When to Use low Volume Manufacturing Service?

30 Sep.,2024

 

High Volume vs Low Volume Manufacturing | RCO Engineering

Check now

 

When it comes to manufacturing, there are two main types: low volume and high volume. Low volume manufacturers service smaller projects, while high volume manufacturers service larger projects that offer cost savings with economies of scale.

 

However, not all businesses are the same, and many may be debating low volume vs. high volume manufacturing. In this blog post, we will discuss the pros and cons of high volume vs low volume manufacturing so you can make the best decision for your business.

 

What is Low Volume Manufacturing (LMV)?

 

Before comparing high volume vs low volume manufacturing, we need to understand the definition of each. Low volume manufacturing is the process of manufacturing products in small quantities. This type of manufacturing is typically used for prototypes, custom products, or limited-edition runs.

 

Low volume manufacturers generally have shorter lead times and can be more flexible with design changes than their high volume counterparts.

 

What are the Pros of Low Volume Manufacturing?

 

There are several benefits to low volume manufacturing, including:

  • Lower minimum order quantities
  • Lower overhead costs
  • Less material waste
  • Greater flexibility with design changes

Low volume manufacturing is typically a more cost-effective option for small businesses or businesses that are introducing a new product to the market. When comparing high volume vs low volume manufacturing, you need to consider the variety of products needed. Low volume high variety production is possible, giving more flexibility in meeting consumer demands.

 

What are the Cons of Low Volume Manufacturing?

 

Despite the many benefits of low-volume manufacturing, there are a few potential drawbacks, including:

  • Higher unit costs
  • Longer lead times
  • Limited production capacity

If you need a large number of products quickly, low-volume manufacturing may not be the best option. However, if you're looking for a more cost-effective solution for a small batch of products, low-volume manufacturing could be the perfect fit.

 

What is High Volume Manufacturing?

 

High volume manufacturing is the opposite of low volume manufacturing &#; it's used to mass produce products quickly and efficiently. High volume manufacturing is often used for products that have high demand, such as electronics or car parts.

 

What are the Pros of High Volume Manufacturing?

 

The biggest advantage of high-volume manufacturing is that it's fast. If you need a large number of products quickly, this is the best way to get them. High volume manufacturing is also very efficient, so you'll save on production costs.

 

Pros of high volume manufacturing include:

  • Quick turnaround time
  • Cost-effective for large orders
  • Allows manufacturers to stay ahead of the competition

What are the Cons of High Volume Manufacturing?

 

The downside of high-volume manufacturing is that it can be inflexible. If you need to make changes to your product, it can be difficult and expensive to do so. You'll also have less control over the quality of your products, as each one is identical.

 

Cons of high volume manufacturing include:

  • Limited production capacity
  • Not cost-effective for small orders
  • Requires a large number of resources

What is Low Volume High Mix Manufacturing?

 

Low volume high mix manufacturing, also called high-mix low-volume (HMLV), is the process of producing a lot of different products in small quantities. This is a common technique for producing one-of-a-kind and complex items with specific quality demands. HMLV production necessitates frequent job modifications, material changes, and equipment adjustments.

 

When it comes to high mix low volume manufacturing lines and a wide range of product demands, operators working in this type of environment are exposed to a lot of change. This can often lead to inconsistency and errors in the scheduling of jobs and materials.

 

The choice between high volume vs low volume manufacturing processes depends primarily on the market demand for a product. Market testing is often more feasible in low volume, high variety production, contrasting the usual approach in high volume vs low volume manufacturing. If you are bringing a new product to market, then high mix, low volume manufacturing might be most appropriate for you.

 

High mix low volume manufacturing allows you to conduct better market testing. It&#;s a much more convenient way to introduce and assess new products without the need for high volume manufacturing runs.

 

By doing so, you can minimize your financial risk and make tweaks to the product as demands change. While this is a more complex manufacturing process, high mix low volume manufacturing gives you adaptability that can give you and edge over your competitors.

 

 

What About Products with High Volume but Small Variety?

 

For products with high volume but small variety, there are a few different types of manufacturing processes you could use. The first is low volume injection molding, which is a process where molten plastic is injected into a mould to create your product.

 

With this method, you can produce large quantities of your product quickly and efficiently. However, one downside to this method is that it can be quite expensive to set up. If you have a small budget, this might not be the best option for you. You might initially focus on low volume manufacturing, and later shift your strategy to high volume vs low volume manufacturing based on market demand.

 

Another option for high volume but small variety products is low volume manufacturing. This is a process where your product is made using CNC machines, which are computer-controlled cutting tools. This method is more affordable than low volume injection molding, but it does have some downsides.

 

Another option is mass production, which is also known as high volume manufacturing. This is the most common method of manufacturing and it has a lot of advantages. One advantage of mass production is that it is very fast. This method is also very efficient and can produce large quantities of products quickly and cheaply.

 

The downside to mass production is that it can be quite impersonal. This method is also not well suited for products that require a lot of customization or detail.

 

Why is Mass Production Preferred for High Volume and Small Variety?

 

Mass production is often preferred over HMLV for high volume and small variety because it enables manufacturers to keep costs down, while still ensuring quality. This type of production is more efficient and less labour intensive, which often results in significant cost savings.

 

Distinct approaches are necessary when planning logistics and supply chains for high volume manufacturing vs low volume manufacturing. With low volume manufacturing, you don&#;t have to worry about having excess inventory. However, if you need to satisfy a larger demand, you should opt for high volume production.

 

That said, businesses looking to manufacture products in low quantities may find that low volume production is a better option. This is because low volume production is typically more flexible and can accommodate a wider range of product designs. Low volume contract manufacturing also allows you to have more control over the design and customization of products.

 

Low Volume vs. High Volume Manufacturing

 

So, which is right for your project? Should you use high volume vs low volume manufacturing? It depends on your needs. If you require a large number of parts quickly and can afford the unit cost, high-volume manufacturing may be the way to go.

 

However, if you need a smaller quantity of parts and have some flexibility on lead time, low-volume manufacturing could be the better solution.

 

Still not sure which is right for you? RCO Engineering has more than 43 years of experience in both low and high volume manufacturing. We&#;ve worked in aerospace, automotive, defense, and other industries. We can help you determine the best production method for your project, based on your individual needs. Contact us today to get started.

 

Work with professional manufacturers today and get a quote!

Guide to Low Volume Manufacturing

Modern manufacturing theory, tools, and best practices are focused on how to make thousands or millions of identical parts or products at a low cost per unit. Custom and low volume production require a completely different set of methods &#; and manufacturers are faced with unique challenges when trying to adapt mass production systems to fit. 

Thanks to the rapid development of manufacturing methods and materials, however, there are now multiple technologies available that can enable the fabrication of these custom and low volume end-use parts and products rapidly and cost-efficiently. 

This guide presents an overview of the different low volume manufacturing scenarios, as well as technologies and solutions for low volume end-use part production.

What is Low Volume Manufacturing?

Low volume manufacturing generally refers to production runs that yield between ten to tens of thousands of parts.

Today, most traditional manufacturing methods such as molding or forming are based on the concept of mass production: fabricating large quantities of identical goods. While these techniques are extremely cost-efficient for high-volume production (over 10,000 parts), they require standardization, expensive machinery, and tooling that rarely allow for product modifications. 

Tooling for mass production processes like injection molding can easily cost $10,000+ and add weeks or months to production timelines. With mass production, manufacturers can offset these steep upfront capital expenses with high-volume orders, as cost per part decreases when the costs get distributed among thousands of parts. Mass manufacturing processes are geared toward producing identical parts in large quantities, restricting the ability to manufacture specialized or highly customized pieces economically.

In contrast, the fabrication of items based on unique specifications, also known as custom manufacturing or high-mix low-volume (HMLV) manufacturing, is traditionally performed manually in small workshops. Because of the high proportion of manual labor and the lower throughput, this results in a higher cost per part for custom products. For the same reasons, creating large quantities of individually custom-built goods, referred to as mass customization, has seldom been economically viable.

Over the last few decades, there has been a rapid development in manufacturing methods suitable for low volume production. Technologies like additive manufacturing (3D printing), CNC machining, and rapid tooling offer unique benefits for low volume production, custom manufacturing (high-mix low-volume manufacturing), and mass customization.

These benefits of low volume manufacturing include:

  • Lower costs: Eliminate excessive tooling costs that require minimum orders to be offset, reduce barriers to market entry, and encourage innovation.

  • Speed: Compress development timelines and reduce months&#; long lead times for production to a couple of days or weeks to beat your competitors to the market.

  • Flexibility: Solve manufacturing challenges, respond to customer feedback, iterate products quickly, and implement design changes, all rapidly and without excessive costs.

  • Customization: Offer customization to customers and create products with unprecedented design freedom, including complex parts using organic, latticed, or intricate shapes without additional costs. 

    Goto thingyfy to know more.

Control: Tighten supply chains and shorten lead times with local, on-demand production and keep inventories of parts or sub-components to the minimum to meet changing business needs rapidly.

White Paper

Outsourcing vs. In-House: When Does it Make Sense to Bring SLS 3D Printing In-House?

In this white paper, we evaluate the value proposition of bringing SLS 3D printers in-house, in comparison with outsourcing SLS parts from a service bureau.

Download the White Paper

Low Volume Production Scenarios

The drive for innovation, improved quality, and lower costs constantly pressures manufacturers as they seek to remain competitive and maximize profit. From bridging the gap between prototyping and mass production to reducing supply chain bottlenecks, let&#;s look at the various low volume production scenarios.

The Hasbro Selfie Series offers the first personalized, mass-customized action figures.

Customization

Today&#;s customers are spending more time and money to find products that fulfill their individual needs and requirements. More options for personalized, curated products and experiences are needed to meet demand. Low volume manufacturing can help companies scale personalized products for mass-market opportunities without the need to invest in costly tooling. 

Businesses can rethink the way products are made and explore new business models that bring them closer to their individual customers&#; needs, such as mass customization.

New Balance released a limited edition high-performance sneaker with 3D printed insoles.

Product Innovation

With innovative tools like 3D printing, designers can push the boundaries of design complexity, optimize structures, and tailor parts at no extra cost to develop unique products that are difficult to manufacture with traditional methods.

Resin 3D printers allow you to create complex shapes and parts, with features like overhangs, microchannels, and organic shapes, that would be costly or even impossible to produce with traditional manufacturing methods. This provides the opportunity to consolidate multi-part assemblies, reducing weight, alleviating weak joints, and cutting down on assembly time, unleashing new possibilities for design and engineering.

Tension Square produces an innovative medical device with 3D printing.

Bridge Manufacturing

Bridge manufacturing is a stage in the product development process that bridges the gap between prototyping and production. Businesses across all industries can leverage low volume production to quickly and affordably produce smaller batches of parts before transitioning to mass production. They can reduce mass-production risks by using pilot runs for product testing, pre-sales, or market validation before committing to expensive tooling for mass production. 

3D printed COVID-19 test swabs produced in response to the global pandemic.

Supply Chain Resilience

Global supply chain bottlenecks increase lead times and represent a major threat to new product time-to-market, client satisfaction, and overall competitive advantage. Low volume manufacturing tools can be leveraged for temporary production, to quickly and affordably produce short runs during times of shortage. Businesses can reduce their reliance on third-party suppliers, withstand logistics disruptions and geopolitical issues, and answer rapidly to market changes by bringing manufacturing capabilities in-house.

Battle Beaver Customs&#; Playstation 5 controllers with 3D printed internal parts.

Aftermarket Parts

Aftermarket manufacturers create end-use products that operate as components or additions to an existing product from the original equipment manufacturer (OEM). For these applications, introducing new innovative products while keeping up with OEM&#;s product updates is a major challenge. 

By eliminating tooling, low volume manufacturing brings the agility needed to adjust aftermarket components on demand, both in design and production. Aftermarket companies can build complex geometries to improve product performance or tailor products to their customers. Low volume production helps to minimize inventory and ensure continued compatibility through the original equipment manufacturer&#;s updates.

Automotive supplier Brose has been evaluating 3D printing spare part production.

Spare Parts

When an OEM stops production of a particular product or model, they have to continue to stock thousands of parts to service clients who have legacy products and need replacements or repairs. If the OEM doesn&#;t create and store enough of these spare parts, large groups of customers who still use those discontinued models are often left without solutions. It is difficult for an OEM to calculate exactly how many parts to store &#; if they overestimate, they have to deal with waste and storage issues, and if they underestimate, buyers become disgruntled. 

Leveraging technologies like 3D printing to produce spare parts in-house allows manufacturers to shift from a physical to a digital inventory. Only the CAD models are stored to produce on-demand parts and replace a lost or damaged item.

Technologies for Low Volume Production

Additive Manufacturing (3D Printing)

3D printing has been ubiquitous in prototyping and product development for decades. Now, this maturing technology is entering widespread use in manufacturing. In the product development process, manufacturers are already leveraging the flexibility of 3D printing for producing internal tools, such as jigs, fixtures, and other manufacturing aids, or even rapid tooling such as molds for injection molding or thermoforming.

Recent advances in machinery, materials, and software open opportunities for producing high-precision, functional 3D prints that can stand in for end-use parts&#;parts that are sold to and used by the final customer &#; empowering businesses to bring innovative products to market and make small and mid-scale manufacturing accessible. 

3D printers are most commonly used to produce plastic parts &#; metal 3D printers are also available, but at a substantially higher cost. There are many different types of 3D printers, the most common processes for producing plastic parts being: selective laser sintering (SLS), stereolithography (SLA), and fused deposition modeling (FDM).

Razor handle

Gillette
SLA - Custom Resin
Mass customization

Lateral thruster for jet boat&#;s pump

JetBoatPilot
SLS Nylon 12 Powder
Aftermarket parts

Housing for a vehicle&#;s control system

IBL Hydronic
SLS  = Nylon 11 Powder
Low volume production

As professional 3D printers require no tooling and minimal setup time for a new design, the cost of producing a custom end-use part is negligible in comparison with traditional manufacturing processes. 

Additive manufacturing processes generally have a higher cycle time and are more labor-intensive than manufacturing processes commonly used for mass production, but they represent a substantial leap in productivity compared to traditional manual low volume production and fabrication processes. As 3D printing technologies improve, the cost per part will continue to fall, opening up an even wider range of low- to mid-volume applications.

Most traditional manufacturing processes require expensive industrial machinery and skilled operators, forcing many companies to outsource their production to dedicated facilities. 3D printing, however, enables in-house production. Compact desktop or benchtop 3D printing systems for creating plastic parts are affordable, require very little space and no special skills, enabling professional engineers, designers, and manufacturers to speed up iteration and production cycles from months to just a few days.

Manufacturing Process

  1. Design: Design your model in CAD, or create a model based on a 3D scan of an existing model, an MRI scan, or an intraoral scan. 
  2. Print setup: Print preparation software is used for orienting and laying out models within a printer&#;s build volume, adding support structures (if needed), and slicing the supported model into layers.
  3. Printing: Choose the right technology and material, and 3D print the part on a 3D printer.
  4. Post-processing: When printing is complete, parts are removed from the printer, cleaned or washed, post-cured (depending on the technology), and the support structures removed (if applicable). Parts can be painted, coated, or post-processed further with other finishing techniques.

Webinar

How to Unlock Low Volume Production and Custom Manufacturing with 3D Printed End-Use Parts

Watch this webinar to learn how to achieve custom manufacturing and low volume production of end-use parts quickly and cost-effectively with 3D printing.

Watch the Webinar Now

White Paper

Stress Testing 3D Printed Parts for End-Use Applications

This white paper presents Formlabs 3D printing hardware and material solutions for end-use part production. It documents various users' case studies and includes stress testing results to verify the suitability of 3D printing materials for end-use applications.

Download the White Paper

CNC Tools

Computer numerical control (CNC) tools are subtractive manufacturing processes. They start with solid blocks, bars, or rods of plastic, metal, or other materials that are shaped by removing material through cutting, boring, drilling, and grinding.

CNC tools include CNC machining, which removes material by either a spinning tool and fixed part (milling) or a spinning part with a fixed tool (lathe). Laser cutters use a laser to engrave or cut through a wide range of materials with high precision. Water jet cutters use water mixed with abrasive and high pressure to cut through practically any material. CNC milling machines and lathes can have multiple axes, which allows them to manage more complex designs. Laser and water jet cutters are more suited for flat parts.

CNC tools can shape parts from plastics, soft metals, hard metals (industrial machines), wood, acrylic, stone, glass, and composites. They&#;re ideal for producing custom or low-volume end-use parts, structural parts, and tooling for a wide range of industries.

Compared to additive manufacturing tools, CNC tools are more complicated to set up and operate, while some materials and designs might require special tooling, handling, positioning, and processing. This makes them costly for one-off parts compared to additive processes and better suited for small production runs.

Machining is ideal for low volume manufacturing applications that require tight tolerances and geometries that are difficult to mold, such as pulleys, gears, and bushings. CNC machining has low to moderate setup costs, and can produce high-quality components with short lead times from a wide range of materials.

Machining processes have more part geometry restrictions than 3D printing. With machining, cost per part increases with part complexity. Undercuts, pass-throughs, and features on multiple part faces all increase costs. Machining processes require allowances for tool access and certain geometries, like curved internal channels, are difficult or impossible to produce with conventional subtractive methods.

Manufacturing Process

  1. Design: Design your model in CAD, or create a model based on a 3D scan of an existing model, an MRI scan, or an intraoral scan. 
  2. Job setup: CNC machines require an intermediary step of generating and validating toolpaths (CAD to CAM). Toolpaths control where the cutting tools move, at what speeds, and any tool changeovers.
  3. Machining: The toolpaths are sent to the machine where the given subtractive process begins. Depending on the desired shape of the final product, the workpiece may need to be set in a new position so that the tool head can reach new areas.
  4. Post-processing: After manufacture, the part is cleaned and deburred, trimmed, and can be post-processed further with other finishing techniques.

Rapid Tooling

Rapid tooling is the group of techniques used to fabricate tooling fast, at low cost, and efficiently for traditional manufacturing processes like injection molding, thermoforming, or casting to create parts on a short timeline or in lower quantities. 

Conventional tooling is most commonly produced out of durable metals using technologies such as machining and metal casting. However, these processes are expensive and better suited for large-scale production cycles. When used for tooling iterations or to produce tooling that would be used to manufacture only small batches of parts, costs rise and production timelines extend dramatically.

Incorporating rapid tooling into the product development process enables manufacturers to validate design and material choices prior to transitioning to mass production to accelerate product development, iterate quickly, and bring better products to market. Rapid tooling empowers engineers to use the actual production-grade materials to evaluate how the parts will perform in real-world applications and produce limited volumes of products for beta and validation testing. Rapid tooling can also help troubleshoot the manufacturing process before investing in expensive production tooling.

Rapid tooling also provides means to produce custom or limited series of end-use parts using traditional manufacturing processes that would be prohibitively expensive using conventional tooling. This allows manufacturers to test the market for new products, offer a wider range of products, or customize parts based on customer needs.

Rapid tooling can be used to support a variety of traditional manufacturing processes to produce plastics, silicone or rubber parts, composites, and even metal parts.

Manufacturing Process

  1. Design: Design the mold, pattern, die, or master tool in CAD software.
  2. Producing the tooling: Manufacture the tooling with a 3D printer or a CNC tool, or create molds or tools based on a master pattern.
  3. Manufacturing: Insert the rapid tooling in your machine or use the pattern in your workflow and carry out the production process.
  4. Post-processing: Perform any necessary post-processing to achieve the quality finish of an end-use part.

Low Volume Production Technologies Comparison

3D PrintingCNC ToolsRapid ToolingTechnologiesSelective laser sintering (SLS), stereolithography (SLA), fused deposition modeling (FDM), metal 3D printingCNC machining (mill or lathe), laser cutting, water jet cuttingInjection molding, thermoforming, overmolding and insert molding, compression molding, casting, sheet metal formingMaterialsPlastics, metals (limited), silicone and rubber-like partsPlastics, metals, wood, acrylic, stone, glass, and compositesPlastics, metals, composites, silicone and rubber partsFormHigh degree of freedomMedium degree of freedomMedium degree of freedomLead time to final parts (in house)One to two daysOne day to a weekOne day to a weekCycle time< 1 hour to multiple hours, depending on part size< 1 hour to multiple hours, depending on part size, design, and complexityCouple of seconds to multiple hours, depending on process and the materialSetup cost$$$$-$$Cost per part$$-$$$$$$$$$

In House Production vs. Contract Manufacturing

While manufacturing traditionally involves contract manufacturers and a long chain of suppliers, low volume manufacturing tools also allow companies to bring production in house.

Outsourcing production to service bureaus or labs is recommended when you require just a few parts occasionally, and for parts that are large or call for non-standard materials. Service providers like Hubs, Protolabs, Fictiv, or local service bureaus offer manufacturing and low volume production services on demand. These bureaus typically have multiple technologies available, including additive and subtractive processes, as well as rapid tooling. They can also provide advice on various materials and offer value-added services such as design or advanced finishing.

The main downsides of outsourcing to service providers are cost and lead time. One of the greatest benefits of low volume manufacturing is its speed compared to traditional manufacturing methods, which quickly diminishes when the outsourced parts take a week or multiple weeks to arrive. Outsourcing the manufacturing of low volume parts is also often very expensive. Depending on the number of parts and volume, a business can often break even within a few months by simply investing in a 3D printer and printing in house.

With desktop and benchtop 3D printers, companies can pay for just as much capacity as their business needs, and scale production by adding extra units as demand grows. By using multiple 3D printers, you also get the flexibility to print parts in different materials simultaneously. Service bureaus can still supplement this flexible workflow for larger parts or unconventional materials.

Interactive

Calculate Your Time and Cost Savings

Try our interactive ROI tool to see how much time and cost you can save when 3D printing on Formlabs 3D printers.

Calculate Your Savings

White Paper

Managing 3D Printer Fleets

Managing multiple SLA and SLS printers doesn&#;t have to be complicated &#; any business can get a fleet of SLA and SLS printers up and running in just a day or two. By reviewing four different successful multi-printer scenarios, this guide will help you set up an efficient workflow for any volume or part type.

Download the White Paper

Get Started With Low Volume Production

Freed from the tooling constraints of traditional methods, additive manufacturing is a powerful solution to produce low volume end-use parts with minimal lead time. In-house 3D printing enables businesses to take control of their manufacturing, reducing production time, costs, and risks. 

Watch our webinar to learn how to achieve custom manufacturing and low volume production of end-use parts quickly and cost-effectively with 3D printing and explore Formlabs&#; range of professional 3D printing solutions.

Have an idea for leveraging low volume production at your business, but don&#;t know where to start? Get in touch with a Formlabs Solution Specialist to discuss how you can piece together an ideal workflow.

Contact us to discuss your requirements of low Volume Manufacturing Service. Our experienced sales team can help you identify the options that best suit your needs.