Is CAD still relevant in the manufacturing industry?
When computer-aided design (CAD) software first came onto the market, it revolutionised the way manufacturers designed their products. Indeed, for many, these tools continue to be a key part of the product development process.To get more news about 2D cad software, you can visit shine news official website.
However, the advanced capabilities of Industry 4.0 technologies have led some experts to speculate that product designers may replace CAD software. This article will consider if this is the case or not and look at the benefits of CAD libraries.
What is the history of CAD?
The first type of CAD technology was used by researcher Douglas T. Ross at the Massachusetts Institute of Technology (MIT) in the early 1950s as part of his investigations into military radar and computer display technology. However, it wasn’t until Dr Patrick Hanratty started to develop these interactive graphics systems in the General Motors Research Laboratories that ‘Designs Automated by Computer’ started to be used in industry.
After launching ICS in 1970, Hanratty developed his tool further to create Automated Drafting and Machinery (ADAM), a product which is at the base of most modern design drafting. The introduction of affordable desktop computers in the 1980s and the launch of Autodesk software saw CAD technologies enter the mainstream, as did the move towards PCs in the 1990s.
Since this time, a huge range of CAD software has been developed and made available to the mass market, enabling a range of industries and manufacturers to take advantage of its capabilities.
How is CAD used in product development?
CAD is used by engineers and designers in manufacturing businesses to develop 2D and 3D product designs for the purposes of visualisation and digital testing. Compared to manual technical drawing, CAD enables these designers to create, iterate and optimise their designs more quickly and easily.
This is particularly the case thanks to the introduction of CAD libraries, which are free or paid-for 2D or 3D designs of specific components or elements that can then be imported by engineers into their design. The software then matches the measurements, scale and details of these parts to the rest of the design, meaning all engineers need to do is make sure it looks good and functions correctly in the right part of the design.
Plus, with the introduction of cloud storage into CAD software tools, designers are able to access and work on their product designs anywhere, making collaboration and decision making easier, even if the team is working in different areas of the world. In short, CAD is used to create, iterate and develop product designs in 2D or 3D so they can be as accurate and optimised as possible before heading into the prototyping or production stages.
Why are CAD libraries useful?
CAD libraries are a collection of free or paid-for 2D or 3D CAD design files. Indeed, the best libraries offer their designs in a variety of 2D and 3D formats to match the needs of whichever CAD software design engineers use.
Plus, CAD libraries provided by components and parts manufacturers make the sourcing and creating of BOM for these elements much easier by testing and analysing them directly in the software. This means design engineers can find the highest quality and most accurate parts without having to order samples or test any physical prototypes.
Are there challenges with CAD?
Although CAD software has brought plenty of advantages to designers and manufacturers, there have been some challenges with the technology and the changes it has made to the product development process.
One of the main changes that CAD software has made to designers is in their required skillset. In addition to being trained in technical drawing, they also need to understand how to use the software effectively. Each type of CAD software is slightly different, so knowing how to access each programme’s full capabilities is a skill.
Similarly, although one of the strengths of CAD is the fact that you can create multiple versions of the same design easily, it does also mean that you end up with a huge amount of file iterations. This can be hard to keep track of or it can cause disruption if your files get corrupted or your storage is too limited to handle the large CAD design documents.
CAD software itself also requires plenty of processing power to run. Plus, to ensure it runs effectively, you need to have the latest software updates. This means designers and manufacturing teams need to have highly powered (which often means expensive) PCs and desktops to work efficiently.
