Customization: | Available |
---|---|
After-sales Service: | One Year |
Warranty: | One Year |
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Selective Laser Melting (SLM) is an advanced additive manufacturing technology that uses a high-powered laser to selectively melt metal powder layers, building complex metal parts layer by layer. This technology is capable of producing parts with high precision and intricate geometries, making it an essential tool in industries such as aerospace, automotive, medical, and engineering. The ability to create complex structures with fine detail allows for innovation and customization that traditional manufacturing methods often cannot achieve.
SLM works with a variety of metal materials, including titanium, aluminum, stainless steel, and nickel alloys. The parts produced through SLM have excellent mechanical properties and high density, ensuring they meet the stringent requirements of critical applications. This versatility in materials and the high quality of the resulting parts make SLM a preferred method for manufacturing high-performance components.
Compared to traditional manufacturing methods, SLM significantly reduces material waste and shortens production cycles, offering greater design freedom. The process is ideal for rapid prototyping and small batch production, allowing for quicker iterations and time-to-market. With its efficiency, precision, and ability to produce complex designs, SLM represents a significant advancement in manufacturing technology, enabling industries to achieve new levels of performance and innovation.
SLM provides unparalleled design freedom, capable of producing complex shapes and internal structures that are difficult to create in other manufacturing processes. Therefore, SLM technology is widely used, and common application areas are not limited to but include:
SLM machines can produce parts with extremely high precision and intricate geometries. This capability allows for the creation of complex components that are often impossible to manufacture using traditional methods. The precision also ensures minimal post-processing and finishing work.
SLM uses only the necessary amount of material to create a part, significantly reducing waste compared to traditional subtractive manufacturing methods. The unused metal powder can often be recycled and reused, further enhancing material efficiency.
SLM provides unparalleled design flexibility, enabling the production of complex shapes, internal structures, and geometries that would be difficult or impossible to achieve with conventional manufacturing techniques. This freedom allows for more innovative and optimized designs.
Parts produced by SLM typically have high density and excellent mechanical properties. The resulting components can withstand high stress, heat, and other demanding conditions, making them suitable for critical applications in industries like aerospace, automotive, and medical.
SLM machines excel at producing highly customized and individualized parts. This is particularly beneficial in industries like medical and dental, where patient-specific implants and prosthetics can be created to match individual anatomical requirements.
SLM allows for quick turnaround times from design to finished product. This speed is valuable for rapid prototyping, enabling faster iterations and product development. It also supports small batch production, making it cost-effective for producing limited quantities of specialized parts.
The ability to produce parts directly from digital models without the need for molds or tooling significantly reduces lead times. This is advantageous in industries where time-to-market is critical, such as consumer electronics and high-tech sectors.
SLM can work with a wide range of metal materials, including titanium, aluminum, stainless steel, cobalt-chrome, and nickel alloys. This versatility makes it suitable for various applications across different industries.
By allowing for the design and manufacture of parts with complex internal structures, SLM can produce components that are both lightweight and high-performing. This is particularly important in aerospace and automotive applications where weight reduction is crucial for efficiency.
The efficiency and reduced waste of SLM processes contribute to more sustainable manufacturing practices. Additionally, the ability to create parts on-demand reduces the need for large inventories and associated storage costs, further supporting sustainable production strategies.
Item |
Specification |
Model | GS-M400 |
Laser Power |
500W |
Laser Type |
GS-MAX Fiber Laser |
Forming Size |
260mm x 400mm x 300mm |
Layer Thickness |
30-100 um |
Power Supply |
110-240 VAC, 50/60Hz, 8KW |
Supporting Materials |
Stainless steel, titanium alloy, cobalt chromium alloy, high temperature alloy, aluminum alloy, copper alloy, mold steel, pure titanium, etc |
Machine Size |
1172mm x 1840mm x 2270mm |
1. The main components of the equipment are guaranteedfor 1 year. If there are quality problems with the systemcomponents within the warranty period, the supplier willarrange engineers to guide the debugging.
2. During the equipment warranty period, the supplier is responsible for free replacement of parts for any damage or damage caused by the quality of the equipment itself. Optical fibers, lenses, gas nozzles, etc., and those that are responsible for user violations are excluded.
3. If there is any questions during the operation process, you can contact the our engineer for guidance.
Certification Details:
Relevant Directives and Standards:
Company Information:
Our technical files have been inspected, and the audit has been successfully completed. Our products comply with the following EU directives and standards, ensuring the safety and reliability of our products.
Certificate Verification: You can verify the validity of the certificate by visiting UDEM offical website. In accordance with the EU declaration, we commit to maintaining product quality and safety standards.
Ensuring the safety and integrity of laser cladding equipment during export is crucial. Here's a detailed description of the packaging and shipping process for exporting laser cladding equipment:
Packaging Requirements:
Protective Packaging:
Moisture and Dust Protection:
Securing Devices:
Labels and Markings:
Shipping Arrangements:
Choosing a Reliable Logistics Company:
Mode of Transportation:
Insurance:
Customs Procedures:
Tracking and Feedback:
By meticulously packaging and carefully planning the shipping process, the laser cladding equipment can be safely and intactly delivered to the customer, ensuring a satisfactory user experience.