A Complete Guide to PVC Retrofit Waterstop Systems

The Complete Guide to PVC Retrofit Waterstop Systems

Everything engineers, specifiers, and contractors need to know — from joint type selection to product specifications, installation requirements, and compliance standards.

Section 01

What is a retrofit waterstop?

A retrofit waterstop is a waterproofing system designed specifically for joints where new concrete is poured against an existing concrete structure. Unlike traditional embedded waterstops — which are cast into both sides of a joint during original construction — retrofit systems are anchored mechanically to the face of the existing structure before the new concrete is placed.

The result is a continuous, watertight diaphragm across the joint that prevents fluid migration even under sustained hydrostatic pressure. Retrofit waterstops bridge the gap between old and new, making them the correct specification whenever one side of a joint is already hardened concrete and reconstruction is not an option.

Traditional embedded waterstop

Cast into fresh concrete on both sides of a new joint during original construction. Requires split formwork and two sequential pours. Not viable when one side is already hardened.

Retrofit waterstop system

Anchored to the face of existing concrete using stainless steel batten bars, anchor bolts, and structural epoxy gel. New concrete is then poured against the installed profile.

Section 02

When do you need a retrofit waterstop?

Retrofit waterstops are specified whenever a new concrete element must be joined to an existing structure and the joint must remain permanently watertight. They are the standard solution for infrastructure repair, facility expansion, and structural rehabilitation projects where demolishing the existing concrete is not practical or cost-effective.

Common applications include water and wastewater treatment plant upgrades, containment wall repairs, below-grade concrete restoration, dam and lock structure rehabilitation, and tunnel lining additions. Any project where one side of the joint is already cured concrete is a candidate.

Water treatment plant upgrades
Tank and basin expansion
Tunnel rehabilitation
Containment wall repair
Below-grade concrete restoration
Wastewater facility renovation
Dam and lock structure repair
Retaining wall addition
Reservoir and aqueduct work
Foundation wall expansion
Section 03

How retrofit waterstop systems work

All Sika Greenstreak PVC retrofit systems use the same core mechanism: a flexible PVC profile is anchored flat against the face of the existing concrete, then encapsulated by the new concrete pour. The three components — mechanical anchoring, structural epoxy bonding, and PVC embedment — work together to form a seamless waterproofing diaphragm across the joint.

1

Mechanical anchoring: Stainless steel batten bars and anchor bolts fasten the PVC profile directly to the face of the existing concrete at regular intervals, holding it firmly in position during the new pour.

2

Epoxy bonding: Sika 7300 structural epoxy gel is applied between the PVC flange and the concrete surface, filling surface voids and creating a watertight bond at the anchorage interface to eliminate bypass pathways.

3

Concrete encapsulation: New concrete is poured and consolidated against the installed profile. The embedded portion of the PVC is fully encapsulated, forming a continuous waterproof diaphragm spanning the full joint depth.

Why flexible PVC? PVC is the industry standard for waterstop material because of its inherent elasticity, chemical resistance, and ability to accommodate joint movement. It will not discolor concrete, produce electrolytic action, or degrade under long-term water contact.

Section 04

Choosing the right retrofit profile

Profile selection comes down to three primary variables: the width of the profile (which determines embedment depth and hydrostatic resistance), the expected head pressure at the joint, and whether the structure requires NSF-61 certification for potable water contact. All four Sika Greenstreak retrofit profiles use the same stainless steel anchoring system and are suitable for both vertical and horizontal joint applications.

Compact — 3″ to 3 11/16″

Profiles 581 and 655. Best where wall thickness or access is limited and head pressure is moderate. Suitable for tanks, vaults, and general containment.

Standard — 6″

Profile 609. Most versatile option. Compatible with both vertical and horizontal joint transitions.

Heavy duty — 9″

Profile 667. For hydrostatic head up to 150 ft (448 kPa). Dams, deep tunnels, and critical high-pressure containment structures.

For joints in potable water structures, all four profiles carry NSF-61 certification for potable water suitability. If the project involves significant joint movement — from thermal cycling, settlement, or live load deflection — confirm anchoring spacing and profile selection with Sika prior to specifying.

Section 05

Product lineup: Sika Greenstreak retrofit systems

Four profiles cover the full range of retrofit waterproofing applications — from compact repairs in tight spaces to heavy-duty sealing under extreme hydrostatic pressure. All profiles are sold as 10-foot pieces and include stainless steel batten bar hardware. Structural epoxy is sold separately for the 581, 655, and 667; the 609 system includes epoxy.

Model 581
Compact retrofit

3 11/16″ wide · 1.51 lb/ft with hardware · Ideal for tanks, vaults, and space-constrained joints

NSF-61 certified

Model 609
Standard retrofit

6″ wide · 2.92 lb/ft · Vertical & horizontal joints · Epoxy included

NSF-61 certified

Model 655
Compact standard

3″ wide · Meets ASTM & Corps of Engineers specs · Tanks, tunnels, retaining walls

NSF-61 certified

Model 667
Heavy duty

9″ wide · 8.27 lb/ft · Rated to 150 ft head (448 kPa) · High-pressure applications

NSF-61 certified

Factory fabrications: Waterstop failures occur most often at improperly field-welded transitions and intersections. Factory-made fabrications are strongly recommended for all profile changes, corners, and intersection points.

Section 06

Physical properties — all PVC profiles

All Sika Greenstreak PVC waterstops are specially formulated and manufactured to meet or exceed the following industry-standard physical property requirements. These values apply across the full retrofit product line.

ASTM material specifications
Tensile strength2,000 psi min. (ASTM D638)
Ultimate elongation350% min. (ASTM D638)
Tear resistance300 lb/in min. (ASTM D624)
Shore A hardness79 ± 3 (ASTM D2240)
Water absorption0.15% max. (ASTM D570)
Low temp. brittlenessPasses at -35°F / -37°C (ASTM D746)
Stiffness in flexure700 psi min. (ASTM D747)
Specific gravity1.38 max. (ASTM D792)
Corps of Engineers CRD-C 572 — accelerated extraction
Tensile strength (post-extraction)1,600 psi min.
Elongation (post-extraction)300% min.
Effect of alkali — weight change+0.25% / -0.10%
Hardness change±5 points max.
Section 07

Installation overview

Retrofit waterstop installation is a precise process that requires careful surface preparation, correct epoxy application, and proper mechanical anchoring before new concrete is placed. Skipping or rushing any of these steps is the primary cause of long-term joint failures. The sequence below applies to all four Sika Greenstreak retrofit profiles.

1

Prepare the existing surface. Clean and profile the concrete face. Remove laitance, oil, dirt, and any loose or unsound material. A clean, sound surface is critical for epoxy adhesion.

2

Position the waterstop profile. Place the PVC profile flat against the existing concrete face, centered on the joint line. The centerline of the profile must align with the center of the joint.

3

Apply structural epoxy gel. Apply Sika 7300 gel between the PVC flange and the concrete surface to ensure a void-free, watertight bond at the anchorage interface.

4

Install stainless steel anchoring hardware. Fasten the batten bars and anchor bolts at the specified spacing to mechanically secure the profile to the existing concrete.

5

Heat weld transitions and intersections. Use a Sika Greenstreak splicing iron to join profile lengths, corners, and intersections. Factory-fabricated fittings are strongly preferred over field welding at all transitions.

6

Place and consolidate new concrete. Pour new concrete against the installed profile. Consolidate carefully to ensure full encapsulation of the embedded portion with no voids.

Heat welding is the only recognized installation method for splicing PVC waterstop. Sika’s Waterstop Welding Certification Program is available for contractors and employees to fulfill training requirements. Full installation guides, splicing instructions, and application guides are available through Sika’s technical documentation library at usa.sika.com.

Section 08

Compliance & certifications

Sika Greenstreak PVC waterstops are manufactured to meet or exceed the industry’s most demanding performance specifications. All PVC and TPER waterstop profiles in the Greenstreak line are NSF-61 certified, making them suitable for potable water contact applications where required by the project specification.

NSF/ANSI Standard 61 — potable water
Army Corps of Engineers CRD-C 572-74
ASTM D638 — tensile & elongation
ASTM D624 — tear resistance
ASTM D746 — low temp. brittleness
ASTM D2240 — Shore A hardness
ASTM D570 — water absorption
ASTM D747 — stiffness in flexure
ASTM D792 — specific gravity

The 655 and 667 profiles are manufactured from prime virgin PVC and meet Corps of Engineers and ASTM performance specifications. Confirm current certification status and project-specific compliance requirements directly with Sika prior to final specification.

Section 09

Waterstop design checklist

Use this checklist when specifying a retrofit waterstop system. Working through these items before writing the specification will reduce RFIs, minimize substitution requests, and ensure the installed system performs as intended for the life of the structure.

Verify chemical containment requirements — confirm whether the structure will contact potable water, wastewater, or industrial chemicals, and specify NSF-61 certification if required

Verify hydrostatic head pressure — for heads above approximately 65 ft, evaluate the 667 profile (rated to 150 ft)

Determine joint type and movement expectations — confirm whether the joint is static or subject to thermal, settlement, or live load movement

Specify profile by product number — 581, 609, 655, or 667 based on width, duty rating, and certification requirements

Verify joint orientation — confirm vertical, horizontal, or transitional joint and ensure the selected profile is rated for that application

Specify factory fabrications — require factory-made fittings for all transitions, corners, and intersections; do not rely solely on field welding

Confirm epoxy requirements — Sika 7300 structural gel is required for 581, 655, and 667; epoxy is included with the 609 system

Confirm installer qualifications — Sika’s Waterstop Welding Certification Program is available for contractor training and certification

Section 10

Frequently asked questions

Common questions from engineers, specifiers, and contractors about PVC retrofit waterstop systems.

What is a waterstop in concrete, and what does it do?

A concrete waterstop is a sealing element embedded in and running continuously through concrete joints, designed to prevent the passage of water and other fluids through the joint. Waterstops form a watertight diaphragm that spans the full joint and must be properly selected and installed to perform under hydrostatic pressure. There are two primary categories: waterstops for movement joints (which must accommodate expansion, contraction, and shear) and waterstops for non-moving joints (where negligible movement is expected).

How does PVC waterstop work?

PVC waterstop works by spanning the concrete joint and forming a continuous, watertight diaphragm that physically blocks liquid passage. When embedded in concrete on both sides of a joint, the flexible PVC profile creates a sealed barrier that accommodates joint expansion, contraction, and longitudinal and transverse movement without losing its seal. The ribbed profile surface bonds mechanically with the surrounding concrete for maximum watertight performance.

What is the difference between a retrofit waterstop and a standard embedded waterstop?

A standard embedded PVC waterstop is cast into fresh concrete on both sides of a new joint simultaneously, requiring split formwork and two sequential pours. A PVC retrofit waterstop system is mechanically anchored to the face of existing, hardened concrete using stainless steel batten bars, anchor bolts, and structural epoxy — making it the correct specification whenever one side of the joint is already cured and demolition is not feasible.

How do you install PVC waterstop in a concrete joint?

PVC waterstops must be installed prior to concrete placement to ensure proper positioning and full concrete consolidation around the profile. For retrofit applications, the profile is anchored to the existing concrete face with stainless steel hardware and structural epoxy before the new pour. For standard embedded installations, split formwork is generally required for slab-to-slab, slab-to-wall, and wall-to-wall joints. Half of the waterstop is positioned within the first pour, with the other half projecting into the second pour. The centerline of the waterstop must be aligned with the center of the joint — permissible variation depends on the profile size and style.

How do you weld PVC waterstop in the field?

PVC waterstop is field spliced using a heat welding iron — the only recognized installation method for joining thermoplastic waterstop material. With a waterstop splicing iron, extension cord, carpenter’s square, and protective gloves, installers can create continuous, watertight transitions, corners, and intersections. Sika’s Waterstop Welding Certification Program is available to contractors and their employees to fulfill training and certification requirements for welding PVC and other thermoplastic waterstop profiles.

What epoxy is required for retrofit waterstop installation, and is it included?

Sika 7300 two-component structural epoxy gel is the required adhesive for the 581, 655, and 667 retrofit profiles and is sold separately. The 609 system includes a compatible structural epoxy. The epoxy fills surface voids between the PVC flange and the existing concrete face, creating a watertight bond that eliminates bypass pathways at the anchorage interface.

Can PVC retrofit waterstop systems accommodate joint movement?

Yes. All four Sika Greenstreak retrofit profiles — 581, 609, 655, and 667 — are engineered from flexible PVC to accommodate limited joint movement, including minor expansion, contraction, and shear. For joints subject to significant movement from thermal cycling, settlement, or live load deflection, consult Sika directly to confirm appropriate profile selection and anchor bolt spacing for your specific conditions.

Are factory-fabricated waterstop fittings required for transitions and intersections?

Factory fabrications are not contractually required, but Sika strongly recommends them for all waterstop transitions, corners, and intersections. The majority of PVC waterstop system failures occur at improperly field-welded joints. Factory-made fittings are precision-welded under controlled conditions, dramatically reducing the risk of leaks at direction changes and cross-joints — and are considered best practice across the waterproofing and infrastructure construction industries.

Which Sika Greenstreak retrofit profile is NSF-61 certified for potable water structures?

The Sika Greenstreak 609 PVC retrofit waterstop is NSF-61 certified for use in potable water contact applications, including drinking water treatment plants, reservoirs, and water containment structures. If your project involves potable water, specify the 609 profile and confirm current NSF-61 certification status with Sika before finalizing the specification.

What is the maximum hydrostatic head pressure PVC retrofit waterstops can handle?

The Sika Greenstreak 667 heavy-duty retrofit profile carries a published hydrostatic head pressure rating of up to 150 feet (448 kPa), making it suitable for dams, deep tunnels, and high-pressure containment structures. The 581, 609, and 655 profiles are engineered for high hydrostatic environments but do not have a single published head pressure rating — contact Sika for project-specific pressure guidance on those profiles.

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