Short Lead Time for SV-999 Structural Glazing Silicone Sealant to Florida Manufacturers

Short Lead Time for SV-999 Structural Glazing Silicone Sealant to Florida Manufacturers
  • Short Lead Time for SV-999 Structural Glazing Silicone Sealant to Florida ManufacturersShort Lead Time for SV-999 Structural Glazing Silicone Sealant to Florida Manufacturers
  • Short Lead Time for SV-999 Structural Glazing Silicone Sealant to Florida ManufacturersShort Lead Time for SV-999 Structural Glazing Silicone Sealant to Florida Manufacturers
  • Short Lead Time for SV-999 Structural Glazing Silicone Sealant to Florida ManufacturersShort Lead Time for SV-999 Structural Glazing Silicone Sealant to Florida Manufacturers

Short Description:

Description SV – 999 silicone structural sealant is a one-component, neutral curing, designed for glass curtain wall, aluminum curtain wall, glass daylighting roof and metal structural engineering structural assembly silicone sealant. Show the effective physical properties and bonding performance   Key Features 1. 100% silicone 2. No sag 3. Strong bonding strength 4. Water & weatherproof 5. Primerless adhesion to most building materials 6. 25% movement capability   Basic Application...


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Our goal is to provide high quality products at competitive prices, and top-notch service to customers around the world. We are ISO9001, CE, and GS certified and strictly adhere to their quality specifications for Short Lead Time for SV-999 Structural Glazing Silicone Sealant to Florida Manufacturers, We are sincerely welcome good friends from numerous circles at dwelling and abroad come to cooperate!


Description

SV – 999 silicone structural sealant is a one-component, neutral curing, designed for glass curtain wall, aluminum curtain wall, glass daylighting roof and metal structural engineering structural assembly silicone sealant. Show the effective physical properties and bonding performance

 

Key Features

1. 100% silicone

2. No sag

3. Strong bonding strength

4. Water & weatherproof

5. Primerless adhesion to most building materials

6. 25% movement capability

 

Basic Application

1.Glass curtain wall, aluminum curtain wall structure adhesive seal

2.Glass daylighting roof, metal structure engineering

3.Insulating glass bonding

 

Technical data sheet

Test standard Test project Unit value
Before curing——25℃,50%R.H.
  specific gravity g/ml 1.40
GB13477 Flow, sagging   or vertical flow mm 0
GB13477 Operating time min 15
GB13477 surface drying time(25℃,50%R.H.) min 40-60
Sealant curing speed and operating time   will have different with different temperatures and temperature, high   temperature and high humidity can make sealant curing speed faster, rather   low temperature and low humidity are slower.21 days after   curing——25℃,50%R.H.
GB13477 Durometer Hardness Shore A 40
  The ultimate   tensile strength Mpa 1.3
GB13477 Tensile strength(23℃) Mpa 0.8
GB13477 Tensile strength(90℃) Mpa 0.5
GB13477 Tensile strength(-30℃) Mpa 0.9
GB13477 Tensile strength(flooding) Mpa 0.6
GB13477 Tensile strength(flooding   – ultraviolet) Mpa 0.6

 

Certification

GB 16776;ASTM C1184

 

Color

Black

 

Package

300ml in cartridge * 24 per box, 500ml in sausage *20 per box

 

Shelf life

12 months

 

Note

If you want the TDS or MSDS or other details, please contact with our sales person.

 

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  • What is SILICONE RUBBER? What does SILICONE RUBBER mean? SILICONE RUBBER meaning – SILICONE RUBBER definition – SILICONE RUBBER explanation.

    Source: Wikipedia.org article, adapted under https://creativecommons.org/licenses/by-sa/3.0/ license.

    Silicone rubber is an elastomer (rubber-like material) composed of silicone—itself a polymer—containing silicon together with carbon, hydrogen, and oxygen. Silicone rubbers are widely used in industry, and there are multiple formulations. Silicone rubbers are often one- or two-part polymers, and may contain fillers to improve properties or reduce cost. Silicone rubber is generally non-reactive, stable, and resistant to extreme environments and temperatures from -55 °C to +300 °C while still maintaining its useful properties. Due to these properties and its ease of manufacturing and shaping, silicone rubber can be found in a wide variety of products, including: automotive applications; cooking, baking, and food storage products; apparel such as undergarments, sportswear, and footwear; electronics; medical devices and implants; and in home repair and hardware with products such as silicone sealants.

    In its uncured state, silicone rubber is a highly-adhesive gel or liquid. In order to convert to a solid, it must be cured, vulcanized, or catalyzed. This is normally carried out in a two-stage process at the point of manufacture into the desired shape, and then in a prolonged post-cure process. It can also be injection molded.

    Silicone rubber may be cured by a platinum-catalyzed cure system, a condensation cure system, a peroxide cure system, or an oxime cure system. For platinum catalyzed cure system, the curing process can be accelerated by adding heat or pressure.

    In a platinum-based silicone cure system, also called an addition system (because the key reaction building polymer is an “Addition reaction”). With platinum as catalyst, two different chemical groups react, a silicone hydride and a vinyl. In this reaction, an ethyl group is formed and there are no byproducts. Two separate components must be mixed to catalyze the polymers: the one component contains a platinum complex which must be mixed with the second, a hydride- and a vinyl-functional siloxane polymer, creating an ethyl bridge between the two. Such silicone rubbers cure quickly, though the rate of or even ability to cure is easily inhibited in the presence of elemental tin, sulphur, and many amine compounds.

    Condensation curing systems can be one-part or two-part systems. In one-part or RTV (room-temperature vulcanizing) system, a cross-linker exposed to ambient humidity (i.e., water) experiences a hydrolysis step and is left with a hydroxyl or silanol group. The silanol condenses further with another hydrolyzable group on the polymer or cross-linker and continues until the system is fully cured. Such a system will cure on its own at room temperature and (unlike the platinum-based addition cure system) is not easily inhibited by contact with other chemicals, though the process may be affected by contact with some plastics or metals and may not take place at all if placed in contact with already-cured silicone compounds. The crosslinkers used in condensation cure systems are typically alkoxy, acetoxy or oxime silanes such as methyl trimethoxy silane for alkoxy-curing systems and methyl triacetoxysilane for acetoxy-curing systems. In many cases an additional condensation catalyst is added to fully cure the RTV system and achieve a tack-free surface. Organotitanate catalysts such as tetraalkoxy titanates or chelated titanates are used in alkoxy-cured systems. Tin catalysts such as dibutyl tin dilaurate (DBTDL) can be used in oxime and acetoxy-cured systems….

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