{"id":13293,"date":"2024-02-26T18:31:44","date_gmt":"2024-02-26T18:31:44","guid":{"rendered":"https:\/\/metaletching.com\/?p=13293"},"modified":"2024-02-27T21:07:28","modified_gmt":"2024-02-27T21:07:28","slug":"manufacturing-shims-chemical-etching-or-laser-cutting","status":"publish","type":"post","link":"https:\/\/metaletching.com\/manufacturing-shims-chemical-etching-or-laser-cutting\/","title":{"rendered":"Manufacturing Shims: Chemical Etching or Laser Cutting?"},"content":{"rendered":"\n\n\t

Shims are essential in the aerospace, automotive, electronic, and medical industries. They are necessary for precision alignment, spacing, and calibration between two components. Precision is fundamental when manufacturing shims, as any deviation from the required specifications can cause system failure or malfunction. Due to the thinner materials, shims must be manufactured accurately and precisely.<\/p>\n

Advanced manufacturing techniques like chemical etching and laser cutting are good options for the production of metal shims. This blog post will explore these two manufacturing techniques and explain when laser cutting or chemical etching is best depending on part designs.<\/p>\n

\n\t\tChemical Etching Shims\n\t<\/h2>\n\t

\"photo<\/p>\n

Chemical Etching<\/a> is a subtractive manufacturing technique that uses a chemical solution to selectively etch away unwanted material from the surface of the metal sheet. <\/p>\n

A photoresist is applied to the metal sheet, and the design or pattern is exposed to the metal through a photolithographic process. The exposed metal areas are then selectively etched, leaving behind the desired shape or pattern of the shim.<\/p>\n

One of the significant benefits of photo chemical etching is that it can produce shims with high precision tolerances of up to +\/- 0.01mm. This level of precision enables manufacturers to create customized shims for specific applications. Moreover, since the etching process does not require tooling dies or expensive equipment, the lead time and cost for prototyping and production are considerably low.<\/p>\n

Manufacturing Shims<\/h2>\n

Several metal applications require shims with exceptionally smooth surface finishes that photo etching provides. Here are some examples:<\/p>\n

Optical instruments:<\/strong>\u00a0Precision optical components like mirrors, lenses, and prisms need shims with near-perfect surface finishes to minimize light scattering and ensure optimal performance. These shims are often made of highly polished stainless steel, aluminum, or even gold.<\/p>\n

Medical devices:<\/strong>\u00a0Surgical instruments, implants, and other medical devices often require shims with extremely smooth surfaces to minimize tissue irritation and ensure proper functionality. These types of shims are usually made of the following metals:<\/p>\n

Titanium is an excellent material option for implants, surgical instruments, and other essential components because it offers superior strength, corrosion resistance, and biocompatibility.\u00a0<\/p>\n

On the other hand, Nitinol is a nickel-titanium alloy that can deform under stress but return to its original shape because of its super elasticity. This makes it perfect for shims in dynamic applications like stents or joint replacements.<\/p>\n

Stainless steel is a cost-effective option that has good strength and corrosion resistance. It can be used for less demanding applications. Titanium is an excellent material option for implants, surgical instruments, and other important components because it offers superior strength, corrosion resistance, and biocompatibility.\u00a0<\/p>\n

Semiconductor packaging:<\/strong>\u00a0High-performance electronic components need precise shims to ensure proper thermal management and electrical contact. These shims are often made of copper, aluminum, or other highly conductive materials with smooth surfaces to minimize thermal resistance and electrical impedance.\u00a0<\/p>\n

Aerospace and defense applications:<\/strong> Critical components in aircraft, spacecraft, and military equipment often require shims with exceptional surface finishes to ensure high performance and reliability. These shims are typically made of high-strength materials like titanium, inconel, or beryllium, with surfaces polished to near-mirror quality.<\/p>\n

\n\t\tLaser Cutting Shims\n\t<\/h2>\n\t

\"Fiber<\/p>\n

Laser cutting<\/a>, also a subtractive manufacturing process, cuts sheet metal to the shape of the shim using a laser beam. A CAD file or vector image is imported into the laser cutting machine, which directs the laser beam onto the metal sheet.<\/p>\n

One of the advantages of fiber laser cutting is that it can cut through various materials, such as stainless steel and aluminum, with high precision and speed.<\/p>\n

The laser cutting process can produce shims with tolerances of up to +\/- 0.05mm. If a higher level of precision is required, laser cutting can be combined with other techniques, such as metal photo etching, to achieve the desired level of accuracy.<\/p>\n

Another benefit of laser cutting is that it eliminates the need for complex tooling setups, which makes it ideal for small production runs or prototyping.<\/p>\n

\n\t\tWhen to Use Chemical Etching or Laser Cutting for Shims\n\t<\/h2>\n\t

The decision to use chemical etching or laser cutting depends on various factors, such as the shim’s thickness, the design’s complexity, and the industry’s application.<\/p>\n

For example, metal etching is preferred for manufacturing shims with high precision tolerances, as it can produce complex designs with micro features without compromising accuracy.\u00a0<\/p>\n

Example:\u00a0<\/p>\n

Tiny shims:<\/strong><\/p>\n