Effect of laser power and wavelength

laser power

• Sintering capacity correlationLaser power is a key parameter for SLS wax 3D printers and directly determines the effectiveness and efficiency of the wax sintering process. Higher laser power allows the wax particles to melt and bond together faster, making it possible to quickly build larger or thicker structures. For example, in the manufacture of wax molds for large industrial parts, sufficient laser power ensures that the wax powder is fully sintered in a short period of time, increasing the printing speed. However, if the laser power is too high, this may lead to overburning of the surface of the wax mold, e.g. scorching, deformation, etc., which affects the quality and subsequent use of the wax mold. On the other hand, too low a laser power may not allow the wax powder to melt completely, resulting in a weak sintering and a loose structure of the wax mold, or even damage during subsequent handling or processing.
• Adaptation to different materials: Different types of wax materials have different requirements for laser power due to their different physical properties such as melting point and thermal conductivity. For wax powder with high melting point and relatively hard texture, higher laser power is often needed to realize good sintering; while wax powder with lower melting point and easier melting can use relatively low laser power. Therefore, the selection of wax powder materials needs to be considered in conjunction with the laser power range of the printer in order to achieve the best sintering results.

laser wavelength

• Material Absorption Properties: The wavelength of the laser also plays an important role in the printing process by influencing the degree of absorption of the laser energy by the wax material. Different wax materials have different absorption efficiencies at specific wavelengths. For example, some wax materials may absorb laser energy better at wavelengths in the near infrared (NIR) region, and under the irradiation of the laser at this wavelength, the laser energy can be efficiently converted into thermal energy, resulting in a good sintering. If the laser wavelength does not match the absorption characteristics of the wax powder material, even if the laser power is sufficient, it is difficult for the wax powder to fully absorb the energy for melting and sintering, which can lead to printing failure or poor quality of the printed wax model.
• Application Scenario Differences: In practical application, according to different use scenarios and requirements on wax mold performance, sometimes it is also necessary to choose a suitable wavelength of laser. For example, in the printing of jewelry wax molds, which requires high precision and high surface quality, a specific wavelength of laser may be selected, which can make the wax powder sintered finely and uniformly, and reduce the surface defects due to uneven energy absorption; while in some industrial wax molds manufacturing scenarios, which require lower precision and pay more attention to productivity, the laser may be selected according to the common wavelengths of the wax powder material, which are generally suitable for the wax powder to achieve fast and stable printing. realize fast and stable printing.

Print Layer Thickness and Accuracy Analysis

print layer thickness

• Impact on model refinement: The print layer thickness is the thickness of the wax mold layer that is formed when each layer of wax powder is sintered during the SLS printing process. Smaller layer thicknesses result in finer details and smoother surfaces. For example, when printing wax models of artistic sculptures with fine textures or intricate jewelry wax models, a layer thickness of a few tens of microns can clearly reproduce details such as tiny grain lines and thin-walled structures in the design model. On the contrary, a larger layer thickness can speed up the printing speed, but it will lead to obvious stepped textures on the surface of the wax model, reducing the fineness of the model, which is not suitable for some products with high demands on appearance and precision.
• Trade-offs with print speed: There is often a trade-off between accuracy and speed when choosing a layer thickness for printing. Thinner layer thicknesses mean that more layers are needed to build the entire wax mold and print times increase significantly, while thicker layer thicknesses reduce the number of layers and speed up the process, but at the expense of some accuracy. In actual production, the layer thickness should be determined according to the specific product requirements and the urgency of the production task. For example, for mass-produced industrial molds that do not require particularly high precision, the layer thickness can be increased to improve production efficiency; while for customized, high-value fine wax molds, a smaller layer thickness is preferred to ensure quality.

Precision Analysis

• Dimensional accuracyDimensional accuracy is a function of how well the printed wax model matches the design model in terms of size, and is affected by a number of factors including the accuracy of the laser scanning system, the positioning accuracy of the mechanical moving parts, and the shrinkage of the wax powder material during the sintering process. High precision printers are able to control the dimensional error within a very small range, which is crucial for wax molds that need to be precisely matched with other parts, such as wax molds for precision casting and wax molds for dental restorations, or else the cast metal parts may not be able to be mounted properly or the medical restorations may not be effective.
• Shape AccuracyShape accuracy is related to the ability of the wax model to accurately reproduce the complex shapes and geometrical structures of the design model. Since SLS constructs wax molds by layer-by-layer sintering, it is easy to have accuracy problems in some parts with special shapes such as overhanging parts, thin walls, inner corners, etc. For example, the overhanging parts may need to be supported, and if the support design is not reasonable or not handled correctly after removing the support, the shape accuracy of the part may be affected. In addition, the planning of the laser scanning path and the uniformity of the wax powder will also affect the shape accuracy. Ensuring a good shape accuracy will ensure that the wax model meets the expected function and appearance requirements in the subsequent applications.

Temperature control for building platforms

Initial temperature setting

• Wax powder spreading uniformityThe initial temperature of the construction platform has an important influence on the uniformity of the spreading of the wax powder on the platform. A suitable initial temperature enables the wax powder to spread better during the laying process and avoids localized piles or vacancies. For example, when the platform temperature is slightly higher than the fluidity temperature of the wax powder at room temperature, the wax powder can be evenly spread on the platform like fine sand, providing a good starting condition for subsequent laser sintering. If the platform temperature is too low, the wax powder may not be able to spread out smoothly, resulting in uneven thickness of each layer of wax powder, which in turn affects the quality of the whole wax mold; whereas too high a platform temperature may cause the wax powder to be partially melted and sticking before it is spread out, which likewise destroys the molding effect of the wax mold.
• Quality of the first sintered layer: The initial temperature also affects the sintering quality of the first wax mold layer. A suitable platform temperature helps the wax powder to bond better with the platform under laser irradiation and improves the firmness of the first layer, so that it can provide a stable foundation for the construction of subsequent layers. Different wax materials have different optimal initial platform temperatures, which need to be set accurately according to the properties of the wax powder used to ensure a good sintering of the first layer and to prevent separation of the first layer from the platform or incomplete sintering.

temperature stability

• Printing Process Impact: The temperature stability of the build platform is crucial during the whole wax mold printing process. Large fluctuations in temperature can lead to changes in the physical properties of the wax powder (e.g. fluidity, sintering characteristics, etc.), which in turn affects the bonding effect between the layers of the wax mold and the structural stability of the overall wax mold. For example, a sudden increase in temperature may cause excessive melting of the wax powder being sintered, destroying the structure of the existing wax mold; a decrease in temperature may cause insufficient sintering of the subsequent wax powder, resulting in quality problems such as delamination and cracking. Therefore, printers are usually equipped with a high precision temperature control system that monitors and regulates the platform temperature in real time to keep it within a set stable range, ensuring high quality sintering from the first to the last layer of the wax mold.
• Requirements for different wax mold typesThe requirements for temperature stability of the platform vary for different types and sizes of wax molds. For large, thick-walled wax molds, due to the longer printing time, the cumulative effect of temperature changes is greater, and stricter temperature control is needed to ensure uniform sintering of the internal and external wax structure; while small, thin-walled wax molds, although the printing time is relatively shorter, due to the fragility of their structure, they are more sensitive to temperature fluctuations, and they also need a stable platform temperature environment to ensure the quality of wax molds to avoid deformation, damage, etc. caused by temperature changes. The temperature environment should be stabilized to ensure the quality and to avoid the deformation and damage of the wax molds due to temperature change.

In summary, the key technical parameters of laser power and wavelength, print layer thickness and accuracy, and temperature control of the build platform interact with each other to determine the print performance and mold quality of SLS wax 3D printers, and require in-depth understanding and consideration when using and evaluating these printers.

了解SLS蠟?zāi)?D打印機(jī)的關(guān)鍵技術(shù)參數(shù)最先出現(xiàn)在三帝科技股份有限公司。

I. Define your own needs

Before embarking on a purchase, be sure to clearly sort out your usage needs. For example, determine which field you will mainly use it in, whether it is jewelry making, industrial parts manufacturing or medical model production, etc. Different fields have different requirements on the accuracy, size and material properties of wax models. At the same time, to estimate the approximate amount of printing, is occasionally a small amount of printing for prototyping, or the need for batch, large-scale production, which will affect the printer printing speed, build size and other aspects of the choice, in order to circle the printer type and the general parameters of the range of needs, to avoid blind selection.

Second, understand the printer performance parameters

1. Printing Accuracy: Focus on the minimum layer thickness and the overall dimensional accuracy of the equipment. For example, the production of fine jewelry wax models may require printers with small layer thicknesses (tens of microns) to ensure that textures and other details are clearly presented; while for some industrial functional wax models, the dimensional accuracy needs to be strictly in line with the design requirements to prevent subsequent casting and other processes from having fitment problems.
2. Printing speed: Examine the volume of molding per unit of time and the performance of print speeds for models of varying complexity. If there are mass production tasks, faster printing speed can improve efficiency and shorten the production cycle, but also note that some printers may plummet in speed when handling complex models, which needs to be weighed in the balance.
3. Build Size: Define the maximum size of wax model that can be printed by the printer, and choose it in relation to the size of wax models that are often made in actual business. At the same time, understand the utilization efficiency of the effective printing area to avoid the situation that the nominal size is large but the actual available space is limited, which affects the printing of special shape wax models.
4. Wax Powder Material Compatibility: Check the supported wax powders to make sure that they are suitable for the material you plan to use, especially those with special performance requirements (e.g. high temperature resistance, high strength, etc.). In addition, the convenience of the material changeover is also important for the efficiency of the subsequent use. If the material has to be changed frequently, a cumbersome changeover process will waste a lot of time.

III. How to avoid common buying traps

1. Be wary of over-promotion: Some manufacturers may exaggerate the performance parameters of their printers, such as claiming ultra-high precision that is difficult to achieve in actual use, or boasting extremely fast print speeds without stating that it is under a specific simple model. To carefully check the actual technical specifications in the product manual, and as far as possible to request a live demonstration or view the actual print samples to verify the authenticity of the promotional content.
2. Avoid the temptation of low pricesWax 3D printers that are priced too low often have shortcomings in terms of quality, performance or after-sales service. Do not simply be attracted by the low price, but comprehensively compare the configuration, functions, reputation, etc. of products at different price points to analyze their cost-effectiveness and prevent buying equipment that seems cheap but has frequent problems in subsequent use and high maintenance costs.
3. Look for hidden clauses: When signing the purchase contract and other documents, read the terms and conditions carefully and pay attention to whether there are any hidden fee clauses (e.g. charges for software upgrades at a later stage, high-priced charges for the replacement of certain key accessories, etc.) or ambiguous expressions of key after-sale contents such as the scope of the warranty of the equipment and the time, so as to avoid any unnecessary disputes and additional expenses in the subsequent period.

IV. Ensuring the quality of after-sales service

1. Technical support responsivenessUnderstand the technical support channels provided by the manufacturer, such as whether there is a 24-hour customer service hotline, online technical support platform, etc., and ask about its average response time. When problems are encountered in the process of use, it is crucial to get professional technical guidance to solve the problems and resume production in a timely manner.
2. Repair service and spare parts supply: Examine the manufacturer's maintenance service network coverage, can arrange timely maintenance personnel to repair (especially for large, heavy industrial-grade printers this is very critical). At the same time, to confirm whether the supply of original spare parts is sufficient, timely, to avoid equipment failure due to waiting for parts and long downtime, in addition, to understand in advance the approximate costing of maintenance costs, to ensure that the cost of maintenance in the later acceptable range.
3. Training services: For first-time users, good training services can help operators quickly familiarize themselves with the operation and maintenance of the equipment. Ask the manufacturer whether to provide free operation training, training content is comprehensive (covering the use of software, routine maintenance, simple troubleshooting, etc.), to ensure that the equipment can be put into use smoothly after arrival.

V. Importance of user evaluation

1. Multi-channel collectionThe user reviews of related products can be searched through the Internet, such as professional 3D printing forums, e-commerce platform buyer reviews, industry exchange groups, etc. Different channels can obtain more comprehensive and objective feedback. Different channels can obtain more comprehensive and objective feedback, from the printing effect, stability to after-sales service and other aspects, to understand the real experience of other actual users in the process of use. Of course, every product is not perfect, from the many brands to choose a better is our purpose.
2. Focus on content: Focus on the frequency of equipment failure, printing accuracy is stable, after-sales service to solve the problem of the actual effect and other key elements of the evaluation. For example, if more than one user feedback on a printer often appear a variety of faults and can not be used, it is necessary to carefully consider the purchase of this product; if the general praise of the manufacturer's after-sales maintenance in a timely manner, a good attitude, then the after-sales aspects of the relative more secure.
3. Compare different brands and models: Compare and analyze the collected user reviews of different brands and models of 3D printers to find out the products with better reputation and high comprehensive satisfaction in all aspects, which will help narrow down the choices and make more appropriate purchase decisions. If necessary, you can personally visit the supplier in the factory, after all, large wax model 3D printer are not cheap, personal communication can learn a lot of useful information. Face-to-face communication is important, and for really strong brands they are happy for you to visit them in person.

In conclusion, when buying a wax 3D printer for the first time, it is important to do your homework, consider all factors, and make a careful choice in order to get a device that meets your needs and saves you money in subsequent use.

初次購買蠟?zāi)?D打印機(jī)需要注意哪些事項(xiàng)？最先出現(xiàn)在三帝科技股份有限公司。