High Quality for SV-628 Acetic Silicone Sealant to San Diego Factories

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Description

It is one- component, moisture curing acetic silicone sealant. It cures fast to form a permanently flexible, waterproof and weather resistant silicone rubber.

Where to use

Widely used in construction, glass assembling and home decoration.SV-628 has good adhesion  to most common building materials e.g. glass, ceramic, tile, wood and fiber glass.

Key Features

1. 100% silicone

2. Easy to apply 

3. Excellent elasticity

4. Excellent adhesion to most common building materials          

5. Outstanding weatherproofing capability

6. Fast Curing

Basic Application

1.All kinds of glass curtain wall weatherproof seal
2.For metal (aluminum) curtain wall, enamel curtain wall weatherproof seal
3.Joint sealing of concrete and metal
4.Roof joint seal

Technical data sheet

Technical data sheet for reference,

Certification

JC/T881-2001 20LM; GB/T14683-2003 20LM.

Color

clear, black, silvery gray, white, brown

Package

300ml in cartridge * 24 per box, 590ml 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.

Behold The Future…Hydrogel superglue is 90 percent water, New “water adhesive” is tougher than natural adhesives employed by mussels and barnacles.

Nature has developed innovative ways to solve a sticky challenge: Mussels and barnacles stubbornly glue themselves to cliff faces, ship hulls, and even the skin of whales. Likewise, tendons and cartilage stick to bone with incredible robustness, giving animals flexibility and agility.

The natural adhesive in all these cases is hydrogel — a sticky mix of water and gummy material that creates a tough and durable bond.

Now engineers at MIT have developed a method to make synthetic, sticky hydrogel that is more than 90 percent water. The hydrogel, which is a transparent, rubber-like material, can adhere to surfaces such as glass, silicon, ceramics, aluminum, and titanium with a toughness comparable to the bond between tendon and cartilage on bone.

In experiments to demonstrate its robustness, the researchers applied a small square of their hydrogel between two plates of glass, from which they then suspended a 55-pound weight. They also glued the hydrogel to a silicon wafer, which they then smashed with a hammer. While the silicon shattered, its pieces remained stuck in place.

Such durability makes the hydrogel an ideal candidate for protective coatings on underwater surfaces such as boats and submarines. As the hydrogel is biocompatible, it may also be suitable for a range of health-related applications, such as biomedical coatings for catheters and sensors implanted in the body.

“You can imagine new applications with this very robust, adhesive, yet soft material,” says Xuanhe Zhao, the Robert N. Noyce Career Development Associate Professor in MIT’s Department of Mechanical Engineering. For example, Zhao’s group is currently exploring uses for the hydrogel in soft robotics, where the material may serve as synthetic tendon and cartilage, or in flexible joints.

“It’s a pretty tough and adhesive gel that’s mostly water,” Hyunwoo Yuk, a graduate student in mechanical engineering and the lead author of a paper on the work, says. “Basically, it’s tough, bonding water.”

Zhao and his students publish their results today in the journal Nature Materials.

A stretchy anchor…
A tough, flexible hydrogel that bonds strongly requires two characteristics, Zhao found: energy dissipation and chemical anchorage. A hydrogel that dissipates energy is essentially able to stretch significantly without retaining all the energy used to stretch it. A chemically anchored hydrogel adheres to a surface by covalently bonding its polymer network to that surface.

“Chemical anchorage plus bulk dissipation leads to tough bonding,” Zhao says. “Tendons and cartilage harness these, so we’re really learning this principle from nature.”

In developing the hydrogel, Yuk mixed a solution of water with a dissipative ingredient to create a stretchy, rubbery material. He then placed the hydrogel atop various surfaces, such as aluminum, ceramic, glass, and titanium, each modified with functional silanes — molecules that created chemical links between each surface and its hydrogel.

The researchers then tested the hydrogel’s bond using a standard peeling test, in which they measured the force required to peel the hydrogel from a surface. On average, they found the hydrogel’s bond was as tough as 1,000 joules per square meter — about the same level as tendon and cartilage on bone.

Zhao group compared these results with existing hydrogels, as well as elastomers, tissue adhesives, and nanoparticle gels, and found that the new hydrogel adhesive has both higher water content and a much stronger bonding ability.

“We basically broke a world record in bonding toughness of hydrogels, and it was inspired by nature,” Yuk says.

https://news.mit.edu/2015/hydrogel-superglue-water-adhesive-1109

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Newly engineered water superglue (MIT Video)

Learn how to make a polymer clay cane with a moon face and stars. With slices you can make rings, necklace, buttons and many other things. SUBSCRIBE! https://goo.gl/Wu0qF1 weekly videos on WEDNESDAY and SUNDAY. EXPAND! info in: English, Español, Italiano, Français

materials and tools i used:
- Polymer clay (Fimo, Sculpey, Cernit, Premo, Kato clay, etc.)
- earrings hooks
- Round Pliers
- Cutting pliers
- wire
- Blade
- scalpel
- super glue
- crochet hook
- Rolling pin, or pasta machine
- Oven
Polymer clay Items must be cooked to 110 ° C, following manufacturer’s instructions.

Check out my playlists here:

https://goo.gl/oCQixw

Want to know more about polymer clay ideas ?

https://goo.gl/V4fZyo

Want to know about miniatures?

https://goo.gl/Ly7E8E

Music:
“The place insidet” by Silent Partner
Youtube Audio library

Brief music Introduction:
“Sing Along with Jim” by Kevin MacLeod
www.incompetech.com
Licensed under Creative Commons: By Attribution 3.0

https://creativecommons.org/licenses/by/3.0

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Les mostraré como realizar estos simpáticos pendientes utilizando unos caños millefiori con la imagen de la luna y de las estrellas, utilizando arcillas poliméricas.
Materiales y herramientas que he utilizado:
- Arcilla polimérica (Fimo, Sculpey, Cernit, Premo, Kato clay, etc.)
- pegamento fuerte
- gancillo
- bisturí
- ganchos para pendientes
- Pinzas
- Alicate de corte
- Alambre
- Rodillo o laminadora
- Horno

Los artículos hechos con arcillas poliméricas deben cocinarse a 110 ° C en un horno común, siguiendo las instrucciones del fabricante.
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Dans cette vidéo vous apprendra à faire une canne millefiori, en utilisant la pâte polymère, avec l’image de la lune et les étoiles. Avec les tranches, vous pouvez créer des anneaux, colliers, boutons et beaucoup d’autres choses.
Matériaux et outils que j’ai utilisé:

- Pâte polymère (Fimo, Sculpey, Cernit, Premo, Kato clay, etc.)
- boucles d’oreilles crochets
- crochet
- Pinces rondes
- pince coupante
- Fil métalique
- Pince coupante
- lame ou scalpel
- colle forte
- Rouleau à pâtisserie, ou machine à pâtes
- Four

Les articles doivent être cuits à 110 ° C dans un four commun, suivant les instructions du fabricant de pâte polymère.

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In questo video vi insegnerò a fare una canna millefiori, utilizzando la pasta sintetica, con l’immagine della luna e delle stelle. Con le fette, è possibile creare anelli, collane, bottoni e molte altre cose.
Materiali e attrezzature che ho usato:
- Pasta sintetica
- Filo metallico
- colla
- uncinetto
- lama o bisturi
- pinze a punta rotonda
- tronchesine
- Matterello, o macchina per la pasta
- Forno

Gli oggetti, se realizzati con le argille polimeriche,devono essere cotti a 110 ° C in forno comune, seguendo le istruzioni del produttore.