I'm sure you want to know how watches are made, right? Don't worry, take your time and listen to Yamaichi Lubricants explain it to you. As mentioned above, the processing of a watch requires various machines, including machine tools. For example, a bracelet is a piece, leather may require a laser marking machine to produce part of the logo printing, and metal materials involve a series of processes such as cutting, grinding and polishing, without the need to produce parts such as watch hands, pushers, dials, etc. The following version uses a mechanical watch as an example to see what role machine tools play in this.

     Watch machining is not just a simple machine tool that can do the job, but often requires small precision combination machines for joint machining. The mechanical watch movement part of it is complex and the processes required are the most important, including steps such as drilling, tapping, chamfering, circular recesses, horizontal straight recesses, rolling recesses, rolling curved recesses, fixing end faces, cutting flat surfaces, drilling cross holes, etc. The smallest part of it is used to pick up the needle to be started and it is complex. The editor sees the creation of a world-famous table where each part is an individual shape, where the computer's machining process zooms in on the added parts and shows the various values to achieve the most perfect precision. The machined parts are then assembled by the main watch, and once assembled, the "movement" is presented to us in perfect working order.

     To produce a beautiful watch you need: computer gongs, precision punching machines, tabletop vertical milling machines, vertical projectors, multi-station milling machines.

Today, let Dongguan Yamaichi Lubricants explain to you. In machining, we see fluids being poured on the equipment onto the tool or workpiece, these fluids are called cutting fluids. What is the role of cutting fluids in this? Metal cutting fluids lubricate and cool workpieces and tools in precision machining, as well as preventing rust and cleaning. The role of cutting fluids depends not only on the various properties of the cutting fluid itself, but also on the machining requirements, workpiece materials, tool materials and machining methods. It should be considered in a comprehensive manner, chosen rationally and used correctly.

     Metal cutting fluids, also known as coolants, play a role in lubrication, cooling, chip removal, rust prevention and antibacterial effects during metal processing. At the same time, the proper choice of cutting fluid directly determines the degree of damage caused to the environment by production and processing. The choice of cutting fluid should not only depend on the surface quality and accuracy of the workpiece, but should also take into account factors such as the material of the workpiece and the type of tool and machining process. Tools and workpieces of different materials have different high temperature performance, cutting performance, hardness and other characteristics. Different cutting fluids should be selected at this point. For example, to prevent gear surface scratches, a high viscosity cutting fluid should be used to process workpieces with low hardness, while extreme pressure cutting oils or emulsifiers should be used to cut difficult-to-machine materials such as stainless steel. We can choose the physical and chemical properties of stable oil-based cutting fluid processing to expensive precision machining equipment has a good maintenance application, but also to prevent corrosion of metal parts, rust, moving parts moving part of the obstacle occurred.