MFG

Technical Drawing Requirements

Technical drawing requirements: title block, datum-based dimensioning, GD&T, surface finish, and thread callouts that make a part makeable.

A technical drawing is the contract between designer and supplier. It states, unambiguously, the geometry, the critical dimensions and tolerances, the surface finish, the material, and any processing, so the part can be made and inspected consistently across suppliers. A clean drawing is also the most direct path to an accurate quote, because it removes the back-and-forth that a vague model forces.

What a drawing must define

A complete drawing defines five things the model alone cannot. It defines the critical dimensions and their tolerances, dimensioned from a datum so inspection repeats.

Geometry and finish

It defines the geometry control through GD&T where fit, position, or runout matter. It defines the surface finish on the features that need it, with the rest left as-machined.

Material and threads

It defines the material, alloy, and temper, because the grade changes both the properties and the machining approach. And it defines the threads by standard, size, class of fit, and depth, so the shop cuts the right thread. A model shows the shape; the drawing defines what the shop must hold and what the inspector must check.

Title block and notes

The title block carries the information that governs the whole drawing. Put the material and temper, the surface finish, the units, the drawing revision, and the general tolerance class there, using a label such as ISO 2768-mK that names both the linear and the geometric class.

Notes block and units

Add a notes block for processing instructions the geometry cannot show, such as deburr all edges, passivate stainless, or anodize type II black. State the units in the title block as well as the filename, because a drawing without explicit units can be read at the wrong scale. Keep the block consistent across drawings, so a shop can find the same information in the same place every time.

Datum and dimensioning

Dimension from a consistent datum so every critical feature traces back to a fixed reference, which makes inspection repeatable across suppliers and machines. A datum is a feature, surface, or axis the part is located from, such as a machined face or a bore, and choosing it well locks the part in six degrees of freedom.

Baseline over chain dimensioning

Chain dimensioning, where each dimension follows the last, lets tolerance stack up along the chain, so prefer baseline dimensioning from the datum for critical features.

Moving to GD&T for fits

Where fit, position, or runout matters, move from plus-minus tolerances to GD&T (ASME Y14.5 or ISO 1101), because geometric control of position or profile holds the functional relationship between features more tightly than size tolerance alone.

GD&T in practice

Geometric dimensioning and tolerancing (GD&T) controls the form, orientation, location, and runout of features, and it pays off exactly where plus-minus size tolerance falls short. A bore can sit inside its diameter band and still be out of round, out of position, or tilted, any of which can stop a bearing from fitting or a seal from holding. GD&T fixes that by controlling the geometry directly: a position tolerance locks a hole pattern to its datum, a perpendicularity tolerance keeps a face square to a bore, a runout tolerance keeps a shaft concentric as it turns, and a flatness tolerance keeps a sealing face in band. The symbols carry the tolerance, the datum reference, and the material condition in a compact frame, so a skilled inspector can set up the measurement unambiguously. The standard behind it is ASME Y14.5 in inch and hybrid work, or ISO 1101 in metric work, and a drawing should declare which it follows so the shop and the inspector interpret the symbols the same way.

Where to apply GD&T

Use GD&T where the function depends on the geometry relationship, not on every feature. A locating pin hole, a bearing seat, a sealing face, and a bolt pattern across mating parts all benefit from geometric control, because their function is about position and relationship, not just size. A cosmetic fillet or a non-mating face does not need it, and adding it there only complicates the drawing and the inspection plan. The discipline is to apply geometric control to the features that affect fit, assembly, or function, and to let size tolerance with the general class govern the rest.

Reading and checking a drawing

Before a drawing goes out, read it as the shop and the inspector will, and check it against the function of the part.

Self-check of the drawing contents

Confirm that every critical feature is dimensioned from a datum and carries the tolerance it needs, and that no critical dimension is missing or implied. Confirm that the general tolerance class is in the title block and that the units are stated. Confirm that the surface finish callouts sit only on the features that need them, and that the threads carry their standard, size, class, and depth. Confirm that the notes block covers the processing the part needs, such as deburring or passivation, and that the revision matches the model. A drawing that passes this self-check quotes faster and builds more reliably, because the shop reads a complete, unambiguous contract instead of a set of guesses.

Worst-case stack check

A second useful check is the worst-case stack. Trace the dimension chain for each critical fit, add the bands, and confirm the stack still assembles at the extremes. If a chain of five plus-minus dimensions can stack past the clearance a mating part needs, the drawing is asking for a fit failure, and the fix is to shorten the chain, switch to baseline dimensioning, or call out the position with GD&T. This check is cheap at the drawing stage and expensive after parts are made, so it belongs in the drawing review, not in the first-article inspection.

Checklist

  • Title block: material and temper, finish, units, revision, and general tolerance class.
  • Critical dimensions toleranced from a datum, with baseline dimensioning where stack-up matters.
  • GD&T on functional fits, positions, and runout so inspection repeats.
  • Surface finish (Ra) called out only where function needs it.
  • Threads specified by standard, size, class of fit, and depth.
  • Notes block for processing such as deburr, passivate, or anodize.

Common drawing mistakes

  • Leaving the general tolerance class out of the title block, so untoleranced dimensions default to whatever the shop assumes.
  • Chain-dimensioning critical features, which lets tolerance stack to a fit failure at the end of the chain.
  • Calling fine Ra on every surface, which adds grinding or lapping cost where the part does not need it.
  • Specifying threads by size only, leaving out the standard, class, or depth, so the shop guesses the fit.
  • Omitting the material temper, which changes both properties and machinability.
  • Forgetting units, which can scale the part 25.4 times between inches and millimetres.

Design rules

  • Dimension from a consistent datum and use GD&T (ASME Y14.5 or ISO 1101) for critical fits, position, and runout, so inspection is repeatable across suppliers.
  • Include a title block with material and temper, finish, units, revision, and the general tolerance class, and add a notes block for processing such as deburr, passivate, or anodize.
  • Specify surface finish (Ra) only where it matters, such as bearing surfaces and seal mates, and leave the rest as-machined to avoid unnecessary grinding cost.
  • State the thread standard, size, class of fit, and depth for every threaded feature, so the shop cuts the right thread on the first pass.

File format guidance

  • Provide the drawing as a PDF, which is universal, alongside the STEP model, and make sure the drawing units and the model units match and are both stated.
  • Always specify units. A file or drawing without explicit units is read against the supplier default and can produce parts at the wrong scale, a 25.4-times error between inches and millimetres.
  • Keep the drawing revision tied to the model revision, so a shop never builds to a drawing that no longer matches the geometry it was sent.
  • Send the drawing and the model as a matched pair and name them together, so a shop always opens the right combination. A drawing that drifted from its model is one of the most common sources of a bad first article, because the part is built and inspected to a contract that no longer describes the intended geometry, and the error often surfaces only at assembly.
  • Keep the drawing legible at the size it will be printed or viewed. A drawing crowded with tiny dimensions, leaders that cross, or notes crammed into a corner is hard to read and easy to misinterpret, so give critical features room, keep leaders from crossing, and let the title block and notes sit in a consistent, readable place. Legibility is part of accuracy: a tolerance the shop misreads is as bad as a tolerance left out.

Tolerances

  • General tolerances follow ISO 2768-1 for linear dimensions and ISO 2768-2 for geometric ones, declared as a class such as ISO 2768-mK in the title block. Apply tighter tolerances only to critical features and show them explicitly on the dimension.
  • Separate size tolerance from geometry tolerance. A bore can sit inside its size band and still fail to seal if its form (roundness, cylindricity) is out, so call out the geometry control that protects the function, not just the size.

Frequently asked questions

Do I need GD&T?
For critical fits, position, and runout, yes. GD&T (ASME Y14.5 or ISO 1101) makes inspection repeatable across suppliers. Simple parts with only size tolerances may not need it.
What goes in the title block?
Material and temper, surface finish, units, drawing revision, and the general tolerance class, such as ISO 2768-mK. Add a notes block for processing like deburring, passivation, or anodizing.
Should every surface have a finish callout?
No. Specify Ra only where function needs it, such as bearing or seal surfaces. Over-specifying finish adds grinding or lapping cost where the part does not need it.
What is a datum and why does it matter?
A datum is a fixed feature, surface, or axis the part is dimensioned from. Dimensioning critical features from a datum makes inspection repeatable across suppliers and machines, because every measurement traces back to the same reference.
How do I stop tolerance stack-up?
Avoid chain-dimensioning, where each dimension follows the last and the bands add up. Use baseline dimensioning from the datum for critical features, and call out position or profile with GD&T where a fit depends on the accumulated dimension.
How should I specify a thread?
Give the standard, the size, the class of fit, and the depth, for example M8 x 1.25 - 6H, 15mm deep. A thread specified by size alone leaves the shop to guess the fit and the depth.
Why state the material temper on the drawing?
Because the temper changes both the properties and the machinability. Aluminum 6061 in T6 machines and performs differently from the O temper, and the shop sets feeds and tooling to the temper, so naming it prevents a wrong assumption.
PDF or native CAD for the drawing?
Send a PDF drawing, which every shop can read, alongside the STEP model. Keep the drawing revision tied to the model revision, and make sure the units on both match and are stated.

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