
Foundation Contractor: The foundation contractor is responsible for constructing the foundation according to the plans and specifications. In the context of the RediCor™ Form System, this party installs all embeds supplied by Vulcraft which are required for the connection of the foundation to the core above.
Steel Erector: In the context of the RediCor™ Form System, this party receives all shipments of form modules on site and checks for shipping damage and quantities. This party also erects all form modules, installs vertical rebar, installs the foundation to core attachment, and makes framing attachments. The erector is also responsible for temporarily bracing the building and its elements during erection. The RediCor™ Form System is not to be used as temporary bracing for lateral loads during erection and construction.
Concrete Contractor: In the context of the RediCor™ Form System, the concrete contractor is responsible for supplying concrete to meet the specifications set forth by Vulcraft and for the placement of concrete within the form system. This party must ensure the maximum form pressures as indicated in the Vulcraft detail drawings are not exceeded during concrete placement. This party also supplies and installs a temporary bulkhead around the base of the form system where the approximately 6” gap exists for facilitation of the foundation to core connection.
Other Trades: Other trades involved in building construction include mechanical contractors, finish contractors, and any other trade installing materials required to complete the building. In the context of the RediCor™ Form System, other trades must ensure they do not damage the RediCor™ Form System by:
1. Applying construction loads in excess of the indicated maximum construction loads at each shelf angle or framing member prior to concrete being placed in the core and reaching an appropriate level of strength 2. Cutting or notching structural elements of the form system prior to concrete being placed in the core and reaching an appropriate level of strength 3. Using the form system to support, plumb, or otherwise brace any building or construction elements other than the indicated floor and roof framing members
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