Many machining shops face small-batch, customized orders where workpieces require multiple processes—such as cutting, trimming, and polishing—simultaneously. Due to limited equipment and incomplete process capabilities, they are often forced to turn down orders or outsource the work, resulting in squeezed profits, restricted business expansion, and an inability to accept one-stop precision machining orders.
In the processing of hardware components, aluminum profiles, stainless steel workpieces, and handicrafts, workpiece surfaces often exhibit sanding marks, tool marks, and a dull, rough finish after coarse grinding, failing to meet shipping standards. Conventional grinding equipment can only perform coarse grinding and is incapable of fine polishing. Companies are forced to purchase separate polishing machines, increasing equipment costs, yet the polishing results are inconsistent, leading to poor surface quality in finished products.
Most multifunctional machining equipment on the market relies on specialized, custom-made accessories, which lack versatility, are expensive, and are difficult to replace once damaged. Subsequent maintenance costs are extremely high. Modifying a standard motor to accommodate saw blades, grinding wheels, or polishing wheels requires disassembly and structural alterations, resulting in instability, poor safety, and unreliable precision.
1. For irregularly shaped workpieces, right-angle edges, grooved gaps, and the edges of profiles, standard handheld grinders are limited in the angles they can reach and produce uneven pressure. 2. This often results in large areas not being properly ground, residual burrs on edges and corners, and uncleaned blind spots, leading to low quality inspection pass rates and frequent rework and repairs.
Traditional grinding wheels use a hard grinding method. When polishing thin-walled metal parts, thin profiles, and soft aluminum, the excessive force and high friction can easily damage the base material, thin the workpiece, and cause surface dents and edge deformation. This results in an extremely high scrap rate for precision thin-walled parts, making it difficult to implement high-end thin-walled polishing processes.
Traditional standard motors have limited functionality and poor load-bearing capacity. They cannot withstand the high-load demands of alternating cutting, grinding, and polishing operations. Frequent process switching easily leads to overheating, stuttering, motor burnout, and speed loss, resulting in high equipment failure rates that fail to meet the demands of high-intensity, multi-process continuous production on assembly lines.
1. Conventional motors modified with pulleys to clamp saw blades suffer from poor concentricity and significant vibration during operation.
Our company has established a comprehensive global after-sales service system, offering end-to-end support ranging from pre-sales selection and technical assistance during the sales process to post-sales repairs and warranty coverage, thereby completely addressing our customers’ after-sales concerns. The specific after-sales services are as follows:
Our Three Phase Asynchronous Motors support customization for mainstream global voltages and frequencies, making them fully compatible with power grid standards in various countries and regions. Customers do not need to install additional transformers or variable frequency drives; the motors can be directly connected to the local power grid for immediate use. The core standard specifications and customization options are as follows: