Perfect dispensing of two-component silicone
Materials science and optimized handling
Silicone – especially two-component silicone – has become one of the most versatile connecting materials. And can be used across a huge range of applications. Although many users are only familiar with standard commercial “silicone sealants” in plumbing, the material has considerably more potential uses. Meanwhile, the ongoing development of silicones is opening new applications in the industry for future production methods. The development of new products and production methods means: Users are constantly faced with new requirements in terms of silicone’s material properties.
A great task for dispensing technology
However, extending its material properties also calls for development of the processing systems. To keep pace with the new applications in production processes. This applies for both – one- and two-component materials. Because of these two technological drivers for chemical joins, this sector is currently experiencing rapid development. As a result of their versatile material properties, two-component silicone rubbers are being used increasingly frequently in industrial applications. These silicones are long-chain polysiloxanes – mainly in a pourable to plastic form. They are vulcanized to an elastic rubber by addition or condensation curing. Their key features include high temperature resistance, good diffusion density, high chemical resistance and adjustable thermal conductivity. They are primarily used in the automotive and electronics industries, but also increasingly in the pharmaceutical and orthopedics industry.
One very interesting product development involves two-component silicone in which the material hardness (“Shore hardness”) in vulcanized form can be varied in a certain small range by regulating the mixing ratio. Uses of these silicones include applications in medical technology. In the manufacture of prosthetics, orthopedic arch supports and pads, this type of silicone enables slightly different hardness ranges to be established within a product.
Applied pumping systems for 2-component silicone
In a dispensing system with gear pumps, mixing ratios can be adjusted by a software-controlled change in the rotation speed of the gears, although this requires sophisticated control engineering. The dispensing quantity produced does not have a linear relationship with the change in speed. Because of the back-flow behavior of this pump system. The actual delivery quantity must be measured by a volume meter and fed back to the system. This means that the dispensing pumps adjust the actual dosing process after a delay. These variations in dispensing become greater as the dosing quantities are reduced and the required dosing accuracy increases.
Because of the volumetric forced delivery principle, they are based on piston dispensing systems do not require any sophisticated continuous adjustment. And operate with a reduced system complexity. However, in simple piston pump systems the fact that every variation in the mixing ratio can only be achieved by a hardware side system adjustment has a limiting effect. The solution involves adjusting the piston stroke using mechanical stops (bars) or by complete replacement of the dosing piston.
Nevertheless, these hardware adjustments require modification work, costs for the replacement parts and significant system stoppages. A further disadvantage of piston dosing systems is the effectively limited production time. Caused by the necessity of refilling the piston volume with the material, respectivelly the two-component silicone. This cycle of dosing and piston filling required by the system means: Only pulsed rather than continuous material delivery is possible. The time needed to refill the piston is extended as the material becomes increasingly viscous.
Optimal implementation due to pumps with endless piston principle
In terms of quality and cost: The best results for using variable mixing ratios can be achieved with dispensing systems that provide high accuracy in the component quantities to be applied. Without cost-intensive control mechanisms, combined with time and cost saving software based configuration. The endless piston principle used by ViscoTec has proved to be a very effective technology. For flexible and precise adjustment of two-component mixing ratios within a dispensing cycle.
This method is based on a volumetric dispensing principle that offers outstanding dispensing accuracy even with fluctuating material viscosity. The interaction between the rotor and the stator produces enclosed chambers. With identical volumes that also do not change during the dispensing process. The special dispensing geometry of the dispensers guarantees the pulsation free flow. It is essential for precise control of mixing ratios. The material is conveyed from the intake to the delivery side of the pump. And follows a uniform and continuous moving flow in one direction.
Dispensing systems for two-component silicone
Based on the configuration of two-component dispensing systems, two dispensing pumps are attached directly to a mixing head. Next to one another in a v-arrangement or standing next to each other. The result is a space-optimized mixing head (first picture) with optimized dead space. Here the A- and B-components of the silicone are fed to the static mixer by two separate channels. The special design of the outlet opening extends the separate feed channel for the components into the static mixing pipe. It reliably prevents a direct curing reaction in the mixing head itself.
Dispensing inaccuracies can be eliminated: Due to the direct combination of the dispensing pumps at the mixing head and the use of short dispensing distances after the pump outlets. That can otherwise occur due to uncontrollable pressure profiles in long conveying distances. The specified mixing ratios can be achieved with excellent accuracy using the system construction described.
The progressive cavity pump technology used works on a strict volumetric principle. Each pump revolution always doses a fixed, defined volume of material. With a defined speed in revolutions per unit of time allowing a delivery quantity in ml per unit of time to be set. There is a linear correspondence between the dispenser speed and the dispensing quantity. I.e. doubling the speed results in double the delivery volume with no delay. This volumetric accuracy is achieved on the systems with outstanding reliability and no pulsation even with fluctuating viscosity values.
On the two-component dispensing system described, the delivery quantity per channel depends on the required mixing ratio for the two-component silicone. The motor speed of the dispenser drives is controlled by an analogue signal. The delivery quantity is provided at the pump outlet. In the exact volume required and directly linear to the set analogue control signal. Because of this functional principle, the system provides the technical capability of continuously changing the dispensing quantity per unit of time. At any point in the dispensing process. And allows quantity profiles to be used. This means that variable mixing ratios for the materials delivery to be used. Based on the achievable dispensing accuracy of the system, dynamic changes to the mixing ratio when applying material is achieved. By variable control of the individual delivery quantity for each material channel.
The control concept for the two-component dispensing system provides two interfaces. The drive units can be actuated. Either by external signal paths from a higher-level controller in an automation system. Or by the two-component dispensing controller specially developed by ViscoTec. On the ViscoTec controller, all basic parameters for the process are preset and calibration is performed. Such as mixing ratio, dispensing speed and dispensing quantity.
The integrated recipe management function enables different mixing ratios and thus product properties to be preset, stored and activated by just a few clicks on the touch panel. As well as setting these basic parameters such as dispensing quantity, dispensing speed and mixing ratio, the ViscoTec controller provides more: An extensive range of adjustable process parameters that support fully automatic production and ensure a stable product quality. The dispensing controller includes an option for specifying and monitoring the dispenser intake and dispensing pressures. If the limits defined by the user are exceeded, a visual indication appears on the display. And an electric signal is transmitted to external devices.
Available additional functions when dispensing two-component silicone
Additional parameters for specifying the material pot life and for adjusting the time to next rinse and a rinse counter are also available. If at least x times the filling volume of the static mixer has been dosed within the set pot life, the system generates an error message. This ensures that no material that is already reacting is used and prevents curing in the static mixer.
Using the time to next rinse parameter allows the controller to initiate a rinse before the pot life has elapsed. By sending a signal to an external controller, the handling system can move to a defined axis position for the rinse. A maximum number of rinses – i.e. a limit on the number of rinses to be carried out – can be set. For example, to prevent excessive consumption of silicone material for rinses during a significant system stoppage. Once this maximum quantity has been reached, the controller generates an error message. And supports the operating personnel in proper system management.
Uniform and high-quality processing of two-component silicone
The endless piston principle from ViscoTec is also used in material extraction and treatment systems in addition to its use in two-component dispensing systems. The material supply routes for two-component systems are provided by parallel channels for the A and B component. With the technology described here, ViscoTec can guarantee uniform and high-quality processing of silicones. All the way through the entire procedure, from emptying of the material through to the dispensing process itself.