Are you accustomed to additive and subtractive production concepts? Subtractive methods entail getting rid of materials to achieve the desired shape, whereas additive methods construct the shape from product layers. Right here, 3D printing and compression molding are two additive manufacturing techniques. However, there are several essential differences between 3D printing and compression Molding.
The distinction is primarily in production speed, efficiency, style adaptability, precision, and applications. In addition, we will certainly analyze the subtleties of these two approaches with their comparison in this short article.
What Is 3D Printing?
It is an additive manufacturing technology that develops precise and elaborate functional components or products by piling and integrating succeeding layers of material. So, a 3D printer does not use a product block to manipulate the form. Instead, the nozzle deposits product layer by layer from the bottom up in the print bed according to the piece pattern of the uploaded style.
On the other hand, a piece pattern describes the horizontal layers into which a CAD design is divided. Each piece represents a cross-sectional area of the version the printer complies with to transfer the product layer.
Furthermore, you might require clarification with numerous 3D printing innovations. They comply with the same basic concept. Nonetheless, they have distinctions in their working device, product compatibility, and printing capacities. Here are the typical types of 3D Printing in modern technologies.
Type | Materials | Description/Working | Pros | Cons |
FDM (Fused Deposition Modeling) | Thermoplastics (ABS, PLA, Nylon) | It melts and extrudes the material filament layer by layer to achieve the final shape. | Structural stability, low cost, various materials | Rougher finish and moderate precision |
SLA (Stereolithography) | Photopolymer Resin | SLA employs an ultraviolet laser to cure photopolymer resin in a tank, creating layers. | High precision, smooth finishes, and creates detailed models and prototypes. | Limited material choice |
SLS (Selective Laser Sintering) | Polymer Powder(Nylon PA 12, glass-filled Nylon | A laser beam sinters material powder in a chamber, often with inert gas to prevent oxidation. | Complex geometries possible | Longer lead times and rough surface texture |
DMLS (Direct Metal Laser Sintering) | Metal Powder (various alloys, aluminum, copper, nickel ) | DMLA fuses metal powder particles layer by layer with a laser. | Prints intricate and robust metal parts. | High cost and limited material choices. |
Advantages of 3D Printing
3D printing production is helpful for several applications. It gives layout adaptability, faster lead times, personalization, etc. Right here is the discussion of common 3D printing advantages;
Design Flexibility and Complexity
If we compare the layout’s possible details with compression molding and 3D Printing, a 3D printer produces extremely intricate geometries and contours. It additionally supplies more intricacy than standard techniques like CNC lathe machining or shot molding. It does not limit detailed hollow sections, damages, and internal latticeworks as subtractive production does.
3d printing warm exchanger with complicated forms
Moreover, the complex forms’ capacity directly benefits the developers. They can make more ingenious and detailed layouts to resolve production demands. Furthermore, developers do not have to consider draft angles, device accessibility, thickness uniformity, huge assemblies, and other constraints while making 3D printing layouts. So, it causes utmost design adaptability.
Rapid Prototyping
The manufacturing rate, precision, and cost-effectiveness make 3D publishing a trustworthy choice for fast prototyping projects. The moment could take a couple of minutes to several hours for a component, depending on the intricacy and 3D printed materials. Additionally, prices are reduced with 3D printing prototyping due to zero advanced tooling expense and an easy design-changing process.
For example, you can rapidly prototype and test a new drone style with required adjustments on the fly with 3D printing iterations. At the same time, it might take months to use various other methods.
Customization and Personalization
The 3D printing processes involve straight manufacturing from electronic documents, and they can handle intricate designs. Because of this, 3D Printing enables custom-made components and products to be made according to particular demands. With a customized layout (3D Model), you can make it into a physical reality with suitable materials and printing equipment.
This modification is extensively advantageous for clinical applications. For example, 3D Printing can produce custom-fit-implants for individuals.
Cost-Effectiveness for Small-Batch Production
The major reason 3D-printed components are inexpensive in small-batch manufacturing is that they do not require costly manufacturing setups like molds or tooling. At the same time, various other methods like shot molding require hefty upfront financial investments in molds and mildew, which leads to higher per-part casts for a little set or low-volume manufacturing.
As an example, small-batch manufacturing for Nylon components first requires a lightweight aluminum shot mold and mildew that costs a minimum of $10 0 00, while there is no such price for 3D Printing.
Limitations of 3D Printing
Although 3D Printing has many advantages, it has some drawbacks, such as product choice, dimension, accuracy, and surface area finish. Let’s discuss each disadvantage independently.
Material Limitations
The material selection is smaller for 3D Printing than for other processes like CNC machining. There are also fewer choices in 3D Printing vs. compression molding. The 3D printing presses are typically compatible with plastics (ABS, PETG, and TPU), photopolymers, and some thermoset products and metals (steel, titanium, and lightweight aluminum).
However, 3D Printing has rapidly broadened its product capacities beyond standard thermoplastics. Because of product science technologies and new 3D printing technologies, more and more materials are becoming compatible.
Lower Strength and Durability
As 3D printers transform the style by adding product layers, the final part endangers mechanical stamina. For example, FDM components delaminate or underperform under tensions on specific orientations (the Z-axis, usually). Furthermore, components could lose their initial properties like solidity or exhaustion strength. These factors also make the parts less resilient.
Surface Finish and Precision
The parts from 3D Printing leave noticeable layer marks and sometimes some support material residue. So, it calls for post-processing, such as sandblasting, deburring, or machining. The Ra value for 3D printing components can be as low as 4 µm (approx.).
Next, it is likewise less precise than other prominent production technologies. 3D printing normally provides a precision of ± 0.2 mm, while CNC can attain ± 0.005 mm and ~ ± 0.025 for compression molded rubber components.
Size Limitations
3D Printing has component dimension limitations compared to other procedures like injection molding or laser cutting. The dimension capability is restricted by the construct quantity and bed size (print chamber) of the 3D printer machines. For instance, 3d Printing can develop lengthy wind generator blades due to dimension restrictions. Nonetheless, huge parts are possible by putting together tiny, specific 3D-printed pieces.
What’s Compression Molding?
A specific polymer molding procedure produces the wanted form by pressing the product in a closed mold. This production approach is prominent for thermoset composites with premium properties.
big range compression molding setup
The compression molding procedure demands a multi-cavity compression mold that exacts the unfavorable geometry of the preferred shape. On the other hand, the mold and mildew contain two halves (dealt with lower and movable top halves). Initially, a pre-calculated amount of product is placed inside the warmed mold tooth cavity, followed by heating and pressing the mold at home. Compression, mol,d, and mildew heating force the product to stream via the dental caries and fill it.
Establishing the appropriate pressure, temperature rate, and curing time is crucial during compression. Next, the mold and mildew opening discloses the strengthened component after cooling.
Advantages of Compression Molding
The adhering is a well-recognized advantage of compression molding across different manufacturing applications.
High Volume Production Efficiency
Production quantity is the most critical advantage, especially when comparing compression molding and 3D Printing. Once you make the mold and mildew, you can reuse it to create identical components in high volumes, as many as several cycles. Nevertheless, the life of a mold depends upon mold material, fee abrasiveness, and various other factors.
This high-volume manufacturing performance will significantly reduce the cost per part in the future. On the other hand, there is no per-part cost reduction with 3D printing mass production.
Excellent Part Strength and Durability
Unlike a layer-by-layer framework, built parts include portable and squeezed architectural kinds. So, compression molding uses excellent part toughness. Subsequently, there is a low opportunity for void development, adding to the exceptional architectural stability of components.
According to relevant research, the toughness, hardness, tensile stamina, and elasticity of compression-molded examples were more than 3d printed parts throughout testing.
Good Surface Finish
This molding method mold and mildews eliminate an excellent surface area finish. This is because the compression adheres material carefully to the mold surfaces. Adhere very closely to the mold and mildew surfaces. It can attain Ra worths from as low as 0.1 micrometers ( µm) with highly sleek mold, mildews, and ideal handling conditions. On the other hand, the surface finish of the dental caries wall surface is critical for the smooth surface of compression molding parts.
Suitability for Large Parts
The attainable dimension of removing compression molding relies on the mold dimension. So, you can develop the majority by designing an appropriate mold and utilizing high-compression tonnage. For example, aircraft wing skin is feasible with centimeters.
Consequently, instead of utilizing shot techniques, pre-placing the fee material in the mold promotes large-sized molding. The reason is that compression allows the product to be dispersed uniformly across a huge mold cavity without the limitations enforced by the circulation and pressure demands.
Limitations of Compression Molding
Although compression molding uses various advantages, it has restrictions in style adaptability, tooling expense, production time, and tight accuracy. Recognizing this constraint can assist you in preventing possible issues in the last molded parts and making better choices. Below is the summary of each constraint;
Limited Design Complexity
Compression molding is preferable for huge and relatively simple designs. Here, minimal design adaptability is generally because of product circulation patterns in complex mold dental caries of compression mold. If the layouts have complicated attributes like extremely slanted angles and small details on edges, the material circulation falls short of loading those dental caries accurately.
Additionally, material circulation restriction might trap compressed air, creating void formation. On the other hand, developers have extensive freedom with 3D Printing.
Higher Tooling Costs
The tooling cost of 3D Printing is significantly higher than that of compression molding, mold, and mildew tooling. This is due to the high ahead-of-time expense of mold and other complementary tooling. In addition, minor layout adjustments call for significant financial investment in mold again. Conversely, 3D Printing does not entail such costly tooling prices.
Longer Cycle Times
The compression molding procedure typically has a much longer cycle, also for compression molding vs shot molding. It includes pre-heating mold and cost, pre-loading of cost, and reasonably much longer curing time, all contributing to the higher production time. Consequently, the flash and burrs elimination procedure from the shaped surface area after production additionally builds up the time.
Quality and Precision Issues
Finally, plastic compression molding struggles to attain high precision and top quality like other sophisticated production strategies. This is preliminary because it produces much less consistent product flow than other molding techniques. Next, other high-quality problems could be contraction and warpage, given that all thermoset and thermoplastic products diminish somewhat throughout air conditioning.
Regarding accuracy, the compression molding tolerance usually ranges from ± 0.127 to ± 0.508 mm. The tolerance varies based on mold tooth cavity surface quality, procedure specifications, and the residential or commercial properties of the fee product.
Differences Between 3D Printing and Compression Molding
After comprehending the advantages and disadvantages of 3d printing and compression molding, let’s review a head-to-head contrast of these processes on various aspects.
Material Selection
Product option is the structure for the last residential or commercial properties and capability of the previous part, regardless of manufacturing approach. So, having many more worldly choices implies more opportunities to obtain the material that precisely resolves your needs.
Material Type | 3D Printing Materials | Compression Molding Materials |
Thermosetting Plastics | Almost No. In very few specialized scenarios | Epoxy, Phenolic, Polyester, Vinyl ester, Melamine |
Thermoplastics | ABS, PLA, PETG, TPU, Nylon, PEEK, PC | Polyethylene (PE), Polypropylene (PP), Nylon (Polyamide), Polycarbonate (PC), Acetal (POM) |
Composite Materials | Carbon Fiber Reinforced PLA, Glass Fiber Reinforced Nylon, Wood-Filled PLA, Metal-Filled PLA, Kevlar-Filled Nylon | Glass Fiber Reinforced Plastic (GFRP), Carbon Fiber Reinforced Plastic (CFRP), Sheet Molding Compound (SMC), Bulk Molding Compound (BMC), Fiber-Reinforced Thermoset |
Metals | Titanium, Aluminum, Inconel, Copper, Gold, Silver | In very few scenarios |
You can find more material options for 3D Printing than compression molding. However, you need to consider cost, your requirements, design specification, and the intended use of final parts while comparing materials compatible with both methods.
Cost Comparison for Different Production Scales
The expense of 3D Printing vs compression molding dramatically depends on the production volume. The high mold and mildew cost in compression molding make it less costly as the manufacturing volume boosts. At the same time, 3D Printing does not substantially reduce manufacturing costs compared to large-scale manufacturing.
Production Scale | 3D Printing | Compression Molding |
Prototyping | Low cost (No molds required) | High cost (Molds required) |
Small-batch | Moderate cost | High cost due to initial mold investment |
Medium-Volume | High cost due to slower production speed | Moderate cost (Amortization of mold cost) |
High Volume | High-cost | Low cost |
Next, the costs increase in compression molding with intricacies as it requires a more complex mold and reduces the cycle time. In contrast, the cost might not increase with complex 3D printing designs. Since material usage has a large share of overall cost, the cost can be decreased if complex parts need less material volume for 3D Printing.
Speed and Efficiency in Production
3D Printing is a much less rapid process than molding, except for the prototyping tasks. Compression molding takes far more time in prototyping due to mold-making and tooling arrangements. However, compression molding equipment promptly goes for the following cycle after cooling the mold and mildew. So, the compression molding rate is restricted in prototyping and small-batch production.
Subsequently, the effectiveness of 3D Printing reduces as manufacturing volume increases. Nevertheless, it is very effective for generating complicated elements without additional expenses. On the other hand, compression molding masters scalability. It can produce thousands to millions of regular systems at a relatively inexpensive.
Quality and Durability of Finished Products
First, we will undoubtedly compare the quality of compression molding and 3D Printing. The structurally high quality of molding components is more than that of 3D-printed ones. It is all due to their development procedure. The layer-building approach of a 3D printer reduces the structural strength of the part, while pressure during compression molding makes the parts structurally undamaged. Subsequently, the finish high quality of the printed surface differs by the printing method. For instance, FDM prints show layer lines and require further ending up, and the run-down neighborhood method generates smoother surface areas. At the same time, compression molding gives a constant and softer surface.
Furthermore, which ones are the more resilient? The response is compression-molded ones. It is due to product harmony and the impacts of heat and pressure throughout curing. On the other hand, split frameworks present vulnerabilities in the 3D printing product.
Design Flexibility
As previously pointed out, 3D Printing uses more design flexibility than compression molding. Mold and mildew production is an intricate process; usually, machining does not sustain the designs with intricate internal geometries. At the same time, 3D Printing does not have any restrictions.
Here is the listing of functions 3D Printing can fit, yet not by compression molding.
Facility undercuts.
Deep and small pockets.
Parts with extremely variable wall thickness.
Complex surface area patterns.
Sharp sides, and so on.
Suitability for Various Industries and Applications
Because compression molding can mold rubbers and elastomers right into solid and resilient elastic components, seals and gaskets are the two most common applications. On the other hand, 3D Printing is highly appropriate for prototyping and custom production.
Industry/Application | 3D Printing Examples | Compression Molding Examples |
Aerospace | Fuel nozzles for jet engines, brackets for satellite components, drone parts, and various prototyping. | Less popular, selling for aircraft |
Automotive | Cooling ducts, customized dashboard components, body part prototyping, and interior components | Gaskets and seals, rubber hoses and belts, and vibration-dampening components. |
Healthcare | Custom surgical models, dental crowns & bridges, custom prosthetic limbs, etc. | Components for durable medical equipment, seals for laboratory containers, silicone masks, and more. |
Consumer Products | Smartphone cases, custom-fit footwear, toys, and more. | Watch casings and non-slip grips for tools and sports equipment, airtight food storage containers |
Electronics | Custom enclosures, various prototyping | Buttons and keypads for remote controls, durable outdoor lighting components, insulating housings for connectors |
How to Make the Right Choice Between Compression Molding and 3D Printing?
Several factors must be considered when determining which approaches match your requirements for 3D Printing and compression molding. The decision generally relies on the production quantity, style intricacy, component dimension, and cost. For example, 3D print production is appropriate for small-size custom-made parts manufactured in reduced quantities. On the other hand, compression molding masters create large-size components in greater volume.
However, it is recommended that you speak with sector leaders like JuSheng before deciding on 3D Printing vs. compression molding. We are at the forefront of on-demand production solutions, including plastic molding and 3D Printing. Our sophisticated molding and 3D printing manufacturing centers permit our engineers to handle your one-of-a-kind tasks.
100+ product alternatives.
Quick prototyping for diverse industry applications.
Rapid preparation.
Specific yet budget-friendly services.
Do not hesitate to begin your job today!