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SECTION XXXXX

DBI/SALA’S EVOLUTION HORIZONTAL LIFELINE FALL PROTECTION SYSTEM

PART 1 GENERAL

1.1 SYSTEM DESCRIPTION

A. Type of system required: Horizontal Lifeline (HLL)

B. System location: Roof/ Wall/ Tower/ Fixed Ladder/ Misc. Structure, etc.…

C. Maximum number of workers on system at one time: ##

D. Systems environmental exposure: What are the service conditions (indoors, outdoors, corrosive environment)? What materials will be required (steel, hot dip galvanizing, stainless steel, marine grade stainless etc…)?

E. Workers task while on the system: Workers will walk along edge. Occasionally, workers are required to look over the edge. While walking, workers need to carry heavy objects.

F. Type of fall protection required: Fall Restraint or Fall Arrest

G. Range of movement while on the system: Uninterrupted movement throughout the entire length of the system

H. Additional components: All attaching devices necessary for # workers.

I. Insurances required: Commercial Liability and Workers’ Comp.

1.2 RELATED SECTIONS

A. Section 03300 - Cast-In-Place Concrete

B. Section 03400 - Pre-Cast Concrete

C. Section 05100 – Structural Metal Framing

D. Section 05400 – Cold Formed Metal Framing

E. Section 05310 - Metal Deck

F. Section 06100 – Rough Carpentry

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G. Section 07510 - Built-Up Roofing

H. Section 07700 - Roof Specialties and Accessories

I. Section 11010 - Maintenance Equipment

1.3 REFERENCES

A. Occupational Safety & Health Administration (OSHA)

1. 29 CFR 1910.28 (b) (1) & 29 CFR 1926.501(b) (1) - Occupational Health and Safety Standards General Industry & Construction: Duty to have fall protection

2. 29 CFR 1910.140(c) (11) (i-ii) & 29 CFR 1926.502(d) (8) - Safety and Health Regulations for General Industry & Construction: Horizontal Lifeline Design Requirements.

3. 29 CFR 1910.140(c) (13) (i-ii) & 29 CFR 1926.502(d) (15) (i-ii) - Safety and Health Regulations for General Industry & Construction: Anchorage Design Requirements.

4. 29 CFR 1910.66 (e) (1) (i) - General Industry: Powered Platform Installations -Affected parts of buildings.

B. American National Standards Institute (ANSI)

1. Z359.1 [2016] – The Fall Protection Code

2. Z359.3 [2017] – Safety Requirements for Positioning and Travel Restraint Systems.

3. Z359.6 [2016] – Specifications and Design Requirements for Active Fall Protection Systems.

4. Z359.11 [2014] – Safety Requirements for Full Body Harnesses.

5. Z359.12 [2009] – Connecting Components for Personal Fall Arrest Systems.

6. Z359.13 [2013] – Personal Energy Absorbers and Energy Absorbing Lanyards.

7. Z359.14 [2014] – Safety Requirements for Self-Retracting Devices for Personal Fall Arrest and Rescue Systems.

8. Z359.15 [2014] – Safety Requirements for Single Anchor Lifelines and Fall Arrester for Personal Fall Arrest Systems.

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9. Z359.18 [2017] – Safety Requirements for Anchorage Connectors for Active Fall Protection Systems.

C. Materials, Bolting, Finishing: American Society of Testing Materials (ASTM)

1. A36 - Standard Specification for Carbon Structural Steel.

2. A500 - Standard Specification for Cold-Formed Welded and Seamless Carbon Steel Structural Tubing in Rounds and Shapes

3. A53 - Standard Specification for Pipe, Steel, Black and Hot-Dipped, Zinc-Coated, Welded and Seamless

4. F1554 - Standard Specification for Anchor Bolts, Steel, 36, 55, and 105 KSI Yield Strength.

5. A193 - Standard Specification for Alloy-Steel and Stainless Steel Bolting for High Temperature or High Pressure Service and Other Special Purpose Applications

6. A123 - Standard Specification for Zinc (Hot-Dip Galvanized) Coatings on Iron and Steel Products

7. A666 - Standard Specification for Austenitic Stainless Steel Sheet, Strip, Plate, and Flat Bar.

8. A992 - Standard Specification for Structural Steel Shapes.

9. F3125 - Standard Specification for High Strength Structural Bolts, Steel and Alloy, Heat Treated, 120ksi and 150ksi Minimum Tensile Strength, Inch and Metric Dimensions.

D. American Welding Society (AWS) D1.1/D1 - Structural Welding Code – Steel

E. Design Standards

1. International Building Code (IBC) [20XX]

2. American Society of Civil Engineers (ASCE/SEI) 7-10 [20XX] – Minimum Design Loads for Buildings and Other Structures

3. American Institute of Steel Construction (AISC) 360-XX [XXth ed.] – Steel Construction Manual. In accordance with local building code and adopted standards.

4. American Concrete Institute (ACI) 318-XX Building Code Requirements for Structural Concrete.

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5. National Design Specification (ANSI/NDS) [20XX] – Wood Construction Manual

F. Definitions

1. Anchorage – per ANSI Z359.0 – A secure connecting point or a terminating component of a fall protection system capable of supporting impact forces applied by a fall protection system.

2. Anchorage Connector – per ANSI Z359.0 – A component or subsystem that functions as an interface between the anchorage and a fall protection, work positioning, rope access or rescue system for the purpose of coupling the system to the anchorage.

3. Clearance – per ANSI Z359.0 – The distance below an authorized person that must remain clear of obstructions in order to ensure that the authorized person does not make contact with any objects that would cause injury in the event of a fall.

4. Continuous Fall Protection – per ANSI Z359.0 – One or more fall protection systems that provide fall protection without interruption.

5. Fall Arrest – per ANSI Z359.0 – The action or event of stopping a free fall or the instant where the downward free fall has been stopped.

6. Fall Hazard – per ANSI Z359.0 – Any location where a person is exposed to a potential free fall.

7. Fall Restraint/Travel Restraint – per ANSI Z359.0 – A combination of anchorage, anchorage connector, lanyard (or other means of connection) and body support (full body harness) that limits travel in such a manner that the user is not exposed to a fall hazard.

8. Qualified Person – per ANSI Z359.0 – A person with a recognized degree or professional certificate and with extensive knowledge, training and experience in the fall protection and rescue field who is capable of designing, analyzing, evaluating and specifying fall protection and rescue systems to the extent required by the Z359 standards.

1.4 PERFORMANCE

A. System shall comply with 1.1 System Description

B. Performance Requirements

1. System Performance

a. The Fall Protection Horizontal Lifeline System shall be designed to allow users to walk the entire length of the system without having

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to disconnect from the system to pass through intermediate supports. The system shall be designed to support required number of users in case of a fall and to prevent the users from free falling more than 6 feet. All components shall be designed by the fall protection system supplier and shall meet the applicable fall protection ANSI standards and applicable OSHA regulations.

b. The Fall Protection Horizontal Lifeline System shall be designed to control swing fall at corners and other locations in accordance with Z359.6.

2. Structural Performance:

a. Structure supporting the Horizontal Lifeline system must be capable of withstanding design loads based on the maximum specified number of users as required by governing regulations and codes. Where component design loads are specified herein, they represent design minimum requirements.

b. All fall protection components and systems shall be designed with a minimum 2:1 safety factor per section reference 1.3.A.2. In addition, structure supporting fall protection components and systems shall be designed for combined loading conditions in accordance with section reference 1.3.B.3.

1.5 DESIGN

A. Design Requirements

1. Fall protection horizontal lifelines shall comply with current applicable OSHA, ANSI, and state regulations and standards.

2. The fall protection system and any supporting structure shall be designed by:

Capital Safety Phone: 1-800-328-6146 3833 Sala Way Website: www.capitalsafety.com Red Wing, MN 55066 E-mail: info@capitalsafety.com.

Gravitec Systems Inc. Phone: 1-800-755-8455 21291 Urdahl Road NW, Website: www.gravitec.com Poulsbo, WA 98370-7124 E-mail: solutions@gravitec.com.

3. General Requirements:

a. Horizontal lifelines shall be designed and installed, under the supervision of a Qualified Person, as part of a complete personal Fall Protection system.

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b. The horizontal lifeline must be level (less than a 5% grade).

c. Engineers shall, at minimum determine the performance of the system when a fall occurs on the shortest span (largest forces) and the longest span (largest total fall distance) in the system.

d. Evolution tip over posts and/or energy absorbers shall not be used to limit the maximum arrest force of the worker. The Evolution tip over posts and/or energy absorbers shall be used only to control or reduce the maximum arrest load on the structure.

e. Anchorages for horizontal lifelines systems shall be verified and designed, prior to use, by a Qualified Person with experience and trained in designing and using horizontal lifelines systems.

f. HLL(s) shall satisfy the seismic conditions for nonstructural components as described by ASCE/SEI 7 and the most current edition of the IBC. No exceptions can be taken if the system is required to function for life-safety purposes after an earthquake.

g. The fall arrest system shall consist of a stainless steel safety cable attached to the structure. The cable shall be continuous or shall have swaged splices, which allow the user to pass without disconnecting from the system.

h. Brackets and supports shall be attached to the structure with appropriate anchors of proper size to adequately support the intended loaded.

i. The HLL(s) shall comply with DBI/SALAs design requirements.

4. Restraint HLL(s) shall be designed per ANSI Z359.2 & ANSI Z359.6:

a. The HLL(s) shall prevent workers from reaching and falling into any open hole or off the edge of a working surface.

b. The horizontal lifeline shall comply with the requirements for fall arrest horizontal lifelines as indicated in this document.

c. Where a worker is using a full body harness the force on the worker’s body shall not exceed 400 lbs.

d. Evolution tip over posts and/or energy absorbers may be used in travel restraint systems; provided that the engineer has determined that the restraint forces will not cause the tip over posts and/or energy absorbers to deploy and ensures that the deflection of the wire rope in combination with other deformations of the restraint system will not permit the worker(s) to reach the fall hazard.

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e. The use of fall restraint systems shall be limited to surfaces at or less than a slope of 4:12 from the horizontal. This is so a fall will not result in dynamic loading on the fall restraint system or where the authorized person could end up being suspended vertically from the system.

5. Fall Arrest HLL(s) shall be designed per ANSI Z359.2 & ANSI Z359.6:

a. The selection, design, and installation of fall arrest horizontal lifelines shall be performed under the supervision of a Qualified Person.

b. Fall arrest horizontal lifelines and all components shall have the strength capable of sustaining static loads applied to the wire rope of at least two times the maximum arresting force.

c. When more than one user is attached to a horizontal lifeline, the load on the lifeline can be determined using either lumped mass or sequential fall as described in ANSI Z359.6 [4.6.7]

d. The swing fall shall comply with ANSI Z359.6 [4.6.9]

e. The clearance safety margin shall comply with ANSI Z359.6 [7.6.2]

B. Sub-System Requirements

1. Harnesses used with the system shall comply with ANSI Z359.11.

2. Vertical Lifelines (VLLs) used with the system shall comply with ANSI Z359.15.

3. Connecting Components (carabiners and snap hooks) used with the system shall comply with ANSI Z359.12.

4. Energy Absorbing Lanyards (EALs) used with the system shall comply with ANSI Z359.13.

5. Self-Retracting Lifelines (SRLs) used with the system shall comply with ANSI Z359.14.

C. Horizontal lifelines shall be used exclusively for their designed use and shall be marked to prevent other uses.

D. The design shall take into consideration the potential uses of and loads on the horizontal lifeline, in order to facilitate the prompt rescue of workers who may fall while attached to the system.

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1.6 SUBMITTALS

A. Submit under provisions of Section ##### – Submittal Procedures

B. Product Data: DBI/SALAs’ data sheet on each product to be used, including:

1. Preparation instructions and recommendations.

2. Storage and handling requirements and recommendations

3. Installation methods

C. Drawings and Calculations:

1. Drawings:

a. Show the layout of the system including where the system is located and the complete assembly of all components. And how the system is to be accessed.

b. Include a specification of the number, location, and qualifications of workers using the system.

c. Clearly specify the type of system, (restraint or arrest), maximum and average arrest force of PFAS equipment, type of equipment to be used (lanyard, self-retracting device, etc.), equipment dimensions, materials, fabrication details, hardware, and installation instructions. And additional information as indicated in Z359.6 Section 3.2.

d. Clearly specify the required clearance for each system and location.

2. Calculations:

a. Calculations shall be prepared by a Qualified Person under the supervision of a registered Professional Engineer who is also a Qualified Person.

b. Include a statement defining the type of system and indicating that the design is in accordance with the requirements of ANSI Z359.6.

3. The Professional Engineer who oversaw the design of the system shall affix their professional seal to each drawing and calculation package issued in accordance with state law.

D. Operation and Maintenance Data shall be prepared per Z359.2 & ANSI Z359.6:

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1. Include complete list of equipment replacement parts; identify each entry with the equipment description and part numbers.

2. Include technical information for servicing equipment.

3. Include legible “as-constructed” drawings of the installed system.

4. Include installation date and system owner’s name and address.

5. Include detailed operating procedures:

a. Written by a Qualified or Competent Person.

b. Identifying the horizontal lifelines location

c. Stating any safety precautions that shall be followed during access and egress.

d. Describing the limitation on use of system: maximum load, designated equipment, required clearance and maximum number of persons permitted to be attached to the system at one time.

e. Instructions for inspection, maintenance, and retirement of the system and all of its components, including how often inspection and maintenance are to be performed and a description of the qualifications required for persons performing these tasks.

f. Procedure for inspection:

I. Required or recommended inspection intervals.

II. Detailed instruction for inspecting each component of the system.

III. Description of acceptance or rejection criteria, including retirement criteria, of each component of the system.

IV. Fall protection procedures shall include a requirement that any incidents, including accidents or near misses, be investigated to determine if procedures can be improved.

6. Provide or direct the owner of the system or the employer of the workers using the system to develop and implement a rescue plan before the system is used.

1.7 QUALITY ASSURANCE

A. Single Source: Obtain all materials and equipment required under this section from a single supplier.

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B. Designer/Installer Qualifications: Engage a single firm to assume undivided responsibility for the design and fabrication of all fall protection system components. Firm shall have a minimum of 5 years documented experience in the fabrication of such components similar to that required for this project. Additionally, the firm shall have a minimum of 5 years documented experience in the installation of such components and who offers a regular inspection and maintenance service on such systems.

C. Design Engineer: Employ a firm with a minimum of 10 years experience designing fall protection systems with a minimum of 5 systems installed in the previous 12 months. Who employs a registered Professional Engineer (PE), with evidence of being the principal PE on at least 3 fall arrest systems which have been in use for no less than 1 year prior to bid closing date.

D. Professional Engineer who is a Fall Protection Qualified Person: Shall oversee the fall protection systems’ design, such that all component items meet the “Structural Performance” requirements, including sizing and spacing of all attachments to the building structure and verify the design is compliant with all applicable OSHA regulations and ANSI standards. Additionally, they must prepare, stamp and sign all required calculations.

E. Welding to be executed by certified welders in accordance with AWS requirements.

1.8 DELIVERY, STORAGE & HANDLING

A. Material delivery shall be coordinated with all effected entities.

B. Storage and Protection:

1. Store originally packaged materials in a cool, dry, and protected location.

2. Materials shall be in new condition and show no signs of damage.

1.9 SEQUENCING

A. Ensure that products of this section are supplied to affected trades in time to prevent interruption of construction progress.

1.10 WARRANTY

A. Manufacturer's standard warranty for materials and workmanship.

B. Installer's standard one (1) year warranty for materials and workmanship.

PART 2 PRODUCTS

2.1 MANUFACTURERS

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A. Manufacturers shall comply with the Quality Assurance section of this documentation.

B. All supporting structure which connects the horizontal lifeline to the super structure shall be designed by:

Gravitec Systems Inc. Phone: 1-800-755-8455 21291 Urdahl Road NW, Website: www.gravitec.com Poulsbo, WA 98370-7124 E-mail: solutions@gravitec.com.

2.2 PRODUCTS

A. Capital Safety 3833 Sala Way Red Wing, MN 55066

2.3 MATERIALS

A. Product

1. The system shall be a complete and turnkey complying with the performance and design criteria of this document.

2. The HLL(s) shall be the product of DBI/SALAs PLC.

3. Components: All system connectors, cables and bolts shall be stainless steel Type 304. All plastic components shall be Anti-UV polymide. Fabricated supports required for additional support may be carbon steel with a corrosion resistant coating. However a faying surface shall be used to prevent galvanic reactions.

4. Post Base Plate Connectors: Provide complete with required components for weatherproof mounting to the following surfaces:

a. Standing Seam Roof Type.

b. Composite Ribbed Roofing Type.

c. Metal Roofing Type.

d. Insulated Roof Deck Type.

e. Concrete Deck Type.

f. Timber Deck Type.

g. Non-Penetrating.

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5. DBI/SALAs Fall Protection System shall be attached to the supporting structure with appropriate fasteners. The fasteners shall be designed to support a load on the fall protection system of 2 times the maximum design load without failure.

6. Provide all designed sub-system items per Section 1.5 (B) of this document.

B. Supporting Structure

1. Structural Components shall comply with the applicable standards:

a. Structural Steel: ASTM A992

b. Structural Tubing: ASTM A500 Grade B

c. Structural Bars, Plates, Shapes, and Sheet Piling: ASTM A36.

d. Piping: ASTM A53. Grade B

2. Fasteners shall comply with the applicable standards:

a. Structural Bolts: ASTM A3125

b. Alloy-Steel and Stainless Steel Bolting: ASTM A193 B7.

3. Flashing and Sealing Material shall comply with the applicable standards:

4. Material substitutions shall be better than or equal to the requirements found in this section.

5 Fabrication

a. Fabricate work true to dimension, square, plumb, level, and free from distortion or defects detrimental to performance.

b. Coordinate the system with supporting structure.

c. Welding:

I. AWS D 1.1 as applicable.

II. If Butt welds are used, then surplus welding material shall be ground off to ensure exposed surfaces are smooth. Fillet welds shall not be ground.

III. Slag shall be removed from the materials surface.

6 Finishes

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a. Hot Dipped Galvanizing: Comply with ASTM A123.

b. Powder Coat: Safety Yellow

2.4 HORIZONTAL LIFELINE DESIGN

A. Horizontal lifeline design shall comply with the Design Requirement section of this document.

B. Steel design shall comply with AISC 360 edition as required by jurisdiction.

C. Wood design shall comply with ANSI/NDS [20XX].

D. Concrete design shall comply with ACI 318-XX.

E. Fall protection systems attached onto an existing or new structure shall comply with IBC and ASCE/SEI as required by jurisdiction.

PART 3 EXECUTION

3.1 INSTALLATION

A. Installation shall be performed by:

Gravitec Systems Inc. Phone: 1-800-755-8455 21291 Urdahl Road NW, Website: www.gravitec.com Poulsbo, WA 98370-7124 E-mail: solutions@gravitec.com.

B. Install in accordance with approved shop drawings and manufacturer’s instructions.

C. DBI/SALAs Fall Protection System shall be installed under the direction of manufacturer’s authorized trained personnel and under the supervision of a Qualified Person

D. Install anchorages and fasteners in accordance with their manufacturer’s recommendations to obtain the allowable working loads published in the product literature and in accordance with this specification.

E. Do not load or stress DBI/SALAs Fall Protection System until all materials and fasteners are properly installed and ready for service.

F. Where bolting is used for fastening, no fewer than three threads are to be exposed and the nut shall be positively locked using a thread-locking fluid or the double nutting technique.

G. Dissimilar materials with greater than 0.15V shall be separated by a faying surface.

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3.2 FIELD QUALITY CONTROL

A. After the Fall Protection System is installed and properly tensioned, the approved Qualified or Competent Person shall inspect and operate the system and shall make all final adjustments for proper operation.

3.3 ADJUSTMENTS AND FINAL INSPECTION

A. Verify that all manufactured units have been installed in accordance with specifications and details, and will function as intended. Adjust any items where necessary to ensure proper operation.

B. Provide a complete drawing set with any revisions to the design or layout of the fall protection systems during installation.

3.4 OPERATOR TRAINING

A. Provide a minimum of 2 hours of operator orientation after system has been installed. Orientation shall be for the users of the system conducted at the installation site. Minimum requirements for orientation; system type, clearance requirements, maximum number of users, pre-use inspection, yearly inspection requirement, system use and use of personal equipment specified to be used with the system.

3.5 MAINTENANCE, INSPECTION AND TESTING

A. Provide xx copies of the manufacturer’s maintenance, inspection and testing instructions.

B. Provide documentation that is consistent with applicable OSHA and ANSI standards.

C. Provide system placards at access points providing system information including, but not limited to; maximum number of users, system type (restraint or arrest), clearance requirement, manufacturer, installer, date of installation, inspection list, and any other specific limitations of the system.

END OF SECTION

You can’t stopevolution

1 2

To evolve is to innovate,

Always faster, higher,

farther.

In a world that is constantly changing,

addressing safety challenges today

and anticipating those of tomorrow

is the vocation of the new evolution

lifeline by Sala.

Whatever the working configurations

or the ambient environment,

evolution ensures the safety of the teams

in action without ever reducing their mobility

and complying totally with the aesthetics of

the buildings in which it is integrated

because nothing stops evolution

and because evolution is not only a theory

but it is a part of everyday life .

Evolution : new generation horizontal lifeline

International safety standards

The heart of the profession may concern manpower

safety but Sala has also opted for the development

of the design quality of its permanent systems.

This approach, in addition to guaranteeing

optimum safety, makes it possible to have the

systems disappear entirely into the environment.

This is particularly the case with the new evolution

lifeline, capable of entering architectural designs

that are particularly daring and innovating without

ever putting the safety of the men connected to

the lifeline in second place. When anchored to the

building, the evolution lifeline offers great freedom

of movement to personnel requiring to work at a

height to accomplish their jobs. Sala has designed

evolution in an innovative frame of mind, it is ideal

for every structure, favours movements along

the line, protect men efficiently from falls from a

height and is discreet, blending into the building

without ever compromising its aesthetics.

In addition to its feeling for “sustainable architec-

ture”, Sala confirms its major requirement come

from design to manufacturing, all the components

of the evolution lifeline are manufactured under

the quality control system ISO 9001 and undergo

stringent inspection.

In addition, the line has been designed into

compliance with

(EN795 classe C – AISI Z359.1 - CSA Z259.16 - AS/

NZ S1891.4 part 2 & 4).

all the way down the lineManpower safety

evolution on the move

Contents P 3•4 ıı Permanent evolution: the concept

P 5•6 ıı evolution in detail: shuttles and intermediate brackets

P 7•8 ıı evolution in detail: absorbers and posts

P 9•10 ıı evolution in detail: curves and anchors

As specialists in fixed systems, Sala specialises uniquely in the domain of fall arrest, innovating

constantly, as it has done for more than 25 years in this area. Sala supplies complete and tailor-made

solutions to ensure safe access and work at a height.

3 4

At the summit of evolution

permanent evolution®

Easy and precise installation on any type

of structure: walls, floors, ceilings, outdoors and

indoors. An extended range of absorbing or tip over

posts adjusted to structures offering less resist-

ance such as trapezoidal roof panels or standing

seam roofs. In such cases, the posts reduce the

forces and contribute to preserving the building.

An upstream simulation system: As a warrant

of the perfection obtained, design software has

been developed specifically for evolution. By

simulating the necessary clearances and possible

heights of fall, this design software validates the

compatibility of the structures with the lifelines

no matter how complex. It verifies that the overall

system is dimensionned according to the number

of users and that the forces at the ends can be

supported by the structure.

Sala believe, it is up to the lifeline to adjust to the

building and not the other way around.

Total adaptability. For evolution Sala has

developed a varied and extended range of curves,

intermediate and end brackets, enabling the

lifeline to follow very accurately the lines of the

buildings while addressing safety demands to the

fullest. A high capacity absorber makes it possible

to use evolution on large single spans; this is an

ideal solution in hangars or on unloading docks.

The evolution lifeline can also be used simultane-

ously with a retractable fall arreste devices.

For a budget price lifeline. Its technical prop-

erties make it possible to lengthen the distance

between the intermediate brackets (centre

distances) thus cutting installation costs without

making any sacrifice to safety. Direct installa-

tion of a lifeline on a metal pannel roof without

drilling into or making any other arrangement to

the metal structure.

A high performance level thanks to a unique

energy absorption method LEAP and the range of

absorbers that can be adjusted to every lifeline

configuration.

Professionalism for every situation. evolution

is installed on site by Sala trained and approved

installers offering overall service from initial

layout study, to periodic verification of the line,

and even including user training.

Backwardly compatibility

with the former systems

by Protecta, Sala, ideal

to ensure the development

of the existing systems.

Exclusively

comprising

materials resisting

corrosion for

outstanding longevity.

A resolutely

innovative design

with perfect integration into

the environment.

Particularly compact

components.

With evolution, as fall arrest system expert,Sala is inaugurating a new generation of fixed horizontal lifelines and is breaking away from the market standards.

Easily installed, evolution is a particularly

flexible system for companies seeking the

protection of their workplaces without

any damage to the buildings or the

structures into which the lifeline has to

be incorporated.

For work on roofs or overhead cranes, operations

in aircraft hangars, bridge maintenance or loading

docks. All activities calling

for many professionals to work at a height.

To maintain the greatest possible manoeuvring

freedom, it is essential for them to have access

to a lifeline attached to the structure.

This enables them to remain connected constantly

so that they can carry out their work without ever

needing to disconnect.

LEAP

Linear Energy Absorption P

rodu

ct

Sala has focused particularly on absorption in developing for evolution the LEAP

system. Designed to offer a constant level of energy dissipation, LEAP enables the

absorber to reduce the forces linearly and smoothly. The calibration can be adjusted

differently (to order), as per the specific configuration and the use of the lifeline so as

to absorb the amount of energy required to preserve the safety of men and structure

alike. In addition, and this is an innovation, this absorber is capable of tolerating seve-

ral successive falls.

absorption systemNew generation

Fluid circulation

Smooth movements

on a straight line

or on curves.

Anchorage ring in

corporated into shuttle:

intervention on both

sides of lifeline

without disconnection.

5 6

evolution in detail evolution in detail

I n t e r m e d i a t e b r a c k e t s

As the central part of the EVOLUTION lifeline,

the shuttle accompanies the user along the

lifeline, smoothly passing the intermediate brackets.

With its unique spherical shape, the specific design

of the openings, and the incorporation of two pairs

of rollers it has exceptional ability to slide along the

line to the point that the passage of intermediate

brackets and curves is imperceptible (even when

used with a retractable fall arrester device).

& Forming an intermediate support, the

intermediate bracket positions the lifeline

cable. It can be installed in many different

configurations (on the ground, at various heights on

the wall, etc.) and at regular intervals, to ensure the

optimum distribution of forces along the lifeline. It

is shaped specifically so as to allow the automatic

passage of the shuttle without the user ever having

to disconnect from the lifeline. It also makes it easier

to incorporate the lifeline into

the building thanks to a new original element: a

protection cover guaranteeing that the anchorage

points are tamper-proof while improving the overall

aesthetics of the system.

In the eventuality of a fall occurring, the EVOLUTION

intermediate bracket deform under the force and

acts as an energy dissipater and a fall indicator.

This helps reduce the fall impact force and the risks

of incorrect use. The chosen materials (stainless

steel, anti-UV polymer) guarantee the longlife and

durability of the-- shuttle and the intermediate

bracket.

Optimum sliding along the cable, automatic passage of intermediate brakets

and curves.

Capability of working on both sides of the lifeline without disconnecting thanks

to rotation through 360° of the anchorage ring (large enough to allow the con-

nection of almost any type of connector).

Possibility of connection/disconnection of the shuttle at point of the lifeline.

Compact shape (light and strong) and good ergonomics (easy manipulation).

Permanent connection of the link element (lanyard, fall arrest system) to

prevent loss or falling of the shuttle during manipulation.

Possible to use with retractable fall arresters (see list of compatible devices).

Automatic locking on closure.

Double safety opening activated by two distinct actions on the shuttle.

Tested individually (manufactured under ISO 9001 quality control).

Installation by single attachment facilitating lifeline assembly (reduction

of installation time)

Monobloc intermediate bracket guaranteeing greater strength in case of fall.

Automatic shuttle passage on both sides of the lifeline without any need

to disconnect.

Integration of a polymer cable guide to reduce friction to the minimum

(shuttle passage, installation and tensioning of lifeline made much

easier).

NOTE

intermediate bracket for

the Sala post or

overhead installation

are also available

NOTE:

the evolution shuttle

is also compatible with

the Ariana and Sayfglida

systems (8 mm and 12 mm)

for better integration in a

multi-system environment.

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I n t e r m e d i a t e b r a c k e t - M A I N C H A R A C T E R I S T I C S

Shuttle locked – top

vi e

w

The automatic locking system of the shuttle

eliminates any possibility of incorrect manipulation

during connection to the cable. Its spherical shape

means that it is easy to grip and can be opened one-

handed (double safety lock) while also providing it

with excellent resistance to shock.

Shuttle - base view

S h u t t l e

E v o l u t i o n s h u t t l e - M A I N P R I N C I P L E S

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P o s t s

Evolution offers solutions that are ideally adapted

to the installation of lifelines on all kinds of

industrial roofs (trapeziodal pannels, standing

seam, membrane etc.) thanks to a combination of

post and bases that are easily installed on every

type of roof without affecting the integrity of their

structure in any way.

Integrating LEAP (Linear Energy Absorption

Product) guarantees constant absorption of forces

through a predefined range. The main objective is

to reduce the forces at the anchorage points so as

to protect the structure.

Because of their high energy dissipating capability,

it is advisable to install LEAP system absorbing

posts in the lifeline at the ends and on the curves.

However, use at intermediate points is also possible

when the installation calls for a major reduction

of the forces. Simulation using the Evolution cal-

culation software is indispensable for controlling

strength levels and clearances.

The evolution post consists of two parts : a post

(with LEAP energy absorption or of the tilting

type) and a base attached to most modern roofs.

As necessary, the post can be equipped with an

anchorage point, an intermediate bracket or a

curve.

Posts are installed directly to the metal pannel

roofs quickly, easily and without any drilling into

the roof (thus avoiding any problems of water-

proofing and thermal bridging). It does not require

any connection to the building structure.

Integrated LEAP absorber : guarantees the smoothing out of forces to

a predetemined value.

Triggering and absorption level adjustable (in the factory) for specific applications.

High absorption capacity of more than +60% compared to traditional absorbers.

Cable tension display window.

Wide cable tension adjustment range.

Monobloc, protection housing and force indicator.

Choice of materials to ensure longlife and durability (stainless steel, anti-UV polymer).

Supports several falls without any loss of performance.

Through swaging: guarantees complete swaging for optimum safety.

Integrate the LEAP system guaranteeing smoothing out of forces at a pre-

selected value .

Compatible with most industrial roofs (trapeziodal pannels, standing

seam, membrane).

Triggering level adjustable (in the factory) for specific applications.

Easy installation without any anchorage to the frame and thus preserving

waterproofing.

Reduction of forces in case of fall preserving the integrity of the roof.

Conforms to international standards: EN795 class A – AISI Z359.1 - CSA

Z259.16 - AS/NZ S1891.4 part 2 & 4

M A I N C H A R A C T E R I S T I C SPosts -

Evolution incorporates an energy absorption

system of a resolutely new design. It is equipped with

the LEAP (Linear Energy Absorption Product) system

allowing the precise and linear adjustment of the

absorber triggering value and absorption threshold.

Protecting the structure, taking up the forces at the

anchorage points and guaranteeing the safety of the

workers are the goals for the development of this new

type of energy absorber. In case of a fall, the LEAP

system guarantees constant absorption of forces in a

predefined range. The maximum value of the forces

permissible along the lifeline is calculated by means

of software dedicated to evolution. Depending on

the constraints represented by the buildings, the

activation value and the absorption threshold can be

optimised during the production proccess.

The considerable energy dissipating capacity of

the evolution high capacity absorber means that it

is capable of handling several falls simultaneously

while maintaining the forces on the building below a

threshold of 10 kN (2250 lb/ft).

Its compact design also includes a window

displaying the tension on the cable as well as an end

clevis compatible with all the evolution anchorage

points. Swaged definitively to the cable the absorber

is installed at the beginning or end of the line, or if

necessary at both ends, depending on the results

obtained with the evolution calculation software.

M A I N C H A R A C T E R I S T I C SAbsorber -

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ap

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Standard LEAP absorber

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L E A P sy s t e m adjusting range

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9 10

Installation by single attachment facilitating line assembly (reducing the

installation time).

Monobloc intermediate curve guaranteeing greater strength in case of fall.

Automatic passage of shuttle either side of lifeline without any need

to disconnect.

Incorporation of polyamide guide-cable reducing friction to the utmost

(shuttle passage, installation and tensioning of line made much easier)

- M A I N C H A R A C T E R I S T I C S

End tensioner

Definitive swaging guaranteeing faultless safety at the link to the cable.

Easy and fast installation, compatible with all Sala end parts.

Possibility of adjusting the pretensioning of the lifeline (tensioner).

No loss of strength at the connection to the cable.

Choice of materials to ensure long life and durability (stainless steel).

- M A I N C H A R A C T E R I S T I C S

C u r v e s

Anchorages

To fulfil to the utmost the installation and safety

needs of each site, evolution comes with a range

of curve parts enabling every possible curve

to be formed to follow as closely as possible the

movements of the users. There are curve solutions for

every type of installation (wall, post, or overhead).

With its patented flexible cable guide, it is now par-

ticularly easy to use the same curve part to form a

curve ranging from 15° to 45° for a short curve or

from 45° to 90° for a long curve. The anti-rotation

system (also patented) makes it possible to keep

the curve totally horizontal in line with the cable to

guarantee optimum passage of the shuttle.

The specific shape of the evolution short curve is

based on the same concepts as the intermediate

brackets, allowing the shuttle to pass automatically

around the curves without the user ever needing to

disconnect from the lifeline.

To handle the stresses that a possible fall would

generate, evolution incorporates a reinforcing part

to guarantee better resistance to falls. The flexible

cable guide ensures that the cable runs smoothly

around the curves in order to balance out the forces

over the entire lifeline and thus reduce the stresses

at the curves.

| | M A I N C H A R A C T E R I S T I C S

High strength thanks to the ideal distribution of forces at each

attaching point.

The multi-directional articulation gives the end anchorage the same

strength whatever the axis of the cable.

The triple-attachment anchorage is versatile and can be used on the

wall or on the floor or overhead.

The specific shape and mobility of the anchorage allow the automatic

alignment of the lifeline cable.

Modern design incorporated easily into any type of building.

Compatible with all the Sala end brackets and absorbers.

Swag ing

To ensure the optimum anchorage of the

evolution lifeline, Sala has developed an articula-

ted anchorage with three attaching points, aligning

accurately with the cable whatever the direction or

angle, to allow consistent distribution of forces at

each attaching point.

The end anchorages are required to take up the

greatest forces in case of fall which is why their

design and construction makes no concessions.

The central articulation means that it can be used

in any configuration (wall, floor, post, overhead)

and the type of solicitation (shearing or pulling

away). Evolution triple attachment anchorages

are compact and discreet fitting in harmoniously

with a metal building or structure. Epoxy finish

(in a wide range of colours) is also available on

request.

To guarantee a faultless link between the cable and

the anchorage points, SALA has opted for swaging

as a technical and safety solution that preserves the

full strength of the cable at its connection with the

end parts.

Integrated into a tensioner or simply fitted with

a clevis, the EVOLUTION end parts are installed

by professionals using specially calibrated tools.

Swaging guarantees a definitive and unchangeable

connection.

evolution in detail

90° standard curve

Half-curve – detail

evolution in detail

90° overhead curve

Articulated end anchor

CANADACAPITAL SAFETY GROUP CANADA LTD260 Export BoulevardMississauga, Ontario L5S 1Y9CANADAToll Free : 800-387-7484Phone : +1(905) 795-9333Fax : (905) 795-8777www.salagroup.comsales.ca@capitalsafety.com

AUSTRALIACAPITAL SAFETY GROUP LTD20 Fariola StreetSilverwaterSydney NSW 2128AUSTRALIAPhone : +61 2 9748 0335Toll-Free : 1 800 245 002Fax : +61 2 9748 0336sales@capitalsafety.com.au

ASIACAPITAL SAFETY GROUP LTDRoom 2009Tower 2 Metroplaza223 Hing Fong RoadKwai Chung N.T.Hong Kong - CHINAPhone : +852 2858 0009Fax : +852 2311 4601inquiry@capitalsafety.com.hk

EUROPE – MIDDLE EAST - AFRICACAPITAL SAFETY GROUP EMEA

Le Broc CenterZ.I. 1ère Avenue - BP15

06510 Carros Le Broc CedexFRANCE

Tel : +33 (0)4 97 10 00 10Fax : +33 (0)4 93 08 79 70

www.salagroup.com information@capitalsafety.com

NORTHERN EUROPECAPITAL SAFETY GROUP NE LTD

7, Christleton CourtStuart Road

Manor Park – RuncornCheshire – WA7 1ST – UK

Tel : +44 (0) 1928 57 13 24Fax : +44 (0) 1928 57 13 25

www.salagroup.comcsgne@csgne.co.uk

USACAPITAL SAFETY USA - PROTECTA/DBI/SALA

3965 Pepin AvenueRed Wing, MN 55066 - USA

Toll Free : 800-328-6146Phone : +1(651) 388-8282

Fax : +1(651) 388-5065www.salagroup.com

solutions@dbisala.com

www.atribu.fr

A0117EVOUK

Ever higher, farther, faster : you can’t stop evolution, you anticipate it

A brand of Capital Safety