Dear Reader!

When talking to our existing customers and industry partners, and particularly our prospective clients, it appears to me that surface treatment via plasma is often still a best kept secret in manufacturing.

Plasmatreat came into existence almost 20 years ago, when the automotive industry was looking to source a better alternative to increase adhesion on a variety of polymers. Eliminating the problem of moisture ingress into car headlamps was one of the first key applications for atmospheric plasma. Plasma treatment until then was only available in a low pressure, vacuum chamber based environment. This limitation stipulated a batch style process which for many manufacturers was doable but limited productivity. Thus Openair Plasma,  offering the first atmospheric plasma solutions, was first created.  Plasmatreat has been the global leader in developing atmospheric plasma solutions for industry ever since.

Plasma is a naturally occurring phenomenon, such as lightening bolts, or the Northern Lights, in fact most of the universe is made of plasma. Here is a fascinating link that shows plasma around our globe in a time lapse video shot from the space station, orbiting the earth: http://vimeo.com/32001208?utm_source=dlvr.it&utm_medium=twitter.

Plasmatreat invented devices (plasma jets) that harness the power of plasma and apply them to surfaces of substrates. Most common surfaces our equipment treat  are polymers, glass, ceramic, metals (particularly aluminum). This always occurs in atmospheric conditions thus can be incorporated into existing production processes without too much effort. Capex spending is very limited. The results are very clean surfaces (down to the nano level), and increased bonding strength for adhesives. The ROIs derive from lower necessary quantities of adhesives material, the utilization of a lower grade of adhesives, the possibilty for faster production speeds, and the reduction of VOCs (green technology).

However the devils lies in the detail, as always. Plasmatreat applications have been developed for a variety of markets and industries, in fact a dozen different markets, with thousands of different applications within them. So in order to enter into a quality discussion with our customers, Plasmatreat is now starting the: “PlasmaBlog”. Our market managers are offering their insight and expertise for each of their markets. We are focusing on solutions, new ideas, and insights we gained from working with this intriguing and effective technology every single day. We welcome your comments, we look forward to your questions. Challenge us!

Till next time,

Andy

I lied, partially.

I said that my next talk would be a trip report (sadly, Dyana said it was overcast) and power of plasma for modification of materials for the life sciences industry.   I’m not ready to jump into specific applications, rather want to start with some of the basics to a successful surface modification program.

I’ll start with Step 1.  Q&A.

The beginning of any lab development program typically involves a thorough Q&A session.   At the minimum, I want to know:

1.  Substrate

2.  Product environment

3.  Desired surface performance goal

The success, based on my experience, of a surface modification program relies on a thorough (if possible) understanding of these three items as 1 and 2 greatly impact the 3.

For each question, there are 10s if not 100s of sub-questions that can shift outcome considerably.   I spoke about some of these recently at Hantel Technologies   http://www.youtube.com/watch?v=gZemVc790oQ  and am summarizing a partial list of variables for each question below.

1. SUBSTRATE.  Tell me about (I’m polymer focused):
1. Resin selection/Metal properties
2. Composite properties
3. Manufacturing practice (molded, extruded, cast).  Are you starting with a machined part for R&D and then possibly considering molding for production.  We may talk about molecular weight distribution as well.
4. Cure mechanism
5. Cure temperatures
6. Hardness (durometer)/crystallinity
7. Topography
8. Tacticity
9. Additives (stabilizers, pigments, nucleating agents, plasticizers, etc)
10. Propensity for migration of additives
11. Propensity for molecular rotation
12. Finishes
13. Mold release materials
14. Machining debris
15. Moisture retain/absorption/adsorption
16. Cleanliness (and how is the substrate cleaned prior to plasma)
17. Manufacturing controls for said substrate
18. Throughput targets

2. ENVIRONMENT.  Once treated, please tell me about the next steps in processing and environment as these variables may impact surface performance and stability:
1. See Item #1.9 above.  Bloom, migration of Internal impurities
2. Adhesive technique (if bonding) and cure mechanism
3. Potential for oxidation
4. Chemical exposure
5. Sterilization technique
6. Subsequent assembly step (are you heat sealing?)
7. Subsequent cleaning steps and techniques (are you IPA wiping part 100X times during assembly?)
8. Handling (glove selection and practices)
9. Storage (Packaging materials, Temperatures)

3. SURFACE PROPERTIES.  What do you want as we have many variables to consider to provide the desired outcome.  Rather than listing the myriad of applications we practice, I’ll focus on variables that we consider in designing an experimental plan.

1. Type of equipment (Corona, Atmospheric, Low Pressure)
2. Steps and type of process (Cleaning, Etching, Activation, Functionalization, PECVD, Grafting, Crosslinking)
3. Chemistry (gas, liquid vapor, sublimated solids, combinations).
4.  Temperature of substrate, chamber, liquid/solid
5. Pressure (flow driven, throttled, pumping capacity)
6. Fixturing and fixture materials (does it contribute to dark space?)
7. Power (continuous, pulsed, duty cycle, frequency)
8. Time (3o seconds or 10 minutes)

BUT WAIT.  There is more!

VALIDATION TECHNIQUE/SURFACE ANALYSIS

Even the choice of how to validate the surface can impact the results.  Our chief technologist, Steve Kaplan, loves to say “don’t throw out the baby with the bathwater.”   It is not unusual for a customer to overlook the success of the process by improper selection of the validation method.  Ultimately, test the product in the ultimate application.  Techniques used and considered at our laboratories include:

• Surface energy testing
• Dyne-cm, contact angle
• fluid choice
• Adhesion testing
• Wear and abrasion testing
• Friction testing
• Hardness testing
• Surface analysis
• X-ray Photoelectron Spectroscopy (XPS)
• Scanning Electron Microscopy (SEM)
• AFM Atomic Force Microscopy
• Fourier Transform Infrared Spectroscopy (FTIR)
• Chemical resistance
• Gas permeation / vapor barrier testing

This list isn’t to overwhelm.   I don’t expect answers to all of these questions nor do we screen every possible combination of variables.  We know where to start if you can provide us with the basics about  1 (Substrate), 2 (Environment of use) and 3 (Desired surface performance) so that we can design efficiently and effectively the best surface for your application.

Next blog…no promises.

Hello loyal blog readers, 

I am often asked what makes Plasmatreat different than other companies selling similar equipment.

Please allow me to explain a bit about Plasmatreat as a company and the plasma equipment we produce.

Plasmatreat is the inventor of atmospheric plasma and currently holds approximately 130 international patents on the design.

Our equipment is manufactured in Germany, and I am sure you can appreciate the quality of both the engineering and manufacturing associated with this.

 Plasmatreat’s philosophy of sales is to provide our customers with a solution to their bonding challenges and not just sell a commodity.  As such, we have a full lab, accessible to our customers, in our Ancaster Ontario, Elgin Illinois and Belmont California locations.

We provide service and stock spare parts for North America from our Ancaster location so next day delivery of parts is certainly possible.  24hr service support is available 7 days a week.

I would like to highlight a few of the features that are included in our plasma systems.

Our generators constantly monitor the plasma voltage, plasma current and sir supply to the jet in order to maintain consistent process parameters.  The limits for each of these parameters is software programmable so the allowable variation in plasma output is determined by the end user.

 Although the process parameters are monitored as noted above, Plasmatreat has developed an independent method to ensure, and obtain QS9000 compliance, that plasma is actually being generated in the jet.  This is accomplished through the use of an optical focusing lens that looks directly at the plasma and this signal is sent to the generator, via a fibre optic cable, where it is monitored in real time to ensure 100% feedback that the plasma is present.

Through our control panel, the voltage, frequency and duty cycle of the plasma can be varied allowing the system to be set up for ideal processing parameters.

The incoming power supply from any customer normally has some degree of fluctuation throughout the day.  Our generators have a power regulator that ensures that the plasma voltage remains constant regardless of the incoming voltage. (95-250VAC is the allowable fluctuation with our smallest systems and 340-500VAC for our three phase systems)  Without this feature, the plasma intensity would vary with the incoming voltage affecting the treatment of the part.

All of our cables contain multiple layers of electrical shielding to ensure that no EMI is present to interfere with other sensitive electronic equipment or possible operator safety due to shock or pacemaker interference.

I have listed some of the features that set us apart from the other plasma equipment you may find on the market and I suggest you become curious as to whether these features are also available on the systems you are comparing ours to. Some of these features have safety concerns attached to them.

I feel very confident that once you have a chance to compare, you will be able to make the correct decision for your company.

Tim

America and Canada are a truly great countries. Both regions are characterized by truly freedom loving people, both feature strong democracies despite the daily stalemates and political quabbles.  While their economies in general are powerful and have created some of the largest wealth per capita in the world, the recent 10-15 years have been marked by, in my view, myopic activities in industry: Manufacturing was given up on. With China achieving first “most favored nation status” and then later gaining access to the WTO, thus allowing for tax and duty favored imports, many manufacturing companies started to believe that they could not compete with China as well as other countries in the SE Asia region with their low wages and other low operating costs. Comprehensive new supply chain systems were set up, new operating and trading relationships were established, more and more company managers became ex-patriates. Some companies that wanted to continue producing product in North America were forced by large retailers such as WalMart to move their operations to a China location. The common crede became: Operating our production in China is the better way, there is no such future in North America.  

I disagreed from the Get-Go. I always believed that America needs manufacturing. One needs to build things to create value. Our countries cannot simply be service and consumption oriented societies. We saw what happened if when relied on the finance/banking sector alone. It created huge wealth only for a very few and when it all went wrong, we were all asked to pay the bill.

Manufacturing creates jobs at all levels, stimulates personal and professional creativity, helps shape products and processes and let us focus on the future by taking direct control. Plasmatreat works with manufacturers all over the world creating better and more productive operating environments. Here in Canada and the USA we have the potential to reclaim a top spot in the global arena of manufacturers. Designing and building product creates not only possibilities domestically but also sets the stage for successful exports. The USA in particular has been suffering from a negative trade deficit for several decades now. We need to think about reversing the flow of dollars into America not away from America. We need to support the Reindustrialization of America – we need to believe again in manufacturing. Plasmatreat together with our many industrial partners continuously are presenting ideas how to create competitive operating environments right here in North America. Our projects reach into various markets such as Solar, Medical, Packaging, Automotive and Electronics. We look foward to mastering the challenge to compete with low cost production countries, but we believe we can. Do you, too?

Till next time,

Andy

I am often asked how can a company verify, in a production environment, that a part has been treated successfully with plasma?   How can they verify post-treatment surface activation?  I will answer these two questions separately as they have two very distinct answers.

Most plasma applications utilize some form of automation to treat a part and some form of fixture to hold the part in a known location while it is being treated.  These systems also run, sometimes for months at a time, without human supervision.

Let’s break down the three key parameters that will ensure that the part has been successfully treated using plasma. 

1- The Plasma

2 - The Robot Path

3 - The Part Fixture

The Plasma

As discussed in my last blog, Plasmatreat equipment has the ability to monitor the voltage, current, frequency and duty cycle of the plasma as well as the incoming and internal jet (optional) air pressure.  In addition to the control and monitoring of all of these parameters, the LCM option allows for the independent verification of the presence of plasma allowing for QS9000 rating.  If all of these feedback signals are present then it can be assured that plasma is present, with the correct operating parameters, at the plasma jet.

The Robot Path

Once a robot has been programmed with a treatment path, it cannot vary from this path without triggering some sort of error.  It is safe to assume that a robot will follow the proscribed path exactly each time and if for some reason it does not, then an error will be indicated.

The Part Fixture

A part fixture must hold the part in an exact location to ensure that the plasma jet, when being moved by the robot, will maintain a fixed and repeatable distance from the part that is to be treated.  The part fixture usually includes some form of mechanical clamping or vacuum to ensure that the part sits properly in its nest.  Through the use of proximity or optical sensors, it can be verified that the correct part is seated in the correct position within the part fixture.

With the abovementioned three parameters verified; the correct plasma, the correct robot path at the correct distance from the desired part, it can be safely assumed that the part is receiving the proper plasma pre-treatment.

Post Treatment Surface Energy Verification

The above steps ensure that the part has been successfully treated with plasma but does not verify that the plasma has been successful in raising the surface energy to the level expected.  One of the largest varibles in pre-treatment that has not been mentioned so far is the substrate itself. 

Even if you have very tight control over your resin manufacturer and supplier, there may be variations in the molded part due to molding machine parameters, mold release agents and/or the environmental conditions present at the time of molding or during part storage after molding.  If you don’t have tight control over the resin you are using then the variation in the properties of the finished part can be even more significant.

These variations due to the substrate can have a negative overall effect on the surface energy of the product before and after plasma treatment.

In order to verify that the post treatment surface energy is sufficient, the only practical method that I have seen, for use on the plant floor, is to use dyne test inks.  The frequency of this testing is usually dictated by the Quality Control department. A part is taken off of the line, its dyne level is measured and checked against the level required and, assuming that the level is sufficient, the part is usually re-introduced into the assembly line for further processing.

To recap, by verifying that the plasma treatment is correct and by further verifying that the resultant surface energy is as expected, a manufacturer can rest assured that their process is performing properly.

Tim