Ultrasonic welding

Ultrasonic welding

Ultrasonic welding is an industrial whereby high-frequency ultrasonic acoustic vibrations are locally applied to workpieces being held together under pressure to create a solid-state weld. It is commonly used for plastics, and especially for joining dissimilar materials. In ultrasonic welding, there are no connective bolts, nails, soldering materials, or adhesives necessary to bind the materials together.

Process

For joining complex injection molded thermoplastic parts, ultrasonic welding equipment can be easily customized to fit the exact specifications of the parts being welded. The parts are sandwiched between a fixed shaped nest (anvil) and a sonotrode (horn) connected to a transducer, and a ~20 kHz low-amplitude acoustic vibration is emitted. (Note: Common frequencies used in ultrasonic welding of thermoplastics are 15kHz, 20kHz, 30kHz, 35kHz, 40kHz and 70kHz). When welding plastics, the interface of the two parts is specially designed to concentrate the melting process. One of the materials usually has traditionally a spiked energy director which contacts the second plastic part. The ultrasonic energy melts the point contact between and the parts, creating a joint. This process is a good automated alternative to glue, screws or snap-fit designs. It is typically used with small parts (e.g. cell phones, consumer electronics, disposable medical tools, toys, etc) but it can be used on parts as large as a small automotive instrument cluster. Ultrasonics can also be used to weld metals, but are typically limited to small welds of thin, malleable metals, e.g. aluminum, copper, nickel. Ultrasonics would not be used in welding the chassis of an automobile or in welding pieces of a bicycle together, because of the power levels required.

Ultrasonic welding of thermoplastics causes local melting of the plastic due to absorption of vibration energy. The vibrations are introduced across the joint to be welded. Ultrasonic welding of metals is not due to heating, but instead occurs due to high-pressure dispersion of surface oxides and local motion of the materials. Although there is heating, it is not enough to melt the base materials. Vibrations are introduced along the joint being welded.

Spin welding is a related friction-based welding technique.

Practical application of ultrasonic welding for rigid plastics was completed in the 1960s. At this point only hard plastics could be welded. The patent for the ultrasonic method for welding rigid thermoplastic parts was awarded to Robert Soloff and Seymour Linsley in 1965. [Close up on technology: Top 50 Update Who Was First In Hot Runners, Ultrasonic Welding, & PET?, Plastics Technology] Soloff, the founder of Sonics & Materials Inc., was a lab manager at Branson Instruments where thin plastic films were welded into bags and tubes using ultrasonic probes. He unintentially moved the probe close to a plastic tape dispenser and the halves of the dispenser welded together. He realized that the probe did not need to be manually moved around the part but that the ultrasonic energy could travel through and around rigid plastics and weld an entire joint. [Close up on technology: Top 50 Update Who Was First In Hot Runners, Ultrasonic Welding, & PET?, Plastics Technology] He went on to develop the first ultrasonic press. The first application of this new technology was in the toy industry. [Welding Still Ensures High-Strength Joints, Assembly Magazine]

The first car made entirely out of plastic was assembled using ultrasonic welding in 1969. [Welding Still Ensures High-Strength Joints, Assembly Magazine] Even though plastic cars did not catch on ultrasonic welding did. The automotive industry has used it regularly since the 1980s. [Welding Still Ensures High-Strength Joints, Assembly Magazine] It is now used for a multitiude of applications.

Ultrasonic welding can used for both hard and soft plastics, such as semicrystalline plastics, and metals. Ultrasonic welding machines also have much more power now. The understanding of ultrasonic welding has increased with research and testing. The invention of more sophisticated and inexpensive equipment and increased demand for plastic and electronic components has led to a growing knowledge of the fundamental process. [Welding Still Ensures High-Strength Joints, Assembly Magazine] However, many aspects of ultrasonic welding still require more study, such as relating weld quality to process parameters. [Ahmed (ed), 241] Ultrasonic welding continues to be a rapidly developing field.

Components

All ultrasonic welding systems are composed of the same basic elements:
* A press to put the 2 parts to be assembled under pressure
* A nest or anvil where the parts are placed and allowing the high frequency vibration to be directed to the interfaces
* An ultrasonic stack composed of a converter or piezoelectric transducer, an optional booster and a sonotrode (US: Horn). All three elements of the stack are specifically tuned to resonate at the same exact ultrasonic frequency (Typically 20, 30, 35 or 40 kHz)
** Converter: Converts the electrical signal into a mechanical vibration
** Booster: Modifies the amplitude of the vibration. It is also used in standard systems to clamp the stack in the press.
** Sonotrode: Applies the mechanical vibration to the parts to be welded.
* An electronic ultrasonic generator (US: Power supply) delivering a high power AC signal with frequency matching the resonance frequency of the stack.
* A controller controlling the movement of the press and the delivery of the ultrasonic energy.

Applications

The applications of ultrasonic welding are extensive and are found in many industries including electrical and computer, automotive and aerospace, medical, and packaging. Whether two items can be ultrasonically welded is determined by their thickness. If they are too thick this process will not join them. This is the main obstacle in the welding of metals. However, wires, microcircuit connections, sheet metal, foils, ribbons and meshes are often joined using ultrasonic welding. Ultrasonic welding is a very popular technique for bonding thermoplastics. It is fast and easily automated with weld times often below one second and there is no ventilation system required to remove heat or exhaust. This type of welding is often used to build assemblies that are too small, too complex, or too delicate for more common welding techniques.

Electrical and Computer Industry

In the electrical and computer industry ultrasonic welding is often used to join wired connections and to create connections in small, delicate circuits. Junctions of wire harnesses are often joined using ultrasonic welding. [Ahmed (ed), 260] Wire harnesses are large groupings of wires used to distribute electrical signals and power. Electric motors, field coils, transformers and capacitors may also be assembled with ultrasonic welding. [American Welding Society, Jefferson’s Welding Encyclodpedia, 571] It is also often preferred in the assembly of storage media such as flash drives and computer disks because of the high volumes required. Ultrasonic welding of computer disks has been found to have cycle times of less than 300ms. [Grewell, Benatar and Park (eds), 169]

One of the areas in which ultrasonic welding is most used and where new research and experimentation is centered is microcircuits. [Ahmed (ed), 260] This process is ideal for microcircuits since it creates reliable bonds without introducing impurities or thermal distortion into components. Semiconductor devices, transistors and diodes are often connected by thin aluminum and gold wires using ultrasonic welding. [American Welding Society, Jefferson’s Welding Encyclodpedia, 570] It is also used for bonding wiring and ribbons as well as entire chips to microcircuits. An example of where microcircuits are used is in medical sensors used to monitor the human heart in bypass patients. One difference between ultrasonic welding and traditional welding is the ability of ultrasonic welding to join dissimilar materials. The assembly of battery components is a good example of where this ability is utilized. When creating battery and fuel cell components, thin gauge copper, nickel and aluminum connections, foil layers and metal meshes are often ultrasonically welded together . [Ahmed (ed), 260] Multiple layers of foil or mesh can often be applied in a single weld eliminating steps and cost.

Automotive and Aerospace Industries

For automobiles, ultrasonic welding tends to be utilized in the assembly of large plastic components and electrical components such as instrument panels, door panels, lamps, air ducts, steering wheels, upholstery and engine components. [Plastics Design Library, Handbook of Plastics Joining: A Practical Guide, 56] As plastics have continued to replace other materials in the design and manufacture of automobiles, the assembly and joining of plastic components has increasingly become a critical issue. Some of the advantages for ultrasonic welding are low cycle times, automation, low capital costs, and flexibility. [Grewell, Benatar and Park (eds), 141] Also, ultrasonic welding does not damage surface finish, which is a crucial consideration for many carmakers, because the high-frequency vibrations prevent marks from being generated. [Plastics Design Library, Handbook of Plastics Joining: A Practical Guide, 56]

Ultrasonic welding is generally utilized in the aerospace industry when joining thin sheet gauge metals and other lightweight materials. Aluminum is a difficult metal to weld using traditional techniques because of its high thermal conductivity. However, it is one of the easier materials to weld using ultrasonic welding because it is a softer alloy metal and thus a solid-state weld is simple to achieve. [Ahmed (ed), 251] Since aluminum is so widely used in the aerospace industry, it follows that ultrasonic welding is an important manufacturing process. Also, with the advent of new composite materials, ultrasonic welding is becoming even more prevalent. It has been used in the bonding of the popular composite material carbon fiber. Numerous studies have been done to find the optimum parameters that will produce quality welds for this material. [Harras, Cole and Vu-Khanh]

Medical Industry

In the medical industry ultrasonic welding is often used because it does not introduce contaminants or degradation into the weld and the machines can be specialized for use in clean rooms. [Plastics Design Library, Handbook of Plastics Joining: A Practical Guide, 54] The process can also be highly automated, provides strict control over dimensional tolerances and does not interfere with the biocompatibility of parts. Therefore, it increases part quality and decreases production costs. Items such as arterial filters, anesthesia filters, blood filters, IV catheters, dialysis tubes, pipettes, cardiometry reservoirs, blood/gas filters, face masks and IV spike/filters can all be made using ultrasonic welding. [The Welding Institute, Ultrasonic Welding Technique] Another important application in the medical industry for ultrasonic welding is textiles. Items like hospital gowns, sterile garments, masks, transdermal patches and textiles for clean rooms can be sealed and sewn using ultrasonic welding. [Plastics Design Library, Handbook of Plastics Joining: A Practical Guide, 57] This prevents contamination and dust production and reduces the risk of infection.

Packaging Industry

Packaging is perhaps the application in which ultrasonic welding is most often used. From tubes of toothpaste to diapers to ammunition it is amazing how many items are used on a daily basis that are packaged using ultrasonic welding. Sealing containers, tubes and blister packs are some common applications.

Ultrasonic welding has also found application in the packaging of dangerous materials such as explosives, fireworks and other reactive chemicals. These items tend to require hermetic sealing but cannot be subjected to high temperatures. [American Welding Society, Jefferson’s Welding Encyclodpedia, 570] One simple example of this application is the container for a butane lighter. This container weld must be able to withstand high pressure and stress and must be airtight to contain the butane. [Grewell, Benatar and Park (eds), 171] Another example is the packaging of ammunition and propellants. Again, these packages must be able to withstand high pressure and stresses in order to protect the consumer from the contents. When sealing hazardous materials safety is a primary concern. Thus, the reliability and automation of this process are strong benefits for companies.

The food industry finds ultrasonic welding preferable to traditional joining techniques because it is fast, sanitary and can produce hermetic seals. Milk and juice containers are examples of some products that are often sealed using ultrasonic welding. The paper parts to be sealed are coated with plastic, generally polypropylene or polyethylene, and then welded together to create an airtight seal. [Grewell, Benatar and Park (eds), 171] The main obstacle to overcome in this process is the setting of the parameters. For example, if over-welding occurs then the concentration of plastic in the weld zone may be too low and cause the seal to break. If it is under-welded the seal is incomplete. [Grewell, Benatar and Park (eds), 171] Also, variations in the thicknesses of materials can cause variations in weld quality. Therefore, the preparation of materials to be welded is extremely important. Some other food items that are sealed using ultrasonic welding include candy bar wrappers, frozen food packages and beverage containers.

In summary, the electrical and computer, automotive, aerospace, medical, and packaging industries are some of the many industries in which ultrasonic welding is utilized. This process is used to assemble everything from microcircuits to milk cartons. It is increasing in popularity throughout many of these industries because of low cycle times, automation, low capital costs, flexibility, cleanliness, dimensional reliability and the bonding of dissimilar materials. Some of the drawbacks of ultrasonic welding are that its use is limited by the thickness of the materials, it may require expensive specialized tooling and it may generate noise. As these drawbacks are overcome by continually developing technologies, it will be interesting to see how this unique welding technique continues to be utilized.

afety

Ultrasonic welding machines, like most industrial equipment, pose the risk of some hazards. These include exposure to high heat levels and voltages. This equipment should always be operated using the safety guidelines provided by the manufacturer in order to avoid injury. For instance, operators must never place hands or arms near the welding tip when the machine is activated. [American Welding Society, Welding Handbook: Welding Science and Technology, 750] Also, operators should be provided with hearing protection and safety glasses. Operators should be informed of the OSHA regulations for the ultrasonic welding equipment and these regulations should be enforced. [American Welding Society, Jefferson’s Welding Encyclodpedia, 572]

Ultrasonic welding machines must receive routine maintenance and inspection. Panel doors, housing covers and protective guards may need to be removed for maintenance. [American Welding Society, Welding Handbook: Welding Science and Technology, 750] This should be done when the power to the equipment is off and only by the trained professional who is servicing the machine.

Since this is an ultrasonic process it would seem that sound would not be an issue. However, sub-harmonic vibrations, which can create annoying audible noise, may be caused in larger parts near the machine due to the ultrasonic welding frequency. [Ahmed (ed), 266] This noise can be dampened by clamping these large parts at one or more locations. Also, high-powered welders with frequencies of 15kHz and 20kHz typically emit a potentially damaging high-pitched squeal in the range of human hearing. Shielding this radiating sound can be done using an acoustic enclosure. [Ahmed (ed), 266] In short, there are hearing and safety concerns with ultrasonic welding that are important to consider, but generally they are comparable to those of other welding techniques.

References

* Assembly Magazine (2007). [http://www.assemblymag-digital.com/assemblymag/200712/?pg=59 "Welding Still Ensures High-Strength Joints, Ultrasonic Welding"] Retrieved on 2008-03-13.
* American Welding Society (1997). "Jefferson’s Welding Encyclodpedia". USA: American Welding Society. ISBN 0-87171-506-6.
* American Welding Society (2001). "Welding Handbook: Welding Science and Technology". USA: American Welding Society. ISBN 0-87171-657-7.
* Ahmed, Nasir (Ed.), (2005). "New Developments in Advanced Welding". Boca Raton, Florida: CRC Press LLC. ISBN-10: 0-8493-3469-1.
* Grewell, David A.; Benatar, Avraham; & Park, Joon B. (Eds), (2003). "Plastics and Composites Welding Handbook". Cincinnati, Ohio: Hanser Gardner Publications, Inc. ISBN 1-56990-313-1.
* Harras, B.; Cole, K. C.; & Vu-Khanh, T. (1996) [http://jrp.sagepub.com/cgi/content/abstract/15/2/174 "Optimization of the Ultrasonic Welding of PEEK-Carbon Composites."] Retrieved on 2008-02-24.
* Plastics Design Library (1997). "Handbook of Plastics Joining: A Practical Guide". Norwich, New York: Plastics Design Library. ISBN 1-884207-17-0.
* Plastics Technology (2008). [http://www.ptonline.com/articles/200512cu1.html "Close Up on Technology: Top 50 Update - Who Was First In Hot Runners, Ultrasonic Welding & PET?"] Retrieved on 2008-03-13.
* The Welding Institute (2007). [http://www.twi.co.uk/j32k/protected/band_3/pjkultrason.html "Ultrasonic Welding Technique."] Retrieved on 2008-02-24.


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