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= Vibration Welding of ThermoPlastics =

Vibration Welding (also known as linear or friction welding) refers to a process where two workpieces are brought in contact under pressure, and a reciprocating motion (vibration) is applied along the common interface in order to generate heat. The resulting heat melts the workpieces, and they become welded when the vibration stops and the interface cools.

Vibration welding is often used for larger applications where the thermoplastics to be joined have relatively flat seams, although the process can accommodate some out of plane curvature. Recently, the automotive industry has made extensive use of the process to produce parts like manifolds, rocket motor casings, and lighting assemblies whose complex geometries prevent single component molding processes.

Advantages and Disadvantages
Vibration welding has numerous advantages over other conventional plastic welding processes. Since the heat is created at an interface, the molten polymers are not exposed to open air, preventing oxidation and contamination of the weld during the process. No filler material is required, and when welding components of the same material the joint can be expected to be just as strong as the bulk material. Heating is localized to the interface, decreasing the chances of material degradation seen with other processes which require a heat source well above the melt temperature of the material. The process itself is cost effective, with no consumables and short cycle times. Vibration welding produces virtually no smoke or fume, requires little surface preparation, and works well for a multitude of applications, making it well suited to mass production environments.

Vibration welding does have its drawbacks, however. The process does not lend itself well to low modulus thermoplastics or to joints between plastics with relatively high differences in melting temperatures. Vibration welding requires part specific fixturing and joint designs, and the part will be exposed to rigorous vibration during the welding cycle which may damage sensitive or miniature components. The finished weld will be surrounded by a significant amount of flash, which must be removed if appearance is an issue. Alternatively, hidden joint style geometries can be used. Lastly, welding of anything other than relatively flat joints will significantly complicate the process.

Vibration Welding Process
The vibration welding process is primarily made up of four steps: solid friction, transient flow, steady state flow, and solidification.

Solid Friction
In this first stage, vibration is commenced between two cold parts. The frictional energy causes the polymers to heat and eventually form a melt layer. In this stage there is no weld penetration as melting has not yet occurred.

Transient Flow
In the transient flow step the polymer begins to melt. The melt layer thickness quickly grows, causing the frictional forces to decrease. This decrease in friction decreases the heat input to the system, and a lateral flow of molten material begins to form.

Steady State Flow
In this phase the melting rate of the material matches the flow of material extruded at the lateral surfaces. The material flow and thickness of the melt layer become constant. This is the step that determines the quality of the weld. This step is maintained until the desired ‘melt down’ thickness is achieved. At that time the vibration is stopped and the weld is allowed to cool.

Solidification
During solidification the vibration has been stopped, and pressure is maintained on the workpieces until no more molten material remains. Once cooled to room temperature, the joint should have near the strength of the bulk material. Pressure is only relieved once the joint reaches an acceptable strength.

Equipment
A vibration welding machine is in essence a vertical machine press in which one side has been modified to vibrate. The main components are the vibrating assembly, a lifting table, and a tooling fixture.

Vibrating Assembly
The vibrating assembly is a moving element driven either by hydraulics or more commonly, electromagnets. The heart of this assembly is a tuned spring-mass system, powered by electrical coils acting on oppositely charged lamination stacks. The frequency of the charges is matched to the mechanical frequency of the system. Although the amplitude of the machine can be adjusted on the machine the frequency can only be changed by changing the mass of the vibrating assembly. The moving portion of the tooling is affixed to the vibrating assembly.

Lifting Table
The lifting table is a hydraulic assembly attached to the fixed portion of the tooling. The lifting table is responsible for bringing the workpieces together, and applying pressure between the moving and non moving portions of the tooling.

Tooling
Tooling refers to the fixtures which are attached to the vibrating assembly and lifting table that hold the work pieces in place. Tooling is application specific, and must allow for different (but identical) workpieces to be quickly switched out after every welding process. It is imperative that the tooling matches the workpieces closely enough to prevent any relative motion between the tooling and the workpieces, as this would reduce the amplitude of the weld and lower heat input as well as dimensional tolerances.

Process Variables
The vibration welding process has five main variables: frequency, amplitude, pressure, time, and depth.

Frequency
Frequency refers to how many times per second a vibration cycle is completed. Most machinery runs at 120Hz, although machinery is available that runs from 100-240Hz. Frequency is dependent on the mass of the vibrating assembly, and as such can only be changed by switching out components of the assembly.

Amplitude
Amplitude refers to the distance traveled during each vibratory cycle. Higher amplitudes tend to be used with lower frequencies, and vice versa. Higher amplitudes increase heat input at the cost of cleanliness and dimensional tolerances, making them more useful for larger parts. Lower amplitudes range from 0.7-1.8mm, while higher amplitudes describe cycles that cover 2-4mm.

Pressure
Pressure is the primary controller of melt layer thickness, and must be kept within an optimal range in order to produce quality joints. Although pressure can vary between 0.5-20Mpa across different materials and geometries, the tolerances for a given application are quite tight. Too little pressure will prevent sufficient heat generation, while too much pressure can cause all of the molten material to squeeze out of the joint. Both scenarios will result in a weak weld. Pressure is controlled by the lifting table.

Time
Time refers to the duration of time that vibration is applied to the workpiece. More time is associated with more heat generation and material loss to flash. Processes can be either time or depth controlled, with most modern processes being depth controlled. A depth controlled process will have a variable time, and vice versa.

Depth
Depth refers to the distance traveled by the workpieces after vibration is started. Sometimes referred to as displacement, it is directly related to the amount of material loss to flash. In general depth should be kept close to or above the thickness of the melt layer at the beginning of the steady state stage. After this value, more depth only results in loss of material without an accompanying rise in joint strength.

Weld Design
Weld design for vibration welding must include a relatively large flat surface, although some out of plane curvature can be accommodated for. The most common type of joint is a butt joint, where two flat pieces with the same cross section are welded together. Variations on this joint can include u-flanges, tongue and groove joints, and even double tongue and groove joints. When appearances are important, flash traps can be used. Flash traps refer to  hollow areas in the cross section next to the weld area that collect the flash and hide it from view.