Carbide vs. Ceramic Can Tooling: Material Selection Guide

Carbide vs. Ceramic Can Tooling: A Procurement Guide to Material Selection and Line Uptime | Carbide Products, Inc.

Carbide Products, Inc. — Georgetown, KY

Carbide vs. Ceramic Can Tooling: A Procurement Guide to Material Selection and Line Uptime

The tooling material you specify isn't just a cost decision. It's a line uptime decision.

May 27, 2026  ·  Georgetown, KY

Can manufacturing lines don't have a lot of tolerance for error — in either sense of the word. The tooling running your body maker operates at hundreds of strokes per minute, making contact with thin-gauge aluminum on every cycle. When that tooling is off by a few tenths, or when it wears unevenly, you don't just swap a component. You lose line time. And in high-volume can production, downtime is expensive in ways that a tooling invoice rarely captures.

Material selection is where most of that uptime risk lives. Carbide and ceramic are both viable materials for precision can tooling — but they are not interchangeable. Each has a defined range of applications where it performs reliably, and specific conditions where it will underperform or fail early. Understanding the difference before you specify tooling is the difference between a three-month replacement cycle and an emergency order in the middle of a production run.

What the Tooling Is Actually Doing

A can body goes through a series of precisely controlled forming operations between flat aluminum blank and finished container. At each station, tooling is doing work that requires tight geometry, consistent surface finish, and the ability to hold that geometry through millions of cycles without drifting.

The critical tooling stations include blanking and drawing, redrawing, ironing (where the can wall is stretched and thinned to final gauge), doming, flanging, and necking. Each of these operations places different demands on the tooling material. Ironing dies, for example, see continuous sliding contact and high surface pressure. Dome punches see repeated impact loads. Necking tooling requires precise internal geometry with extremely tight tolerances held over long production runs.

The right question isn't "what's the hardest material?" It's "what material performs best at the specific contact condition, pressure, and cycle rate this station demands?"

Where Tungsten Carbide Wins

Tungsten carbide is the workhorse of can tooling. Its combination of hardness, toughness, and compressive strength makes it the right choice for stations that see the highest contact stress and the most demanding wear conditions.

Primary applications for carbide can tooling

Drawing and redraw dies, ironing rings, dome tooling, and flanging tools are typically specified in tungsten carbide. These stations involve sustained contact pressure and benefit from carbide's resistance to abrasive wear and its ability to maintain a polished surface finish over extended production runs.

Grade selection within carbide matters significantly. Cobalt binder content affects the trade-off between hardness and toughness. A lower cobalt percentage increases wear resistance but reduces impact toughness — appropriate for steady-contact operations. Higher cobalt content adds toughness for applications that involve any impact loading. Grain size is a second variable: finer grain carbide supports higher surface finish and holds tighter edge geometry, while coarser grain offers improved toughness for more demanding structural applications.

The practical consequence is that carbide tooling specified without reference to the actual production conditions — grade, geometry, surface finish — may still wear prematurely or fail to hold dimensional accuracy through the expected tool life. This is why CPI works from customer prints and, when needed, from application context rather than a catalog default.

Where Ceramic Can Tooling Has an Advantage

Advanced ceramics — including alumina, silicon nitride, and zirconia-toughened formulations — offer hardness values that exceed tungsten carbide in select applications. In the right conditions, this translates to meaningfully longer tool life and reduced downtime frequency.

Primary applications for ceramic can tooling

Necking dies, certain ironing applications, and tooling for specific aluminum alloys where lubrication conditions are controlled are candidates for ceramic. The key qualifier is that the application involves consistent, steady contact rather than cyclic impact or shock loading.

Ceramic components are more brittle than carbide. That brittleness is not a defect — it's the trade-off for the hardness gain — but it means ceramic tooling requires a controlled environment to realize its longevity advantage. Applications with inconsistent feed, debris in the forming zone, or any real impact loading will see shorter tool life in ceramic than carbide, not longer.

The other consideration is tolerance capability. Precision ceramic grinding requires equipment and process knowledge that not every tooling shop maintains. At CPI, we grind ceramic components on the same precision equipment as carbide, holding the same tolerance standards. This matters because a ceramic component with inconsistent geometry doesn't deliver the surface finish consistency or tool life that makes ceramic worth specifying in the first place.

What to Know Before You Source

When procurement teams contact CPI for can tooling, the conversations that go smoothly share a few things in common. An existing print — or a worn component to measure — gives us the geometry we need to quote accurately. Information about the production environment (material being run, line speed, lubricant system, cycle expectations) helps us recommend the right material specification if the print doesn't call one out.

What helps us quote accurately

A print or sample part, material specification if known, expected cycle life, and whether this is a first-article or repeat production order. If you're replacing tooling that failed early, knowing the failure mode — wear pattern, surface degradation, edge chipping — gives us the information to recommend whether a grade or geometry change is worth exploring.

Domestic sourcing is worth factoring into your evaluation. Lead time on imported can tooling has been a persistent challenge in recent years, and the traceability requirements that automotive-adjacent and beverage customers are increasingly imposing on their supply chains favor domestic production with documented inspection records. CPI manufactures can tooling in Georgetown, Kentucky, ships from domestic inventory, and maintains full dimensional traceability on every component we produce.

If you're evaluating tooling suppliers for a can manufacturing application — whether carbide, ceramic, or still deciding on material — the conversation starts with your print and your production requirements. CPI can help you specify the right material for the right station, manufactured to the dimensional standards your line demands.

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Carbide Punch and Die Tooling: Specifying for Life

Carbide Punch & Die Tooling: Specifying for Service Life | Carbide Products, Inc.

Tooling Engineering  ·  Carbide Products, Inc.

Carbide Punch & Die Tooling:
Specifying for Service Life,
Not Just First Cost

Grade selection, geometry, and tolerance discipline are the variables that separate tooling that runs a million cycles from tooling that fails at fifty thousand.

Georgetown, KY  ·  May 13, 2026

Every stamping engineer has a story about tooling that didn't make it. The punch cracked at the corner radius on the third day of production. The die insert chipped on a burr the setup missed. The first-article parts looked perfect, and by ten thousand cycles the feature had drifted outside tolerance. These aren't failures of machining skill — they're usually failures of specification. The wrong material, the wrong geometry, or an inadequate tolerance on a feature that had to hold under real production conditions.

Carbide punch and die tooling is not immune to these failures, but it changes the math significantly. When specified correctly — right grade, right geometry, tolerances that reflect the actual demands of the application — carbide tooling routinely achieves ten to forty times the service life of equivalent tool steel tooling in high-cycle stamping environments. When specified incorrectly, carbide's brittleness makes failures faster and more dramatic than anything tool steel would have produced.

This post covers how to get the specification right.

Why Carbide in High-Cycle Stamping

Tungsten carbide's advantages in punch and die applications are well established: hardness in the range of 1,400–1,800 HV (compared to roughly 740–900 HV for the best tool steels), exceptional wear resistance, and the ability to hold a sharp cutting edge through far more cycles than any metallic alloy. In high-volume stamping — blanking, piercing, fine blanking, progressive die work — these properties translate directly into longer runs between regrind, fewer die changes, and lower cost per stamped part.

The tradeoff is toughness. Carbide is stiffer and more brittle than tool steel. It does not deflect gracefully under overload — it fractures. This means carbide tooling demands more from the press setup, the die clearance, and the part geometry specification than equivalent tool steel tooling would. The engineering work done before the tool is made determines whether carbide's advantages are realized or its brittleness shows up in production.

A useful framing: in a well-specified carbide punch and die application, the tooling should outlast every other consumable in the die. If you're replacing punches before you're replacing the die block, shims, lifters, or die shoe, the tooling specification is worth revisiting.

Grade Selection: The Foundation of the Specification

Tungsten carbide tooling is not a single material. Grades vary primarily by cobalt binder content and WC grain size, and these two variables drive a direct tradeoff between hardness and toughness. Understanding where your application sits on this tradeoff is the most consequential decision in the specification process.

Low Cobalt (3–8% Co) — High Hardness Grades

Fine grain, very high hardness (1,600–1,800 HV). Best choice for fine blanking and precision piercing of thin, soft materials where cutting edge retention is the primary requirement. Limited toughness — not appropriate for applications with shock loading, interrupted cuts, or misalignment risk. Chipping and fracture are the failure modes when these grades are used outside their design envelope.

Medium Cobalt (10–15% Co) — General Purpose Grades

The workhorse of carbide punch and die tooling. This range provides the best balance of wear resistance and toughness for most stamping applications: medium-gauge sheet metal, stainless steel blanking, and progressive die work where punches may see some lateral load. Most custom carbide punch and die work is specified in this range.

High Cobalt (16–25% Co) — Tough Grades

Lower hardness but substantially improved impact and fracture resistance. Appropriate for heavy blanking of thick or high-strength material, applications with significant shock loading, or geometries — long slender punches, thin webs — where brittleness failure is a primary concern. Also used in forming applications where the tool needs to absorb deformation energy without fracturing.

CPI works with customers to match grade selection to the documented demands of the application: material thickness, tensile strength, press speed, punch geometry, and expected cycle count. There is no universal right answer, and a grade that performs well in one application will fail in another that looks similar on paper.

Geometry: Where Most Carbide Punch Failures Begin

Carbide's brittleness concentrates stress at geometric discontinuities. This is not a design flaw to be worked around — it's a physical property to be designed for. The geometry of a carbide punch or die insert must be specified with this in mind.

Corner radii are the most common failure point. Internal corners — any place where two surfaces meet at an angle — are stress concentration sites. In carbide tooling, an internal corner with no specified radius is not just a drafting convention, it's a crack initiation site. Most carbide punch geometries require a minimum corner radius on the print. What that radius should be depends on the cobalt grade, the cross-section geometry, and the load environment — but zero is almost never the right answer, regardless of what the stamped part geometry would otherwise call for.

A key specification question that customers often don't think to ask: what is the corner radius on the punch shank where it transitions to the cutting head? If this transition is a sharp step, it's a fracture site under bending load. A blended radius here — even a small one — significantly improves punch life in applications where the punch sees any lateral force during the cut.

Land and clearance specifications also matter more with carbide than with tool steel. The die clearance — the gap between punch OD and die bore — must be tightly controlled. Insufficient clearance increases lateral loading on the punch during cutting, concentrating bending stress in the shank. Excessive clearance produces a drawn edge rather than a sheared edge, causes the punch to seek the center of the die bore on each stroke (introducing fatigue loading), and degrades part quality. The correct clearance for a given application depends on material thickness, tensile strength, and the type of cut — and it should be specified on the die drawing, not left to the die shop's default practice.

Tolerancing Carbide Punch and Die Sets

Carbide punch and die tooling is typically ground to close tolerances — surface ground for flatness and thickness, OD ground for punch diameter, and ID ground or wire EDM'd for die aperture. The tolerances achievable in carbide grinding are tight: ±0.0001" on diameter, ±0.0001" on flatness, surface finish below Ra 16 µin as a practical standard.

The question is which dimensions require that precision, and which don't. Over-specifying tolerances on features that don't functionally require them drives cost without improving performance. Under-specifying on features that do matter — punch-to-die clearance, flatness of the seating surface, perpendicularity of the punch OD to the shank face — produces tooling that performs poorly regardless of how well it was manufactured.

Tolerance callouts that are commonly under-specified on carbide punch and die prints:

Perpendicularity of the Cutting Face to the Punch Axis

If this relationship is not called out, each supplier will hold whatever their equipment produces by default. A punch that is slightly out-of-square to its axis produces an uneven cut and applies lateral load at a consistent clocking position every stroke — exactly the fatigue loading pattern that causes early shank fractures.

Flatness of the Die Seating Surface

A die insert that rocks on its seat — even a few tenths — concentrates load at the high point on every stroke. This is a common contributor to edge chipping on carbide die inserts in progressive die applications where the die block sees repeated impact.

Surface Finish on the Cutting OD

Carbide's hardness means surface finish on the cutting OD is a wear and friction specification, not just cosmetic. A poorly finished punch OD increases friction during the cut, adds lateral loading during extraction, and can gall against the die bore in tight-clearance applications. Ra 16 µin or better is the practical standard for carbide punch ODs in stamping applications.

What CPI Brings to Carbide Punch and Die Work

CPI has been manufacturing precision carbide components to customer print for over 80 years. Our punch and die tooling work is not catalog-based — every component is manufactured to the dimensions, grade, and surface finish specified on the customer's print, with the process experience to flag when a specification is likely to cause problems before the tool is made.

Our process combines CNC grinding, surface grinding, and wire EDM for profiles that require it, with CMM inspection on critical dimensions. We work in the full range of WC-Co grades and can advise on grade selection for customers developing a new application or respecifying existing tooling that's underperforming.

If you're sourcing carbide punch and die tooling for a new program, dealing with premature tool failures in an existing application, or transitioning from tool steel to carbide and want to understand what changes in the specification — send us your print and we'll take a look.

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Have a Punch or Die Application
That Needs Precision Carbide?

Send us your print and we'll put a quote together. Custom carbide punch and die tooling — to your specification, made in Georgetown, KY.

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How to Source a Part That Doesn't Exist

How to Source a Part That Doesn't Exist in Any Catalog | Carbide Products, Inc.

Sourcing Guide · Carbide Products, Inc.

How to Source a Part That Doesn't Exist in Any Catalog

Whether you're starting from a print, a worn-out part, or a description of what you need — here's how to find a domestic manufacturer who can actually make it.

May 6, 2026  ·  Georgetown, KY

Most industrial buyers know this moment well. You need a wear component, a die insert, a guide, a profile — something specific to your machine, your line, or your application. You call your distributor. They search the catalog. They come back with some version of the same answer: "We don't carry that" or "That would be a special order" or simply silence.

It's not that your part is unusual. It's that parts like yours — application-specific, dimensionally precise, built to perform one job on one line — were never catalog items to begin with. They never will be. They exist because someone made them, to a specific print, for a specific purpose.

Finding the right manufacturer for that work is a different process than sourcing from distribution. This post walks through how it works — including two common starting points — and why the current manufacturing climate has made domestic to-print sourcing easier and more important than it's been in years.

Why These Parts Aren't in Any Catalog

Catalogs exist to solve a volume problem. A distributor stocks parts that enough customers will need, in standard dimensions, so inventory can be managed profitably. That model works well for fasteners, bearings, and general wear stock.

It breaks down for precision components that are purpose-designed for a specific application. A carbide wear pad ground to a proprietary profile for a particular stamping line. A ceramic die insert dimensioned to a customer's part geometry. A tungsten carbide guide bushing with a bore and OD tolerance that reflect 30 years of process refinement at one plant. These parts aren't in catalogs because they belong to you — your application, your print, your performance specification.

The right question isn't "who carries this part?" It's "who can make this part?" Those are different phone calls — but the second one is usually more straightforward than buyers expect.

To-print manufacturers like CPI exist specifically for this work. The entire business model is built around receiving a customer's specification — whether that's a formal engineering drawing or a physical sample — and producing parts that meet it exactly, with full documentation.

Two Starting Points, One Process

Most requests for to-print precision components come from one of two places. Both lead to the same outcome.

You Have a Print

A dimensioned drawing — even a PDF, a hand sketch, or a CAD file — is all a to-print manufacturer needs to get started. Submit it with your material specification, required tolerances, and quantity. The manufacturer reviews it for manufacturability, quotes it, and produces to your exact dimensions. If there's a question about the print, a good manufacturer calls you before cutting anything.

You Have the Old Part

Prints go missing. Machines outlive their documentation. Original suppliers go out of business. When the only reference you have is the worn-out part itself, a capable manufacturer can reverse engineer, and produce replacements — sometimes improving on the original in the process. This problem is much more common than many realize.

Learn about CPI's reverse engineering process →

In either case, the conversation starts the same way: a description of what you need and whatever reference material you have. No formal procurement process required to get an initial quote. No minimum order. No need to fit your part into someone else's catalog.

What Materials and Parts Can Be Sourced This Way

To-print manufacturing covers a much broader range of materials and part types than many buyers realize. At CPI, that includes carbide wear components — wear pads, guides, liners, bushings, and wear inserts used in stamping, forming, and high-cycle industrial applications. It includes punch and die tooling, carbide and ceramic can tooling, specialty carbide profiles produced via precision grinding and Wire EDM, and precision components to print across a range of materials and geometries.

If it requires tight tolerances, a specific material, or a geometry that doesn't come off a shelf, it's a candidate for this sourcing path. The question to ask is not "is this a standard part?" — it almost certainly isn't — but rather "can I describe what this part needs to do and what dimensions it needs to hold?" If yes, a to-print manufacturer can work with you.

One of the most common conversations CPI has with new customers goes like this: "We've been buying this part from the same place for fifteen years, they closed down, and nobody else has it." That's exactly the situation to-print manufacturing exists to solve.

Why Domestic Sourcing Matters More Right Now

The trade policy shifts of 2025 and 2026 have changed the calculus for precision component sourcing in ways that are still working through supply chains. Procurement teams that built their supplier base around overseas carbide and specialty components — often drawn by lower unit prices — are now navigating a very different landscape: longer lead times, tariff cost exposure, and in some cases, suppliers who simply can't hold tolerances consistently under the volume pressure of a reshoring-driven market.

For application-specific precision components, the case for domestic sourcing was always stronger than the unit price comparison suggested. Documentation, traceability, communication, and the ability to work directly with the manufacturer on a tolerance issue or an emergency replacement order — none of these are easy to maintain across a 14-week international supply chain.

CPI has operated in Georgetown, Kentucky for over 80 years. Every component we ship can come with full material certifications and dimensional documentation if needed. When something needs to change on a print or a delivery needs to move up, you call us directly. That's not a marketing claim — it's the practical reality of working with a domestic manufacturer at this scale.

The reshoring conversation happening at the OEM and Tier 1 level right now is, in many ways, a rediscovery of what domestic to-print manufacturers have always offered: reliability, traceability, and a supply chain you can actually see.

How to Get Started

The fastest path to a quote is straightforward. If you have a print, submit it with your material and tolerance requirements and a note on quantity and timing. If you have the physical part and no print, ship it — or send clear dimensional photos and your best description of the application — and we'll measure and quote from there. If you have neither and are starting from scratch on a new design, that's a conversation worth having early, while material selection and geometry are still flexible.

What you don't need is a formal approved vendor process, a purchasing account, or a perfectly complete drawing package. Most of the best sourcing relationships start with an imperfect RFQ and a phone call. We've been doing this for over 80 years. We know how to work with what you have.

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Have a Part That Needs to Be Made, Not Found?

Send us your print, your sample part, or just a description of what you need. CPI's team will review it and get back to you with a quote — no formal vendor process required to get started.

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Grinding for Precision Components

When the Tolerance Can't Be Milled: Precision Grinding for Precision Components | Carbide Products, Inc.

Precision Grinding · Carbide Components

When the Tolerance Can't Be Machined

For precision components where surface finish and dimensional accuracy define whether a part performs or fails, precision grinding isn't the last step — it's the one that matters most.

Carbide Products, Inc. · Georgetown, KY · April 29, 2026

There is a tolerance threshold where conventional machining operations — milling and turning — reach their practical limit. Below that threshold, precision grinding takes over. For carbide components, that handoff is not a contingency. It is part of the process.

Carbide is among the hardest industrial materials in commercial use. That hardness is the point — it's what makes a carbide wear pad outlast a steel equivalent by an order of magnitude, or what keeps a carbide knife edge consistent through hundreds of thousands of cycles. But hardness is also what makes carbide unforgiving. You cannot come back to a carbide part with a file or a polishing cloth and expect to move the number. Once it's ground, it's ground. Which means the grinding operation has to be right the first time.

This post covers what precision grinding actually does for carbide components, when it should be specified, and what to expect in terms of dimensional and surface finish outcomes.

Why Forming Operations Alone Don't Get You There

Carbide blanks — whether pressed and sintered, cast, or produced via powder metallurgy — come out of the blank stage with dimensional tolerances that are intentionally generous. Sintering shrinkage is not perfectly uniform. Press geometry can vary from piece to piece. The blank is designed to be finish-processed to print, not to be used from the blank stage.

Wire EDM can hold tighter tolerances than sintering and is excellent for complex profiles — but EDM also leaves a recast layer at the surface, a thin zone of metallurgical disruption that affects surface integrity in high-stress or high-wear applications. For parts where surface integrity is a specification requirement — aerospace tooling, precision wear pads in a rolling-contact application, carbide knives running against abrasive materials — grinding is typically required after EDM to remove the recast layer and reach the final surface specification.

Key Principle

Precision grinding is not a corrective operation. It is a planned step in the manufacturing sequence. If your carbide component requires dimensional tolerances tighter than ±0.0005" or surface finishes below Ra 32 µin, grinding should be designed into the process plan from the beginning — not added at the end.

What Precision Grinding Achieves for Carbide

The practical outputs of precision grinding on carbide components fall into three categories:

Dimensional Control

Tight tolerances on critical features

Surface grinding, cylindrical grinding, and centerless grinding can routinely hold ±0.0002" to ±0.0004" on carbide. For some applications, tighter is achievable depending on part geometry and setup stability.

Surface Finish

Finish to Ra 8–16 µin or finer

Precision grinding can achieve surface finishes in the Ra 8–16 µin range as a standard output. Lapping or superfinishing after grinding can reach Ra 4 µin and below where contact surface geometry demands it.

Parallelism & Flatness

Geometric accuracy across a surface

Surface flatness and parallelism on carbide wear pads, liners, and guide components are critical to load distribution. Precision grinding controls these geometric tolerances in ways that sintering and EDM cannot.

Edge Geometry

Controlled edge preparation

For carbide knives and cutting inserts, grinding defines the edge geometry — relief angle, clearance angle, edge sharpness — that determines cutting performance and edge life in production.

When Precision Grinding Should Be Specified

Not every carbide component requires grinding as a finishing step. Many wear pads and liner components in moderate-tolerance applications run fine off sintered or EDM dimensions. The cases where grinding is necessary fall into a predictable set of conditions:

Tolerances tighter than ±0.005". Below this threshold, sintered carbide will not be consistent enough. Wire EDM can get much closer, but surface integrity requirements often preclude using EDM as the final operation.

Surface finish specifications below Ra 32 µin. Carbide components running in contact-sliding applications — wear pads against guide rails, bushings in precision bores, knives against substrates — require surface finishes that control friction and wear behavior. Ra 32 µin is the rough threshold where grinding becomes the appropriate process.

Post-EDM recast layer removal. When Wire EDM is used to produce complex carbide profiles, the recast layer at the cut surface should be removed by grinding if the component will be subjected to cyclic stress, high contact loads, or applications where surface cracks from the recast zone could initiate failure.

Flatness and parallelism requirements on wear surfaces. If your carbide wear pad or liner has a flatness or parallelism callout on the drawing — as opposed to just a thickness tolerance — grinding is almost certainly the required process to meet it.

How to Specify Grinding on Your Print

If precision grinding is required for your hardened or carbide components, it is important to clearly define the requirements on your print. A few specific things that help:

Call out the surface finish requirement on the relevant surfaces using a standard roughness symbol and Ra value. Don't leave it as a note in the title block. If the finish matters on a specific face, mark it on that face.

Apply geometric tolerances — flatness, parallelism, perpendicularity — as direct feature callouts using GD&T. A thickness tolerance alone does not control flatness. These are different specifications and they need to be stated separately.

If the part requires grinding on some surfaces but not others, a process note helps: "Grind surfaces A, B, C to print. All other surfaces: as-sintered/as-EDM." This prevents a shop from applying grinding uniformly where it isn't needed — and adding cost accordingly.

Specify the final state of the part. If PVD coating follows grinding, note the pre-coat inspection requirement. The more the print communicates about the intended process sequence, the cleaner the result.

CPI's team reviews drawings before quoting and will flag specification gaps. But a complete print produces a more accurate quote, a cleaner process plan, and fewer conversations before first article.

Precision grinding is one of those operations that is treuly necesary for many precision applications. A correctly ground carbide wear pad arrives flat, dimensionally correct, and ready to install — and runs as expected. The work that went into making it right doesn't show. That's how it's supposed to be.

If you have hardened steel or carbide components with tight dimensional or surface finish requirements, or if you've had parts come back from other suppliers that weren't ground where you expected them to be, CPI's grinding capabilities might suprise you — and it's worth a conversation.

Custom Carbide · Precision Grinding

Have a Part That Needs Precision Grinding?

Send us your print. CPI's grinding team reviews tolerances and surface finish requirements before quoting — so you get an accurate answer, not an estimate.

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