Article re-posted with permission from Parker Hannifin Sealing & Shielding Team.
Original content can be found on Parker’s Blog.
We receive many requests from customers asking for recommendations on how to retain seals in an application. One of the most popular "quick fixes" is to apply liberal amounts of adhesive to a standard O-ring type product without respect to groove shape or sealing function. However, Parker OES provides a wide array of sealing technologies, offering innovative solutions to accommodate the challenging and vast sealing needs of our customers.
A customer had been using a standard O-ring product on an outdoor electronic device. This part was sealing the external edge of the enclosure and meant to keep out water and dust. The enclosure was plastic injection molded so this extreme edge had irregular geometry to accommodate the molding process. The original proposal was to shove O-ring cord in place and adhere it down with RTV (Room Temperature Vulcanization) so that it did not fall out during assembly. This left a rust colored stripe exposed on a consumer device due to fitment issues. Parker’s proposal was to replace the O-ring cord with a custom hollow extrusion that fit the available space and allowed complete closure, thus not exposing the seal to be visible. The RTV process was replaced with PSA (Pressure Sensitive Adhesive) that was preassembled to the seal and allowed for quick and clean placement during assembly and retention for any maintenance needed.
Gallagher recently published its Failure Modes of Elastomers in the Semiconductor Industry White Paper, now available for download on our site. This white paper discusses common issues that occur with elastomer seals in the semiconductor industry. The excerpt below is the third section of our new white paper, discussing O-Ring Stretch, Chemical Attack, Plasma Cracking, and Permeation. To download the entire white paper, visit our Resources Page, or click on the image to the right.
High performance elastomers are found in many applications in the semiconductor industry (see paper titled Perfluoroelastomers in the Semiconductor Industry). Though perfluoroelastomer (FFKM) seals are formulated to meet the highest performance requirements of integrated circuit (chip) manufacturers, even these elastomers can’t solve every sealing application nor will they last forever in service. Additionally, end users need to understand subtle performance differences between perfluoroelastomers in the same product line. For example, one product may be better at minimizing particle generation while another may be better for high temperature services.
O-Rings continue to be the most widely utilized sealing product. While the ‘Donut’ shaped profile has by and large been kept intact since their inception, continued elastomeric development has pushed o-ring temperature and chemical compatibility to limits unimaginable several decades ago.
Typically, O-Rings fail due to adverse effects of a number of factors, from improper installation and lubrication to incorrect size and design. The collection of videos below will help you minimize installation errors that may lead to failure (be sure to bookmark this page for future reference).
[embed]https://youtu.be/QcJBVQvTvhw[/embed]
Article re-posted with permission from Parker Hannifin Sealing & Shielding Team.
Original content can be found on Parker’s Blog.
Precision O-rings are manufactured by vulcanization in a closed mold using compression or injection molding. This makes it possible to produce O-rings in relatively small manufacturing tolerances and with good surface quality according to ISO 3601-1 and ISO 3601-3. Due to defined vulcanization parameters, precision O-rings
[embed]https://www.youtube.com/watch?v=dAG0ymNGaHE[/embed]
Lubrication of O-rings is extremely important. The greatest benefit of using a lubricant is typically obtained during installation.
Using a lubricant is going to decrease the surface friction of the O-ring helping to prevent abrasion, pinching or cutting of the O-ring during installation. Lubricating an O-ring can also help to seat the O-ring properly into the application, as well as aid and speed up automated assembly processes.
The proper method of applying a lubricant to an O-ring always seems to be an area of concern for many of our customers and there are many methods used in the marketplace. One is to apply the lubricant to the O-ring using your fingers, your hand or a brush. Another is
The face seal design chart below explains the hardware dimensions to use for an O-ring seal when the groove is cut into a flat surface.
For designing systems which contain internal pressure, like the example below, the groove's outside diameter (OD) is primary, and the groove's width then determines the inside diameter.
Extrusion and nibbling of the O-ring is a primary cause of seal failure in dynamic applications such as hydraulic rod and piston seals. This form of failure may also be found from time to time in static applications subject to high pressure pulsing which causes the clearance gap of the mating flanges to open and close, trapping the O-ring between the mating surfaces.
Watch the video below from Parker's O-Ring eHandbook, showing how extrusion & nibbling can happen.
Article re-posted with permission from Parker Hannifin Sealing & Shielding Team. Original content can be found on Parker’s Blog.
This video provides instructions on how to properly install and uninstall a Parker TechSeal's hollow O-ring. Although appearing simple, the installation process of a hollow O-ring requires a proper method in order to prevent overstretching the seal.
[embed]https://www.youtube.com/watch?v=pCMwwuyfrso[/embed]
The best way to install a hollow O-ring is to start at one point and work your way around the groove, pushing the seal into the groove. Once the seal is installed, lightly slide your finger around the seal to make sure that the seal is positioned and aligned correctly. Replacement is also fast and simple; gently pull the old seal out of the groove and install
Article re-posted with permission from Parker Hannifin Sealing & Shielding Team. Original content can be found on Parker’s Blog.
Dovetail grooves are a great mechanism for holding O-rings in place. The retention feature makes having an upside-down or vertical face seal groove much easier. However, installing an O-ring into these grooves can be tricky without proper technique. The most important variable for installing an O-ring into a dovetail gland is making sure the seal is sized properly.
[embed]https://www.youtube.com/watch?v=KJje7GgFBbQ[/embed]
Start the installation by directly aligning the O-ring
Article re-posted with permission from Parker Hannifin Sealing & Shielding Team. Original content can be found on Parker’s Blog.
This is the third in a series of video blog posts showing viewers how to install an O-ring.
In December, we discussed how to install an O-ring on a face seal gland and in January we showed you how to install an O-Ring in a standard female gland. In today's post, we'll look at the best way to install an O-ring on a standard male gland.
[embed]https://www.youtube.com/watch?v=QcJBVQvTvhw[/embed]
Typically when installing an O-ring into a standard male gland, the process is pretty straight forward. Guide the O-ring along the shaft until you reach the gland to where it snaps in place. Sounds simple enough, but here's some tips on exactly what to do, and not to do.