Difference between revisions of "Tape Casting"

One of the most well-known and used method to manufacture multilayered ceramic components is the doctor blade tape casting technique. Glenn N. Howatt is regarded as the godfather of tape casting and established this processing method in 1947^[1] and also filed the first patent in 1948^[2]. A plentiful variety of electronic components like multilayer ceramic capacitors (MLCC), actuators (MLA), varistors (MLV) or tapes for low/high temperature cofired ceramics (LTCC, HTCC) can be manufactured.

Components of a tape caster

Tape casting machine

Tape casting machines are available in different scales. Usually big industrial companies have continuous tape casters with a length of several hundred meters. However, in academic research much smaller lab-scale tape casters are used which can range from half a meter to several meters in length. Major components of such machines are a solid, level casting surface, reservoir for the slip, doctor blade systems, drying chamber with measures for controlling the airflow and temperature of the air during drying, an adjustable speed drive control during casting, and underbed heating systems.

Lab-scale doctor-blade tape caster. The slurry is poured into the reservoir before starting to cast.

Another doctor-blade tape caster with exchangable reservoirs and doctor-blades. Additionally, a heating plate can be useful during drying.

Continuous as well as discontinuous tapes can be prepared with lab-scale tape casters. For continuous tapes, guide rollers, and rollers with the carrier substrate are needed. If discontinuous tapes are produced, carrier substrate sheets can be used likewise.

Schematic of the doctor blade tape casting technique. The slip is poured in a reservoir and cast on a carrier substrate on an exemplarily granite block. The doctor-blade height defines the green sheet's thickness.

The machines can be equipped with unbderbed heating systems to keep the drying temperature constant. The ingredients of the slip need to be adjusted towards elevated temperatures to avoid rapid drying and bubbling. Solvents may evaporate much faster thereby degrading the green tape severly. It is recommended to use temperatures close to room temperature.

Carrier substrate

Stainless steel belts as carrier substrates are most common in continuous manufacturing operations. It is economic and cost-effective. However, also Mylar, PTFE (Teflon), cellophane, silicone-coated polyester, and many other materials are suitable as well. Especially for lab-scales, Mylar sheets are easy to handle. If the tape caster The binder, solvent, and plasticizer system determines the interaction with the carrier material. The slip needs to wet the surface sufficiently and after drying the green tape needs to be peeled off easily.

Carrier substrate sheets are used for discontinuous tape casting. Peeling off the green sheets of the carrier substrate is one important but critical step.

Reservoir

A reservoir is utilized to store the slip temporarily in front of the doctor blade. It distributes the slip along the blade and feeds the blade continuously. For lab-scale tape casters in particular, removable reservoirs with fixed gap doctor blades are used. Not only the shape of the reservoir but also the reservoir depth and viscosity of the slip have a huge impact on the cast tape. Removable reservoirs have the advantage to be cleaned easily.

Doctor blade

Most commonly, doctor blades are made of stainless steel or hardened carbon steel. The casting surface essentially has to be ground flat and smooth. Also the doctor blades should be designed such that it can be disassembled for cleaning purposes. Doctor blades are mainly used for thick-film tapes, i.e. larger than 25 µm after drying. Therefore, the doctor blade gap or gap height is usually in the range of 100-1000 µm. In most laboratory operations, the blade height is adjustable and not fixed.

Adjustable doctor blade with micrometer screws on both ends.

Feeler gauges are a helpful tool to

Drying chamber

Process of tape casting

Slip delivery

After mixing the slip system, air can be trapped within the slip. To remove remaining air bubbles and promote smooth and homogeneous green tapes without defects, a de-airing step is required. Putting the slip under vacuum will help to remove air. It needs to be noted that too high vacuum tends to let evaporate solvent. This will unbalance the weight ratios of the slip and change its rheological behavior. Subsequent to de airing the slip will be poured into the reservoir of the machine. Additional sieves can be used to prevent e.g. milling balls from falling into the reservoir. Before starting to cast the slip is supposed to be distributed in the reservoir. Furthermore, the sedimentation behavior will have an effect. Also if the slip system is well-dispersed, sedimentation can take place after a certain amount if time. This will influence the starting point of the final tape and deteriorate the homogeneity of it.

Casting

The doctor-blade gap defines the wet thickness of the tape being cast. Either the substrate is stationary or the doctor-blade. The speed is supposed to be set in the range of 0.7 - 1 m/min. Feeler gauges check gap height.

Drying

Quality assessment

optical check, bubbles, orange peel, cracking, homogeneity, bendable, strechable, handable, homogeneous green sheet thickness, green density

References