Product Guides
Linear Bearing Guide: Types, Sizes & How to Choose
Linear bearings sit behind a lot of machinery that most people never think about — the slide on a CNC router, the vertical axis on a pick-and-place machine, the transfer carriage in a packaging line. They do one job: allow controlled, low-friction movement along a fixed path. Get the selection right and they run quietly for years. Get it wrong and you'll be replacing them inside a year under real load. This guide covers what linear bearings are, how they work, the different types available, and how to select the right bearing for the shaft size, load, and environment. It's aimed at maintenance fitters, machine builders, and anyone sourcing replacements or specifying new linear motion components for industrial equipment. What Is a Linear Bearing? A linear bearing is a bearing designed to allow movement in a straight line — along an axis — rather than rotational movement. Unlike a radial ball bearing, which supports a rotating shaft, a linear bearing supports and guides a shaft or rail that moves back and forth in a straight path. The standard recirculating ball linear bearing (the LM series used in automation, CNC, and industrial equipment) consists of an outer steel cylinder housing a recirculating track of ball bearings. As the bearing moves along a hardened steel shaft, the balls roll along the shaft surface and recirculate through internal return channels, maintaining continuous contact with minimal friction throughout the stroke. The result is a bearing that can traverse a shaft repeatedly with very low rolling friction — typically a coefficient of friction of 0.001 to 0.004, compared to 0.10 to 0.15 for plain sliding contact. This makes recirculating ball linear bearings suitable for high-speed, precise, and repetitive linear motion applications. How Does a Linear Bearing Work? In a recirculating ball linear bearing, a series of ball bearings sit within internal raceways arranged in rows along the bearing body. As the bearing moves along the shaft, the balls in contact with the shaft roll and are channelled through a return passage inside the bearing housing, bringing them back to re-enter the loaded zone. This recirculation means the bearing can traverse an unlimited stroke — unlike a simple ball cage, which can only travel as far as the balls allow. The recirculating design is what enables the LM bearing series to support high loads and long strokes in machinery. The key to performance is the hardened shaft. Standard linear bearings require a case-hardened shaft of SUJ2 bearing steel (equivalent to AISI 52100) ground to an h6 tolerance and surface-hardened to HRC 60–62. A soft shaft or an incorrectly sized shaft will result in rapid wear and premature failure — the shaft, not the bearing, is often the first component to fail in poorly specified systems. Types of Linear Bearings Three main categories of linear bearing are in common use in industrial and automation applications, each with different performance characteristics. Recirculating Ball Linear Bearings (LM Series) The LM series — also referred to as ball bushings or linear ball bearings — is the dominant type for general industrial and automation use. These are the cylindrical bearings pressed into a housing bore, designed to slide along a round hardened steel shaft. They are available in standard (UU — double-sealed) and open configurations. The LM designation follows a straightforward naming convention. The number indicates the bore diameter in millimetres (matching the shaft diameter). The suffix indicates the sealing and length variant: No suffix: open bearing — no end seals, requires regular lubrication U: single rubber seal on one end UU: double rubber seals — one on each end — the standard for most applications L: long version — extended length for higher load capacity and moment resistance LUU: long version with double seals So an LM12UU is a 12mm bore, double-sealed, standard-length linear bearing. An LM25LUU is a 25mm bore, double-sealed, long version. LM series bearings are precision components — housing bore and shaft diameter tolerances must be within specification for the bearing to perform correctly. A housing bore to H7 tolerance and a shaft to h6 tolerance is the standard pairing for a light interference fit in the housing and a sliding fit on the shaft. Plain and Polymer Linear Bearings Plain linear bearings — also called linear bushings or sleeve bearings — replace the recirculating ball mechanism with a sliding contact surface. The bearing slides directly along the shaft with no rolling elements. Bronze and sintered bronze bearings are self-lubricating — oil is impregnated into the porous metal structure and is released under load. They are robust, tolerant of misalignment, and can operate in environments where contamination would destroy a recirculating ball bearing. Load capacity per unit length is lower than LM series, but they handle shock loads and misalignment better. Polymer plain bearings — of which the igus drylin system is the most well-known in AU — are made from engineered polymers with embedded solid lubricants. They require no grease or oil, are corrosion-resistant, and tolerate dust, moisture, and light contamination. They are widely used in food processing, pharmaceutical manufacturing, and outdoor machinery where contamination of lubricants is a concern and where metal-on-metal contact is undesirable. The trade-off with polymer bearings is load capacity (lower than recirculating ball) and dimensional sensitivity (coefficient of thermal expansion is higher than steel — clearances must account for temperature variation). They are also less suitable for high-speed applications where heat generation at the sliding contact becomes a limiting factor. Linear Guide Rails (Profiled Rail Systems) Linear guide rails — THK, Hiwin, Bosch Rexroth, and similar — are a fundamentally different architecture. Instead of a cylindrical bearing running on a round shaft, a profiled steel rail carries a precision-machined carriage block. Multiple rows of recirculating balls or rollers sit between the carriage and the rail, providing high load capacity in all directions (radial, reverse radial, and lateral). Linear guide rails offer significantly higher load ratings than round shaft LM bearings, better moment capacity, and higher stiffness. They are the standard choice for machine tools, precision machining centres, and high-load automation where LM bearings would be undersized. The trade-off is cost and installation precision — rail surfaces must be ground flat to within fractions of a millimetre, and the carriage preload must be correctly specified for the application. They are not a drop-in substitute for round shaft bearings; they require precision mounting surfaces and correct rail alignment. LM Series Sizing Guide The table below covers the standard LM series range with principal dimensions. All dimensions are in millimetres. Load ratings are approximate dynamic load ratings (C) for standard-length UU variants — actual ratings vary by manufacturer. Designation Bore (mm) OD (mm) Length (mm) Long (LUU) Length (mm) Approx. C (kN) LM6UU 6 12 19 35 0.5 LM8UU 8 15 24 45 1.4 LM10UU 10 19 29 55 2.2 LM12UU 12 21 30 57 3.2 LM16UU 16 28 37 70 5.6 LM20UU 20 32 42 80 9.4 LM25UU 25 40 59 112 16.2 LM30UU 30 45 64 123 22.0 LM35UU 35 52 70 134 32.0 LM40UU 40 60 80 154 42.0 LM50UU 50 75 100 192 68.0 LM60UU 60 90 125 240 100.0 LM80UU 80 120 165 320 196.0 The most common sizes in Australian industrial maintenance and automation are LM8UU (used extensively in 3D printers, small CNC machines, and light automation), LM12UU through LM20UU (general automation, transfer mechanisms), and LM25UU through LM40UU (heavier machinery, industrial slides, and transfer carriages). Load Ratings Explained Linear bearing datasheets specify two load ratings: dynamic load rating (C) and static load rating (C0). Understanding the difference matters when specifying or replacing a bearing under real load. Dynamic load rating (C) is the load under which a bearing will achieve a rated travel life — typically expressed in kilometres of travel. The ISO standard for linear bearings uses 50km as the reference life (L10 = 50km at 90% reliability). Dynamic load rating is used for applications with continuous or frequent reciprocating movement — conveyor slides, transfer mechanisms, robotic axes. Static load rating (C0) is the maximum load the bearing can support without permanent deformation of the balls or raceway. Static load rating applies to applications where the bearing is stationary under load, or where shock loading occurs. For applications with infrequent movement and high static loads, C0 is the relevant figure — not C. The basic travel life calculation follows the ISO formula: L = (C/P)³ × 50, where L is life in km, C is dynamic load rating in kN, and P is the applied load in kN. Halving the applied load increases travel life by approximately eight times — load management has a disproportionate effect on bearing life. For critical applications, a safety factor of 2–3 applied to the calculated load is standard practice in industrial machine design. This accounts for shock loads, vibration, misalignment, and acceleration forces that are difficult to quantify precisely in real-world machinery. What Rail Material Is Best for Linear Bearings? For standard recirculating ball linear bearings (LM series), the shaft must be a hardened steel rod — not mild steel, not aluminium, not stainless. The minimum surface hardness requirement is HRC 58. The standard shaft material is SUJ2 bearing steel (JIS standard), equivalent to AISI 52100 / EN 31. It is case-hardened to HRC 60–62 and ground to h6 tolerance. The practical answer is: buy matched shafts from the same supplier as the bearings. Using a mild steel rod as an improvised shaft will result in shaft wear, not bearing wear — the shaft surface will be scored within a short period of use. This is the most common installation error encountered in the field. Chrome-plated shafts are also commonly available. Chrome plating adds corrosion resistance to the hardened steel core — useful for applications where condensation or light moisture is present. The chrome layer is typically 10–25 microns and does not significantly change shaft dimensions for standard bearing fit. Chrome-plated shafts are appropriate for food processing, marine, and washdown environments. Stainless steel shafts are available for corrosive environments but require careful selection — standard austenitic stainless (304, 316) is too soft and will score. Martensitic stainless or specially hardened stainless grades are required for LM series bearings. Confirm hardness ≥ HRC 58 before specifying stainless shafts with standard LM bearings. For polymer plain bearings (igus drylin), the shaft material options are broader — anodised aluminium shafts, hard-chrome steel, and stainless all work because the polymer sliding contact is self-lubricating and less demanding on shaft hardness than recirculating balls. This is one of the practical advantages of polymer systems in environments where sourcing and maintaining hardened steel shafts is difficult. Sealed vs Open Linear Bearings The sealing suffix on LM bearings indicates the type and number of end seals: Open bearings (no suffix) have no end seals. Grease can be applied directly into the ball track from the ends. They are used in clean, controlled environments where regular maintenance is possible — precision machine tools, enclosed enclosures, applications where the bearing can be accessed frequently for relubrication. Open bearings are also used where compact installation length is critical. Single-seal (U) bearings have one rubber lip seal on one end. Partial protection — useful where contamination approaches from one direction only. Less common in standard practice. Double-seal (UU) bearings have rubber lip seals on both ends. This is the standard specification for general industrial use. The seals retain grease inside the bearing and exclude dust, swarf, and light contamination from entering the ball track. For most maintenance replacement applications, UU is the correct choice — it requires less frequent relubrication and is more tolerant of imperfect environments. The UU suffix seals are contact lip seals — they provide good retention but add a small amount of friction compared to an open bearing. In high-speed applications (linear speed >2 m/s consistently), this friction can become relevant. For standard industrial speeds (typically <0.5 m/s in most maintenance applications), it is not a practical concern. Can Linear Bearings Be Used Vertically? Yes. Linear bearings can be used in any orientation — horizontal, vertical, or at any angle. The bearing mechanism functions identically regardless of orientation. The considerations specific to vertical applications are: Load direction: In a vertical application, the weight of the moving element (carriage, toolhead, gripper assembly) acts as a constant downward load throughout the stroke. The bearing must be rated for this load — check that the applied load is within the dynamic load rating under continuous operation. For heavy vertical loads with long strokes, the long LUU version increases load rating and improves moment resistance. Grease retention: Gravity draws grease downward in a vertical orientation. In sealed (UU) bearings, this is largely managed by the end seals. For open bearings used vertically, more frequent relubrication of the upper end of the bearing may be required, as grease migrates away from the upper contact zone over time. This is a practical issue in long-service vertical applications — not a barrier to use, but a maintenance consideration. Self-weight of the carriage under power loss: In vertical systems where the carriage is power-driven, consider what happens if power is lost and the drive disengages. The carriage will travel under gravity at whatever speed the linear bearing permits. If this is a hazard, a brake or counterbalance must be part of the system design — the linear bearing itself does not provide resistance to free travel. This is a system design issue, not a bearing limitation. Polymer vs Recirculating Ball: Which Should You Choose? The choice between polymer plain bearings and recirculating ball bearings depends on the operating environment, load, speed, and maintenance context. There is no universal answer — both types are in widespread use in Australian industry for valid reasons. Choose recirculating ball (LM series) when: Precision of positioning matters — LM bearings have tighter running clearance and better repeatability High speed is required — rolling contact handles higher linear speeds with less heat generation Load capacity is critical — LM series outperforms polymer by a significant margin per unit size The environment is clean and controlled — lubricant contamination is not a concern The application is standard automation, CNC, 3D printing, or transfer machinery Choose polymer plain bearings when: Maintenance access is difficult or infrequent — polymer runs dry indefinitely, no relubrication required The environment is wet, dusty, or contaminated with food products, cleaning agents, or fine particles that would contaminate lubricant Corrosion resistance is required — polymer and anodised aluminium shafts can be used where steel would corrode Noise is a constraint — polymer bearings are quieter than recirculating ball bearings in service The application is outdoor, agricultural, or food processing The forum consensus among engineers on r/3Dprinting and r/robotics is that recirculating ball bearings (LM series) win on precision and speed, while polymer bearings win on reliability in contaminated or maintenance-inaccessible environments. Both assessments are correct for their respective contexts — the selection decision should be driven by the operating environment and maintenance reality, not by cost alone. Moment Loading and Minimum Bearing Span A linear bearing loaded purely in the radial direction (load perpendicular to shaft, no offset) is in its optimal loading condition. Moment loading — where the applied load creates a turning force about the bearing — reduces the effective load capacity significantly and must be accounted for in design. Moment loads arise when: the load point is offset from the bearing centreline, a single bearing supports a cantilevered load, or acceleration forces act on a load with a centre of mass offset from the shaft axis. In engineering terms, moment load (M) = applied force (F) × offset distance (L). The standard practice for managing moment loads is to use two bearings per shaft, spaced as far apart as the application allows. Increasing the bearing span by a factor of 2 reduces the effective moment on each bearing by a factor of 2. For heavily cantilevered loads, LUU (long) bearings are preferred over standard-length bearings — the longer bearing body distributes moment force over more ball contact points. For critical applications with significant moment loading, a profiled linear guide rail system (THK/Hiwin style) is more appropriate than LM round shaft bearings — the four-way load capacity of a profiled rail carriage handles moment loading far more effectively than a round shaft bearing can. Installation and Alignment Correct installation is the single biggest factor in linear bearing service life after correct sizing. The most common causes of premature failure are not bearing defects — they are installation errors. Housing bore tolerance: The housing bore must be machined to H7 tolerance for a standard LM bearing. A bore that is too tight will crush the outer race and reduce internal clearance, causing the bearing to run rough or seize. A bore that is too loose will allow the bearing to spin in the housing under load, causing housing wear and eventual loss of positional accuracy. Do not attempt to compensate for an oversized bore with adhesive alone — re-machine the housing or use an interference-fit sleeve. Press fitting: Always press on the outer race — never the inner race or balls. Pressing on the inner race forces the load through the balls, which can indent the raceways and cause premature failure. Use a mandrel or press tool that contacts only the outer ring end face. A soft mallet against a properly fitting mandrel is acceptable for light-interference installations. Shaft alignment: Two parallel shafts (as in a twin-shaft gantry or slide) must be parallel within the manufacturer's specified tolerance — typically 0.05 to 0.1mm over the full shaft length. Misalignment creates a pre-load on the bearings throughout the stroke, drastically reducing service life and increasing operating force. If the carriage feels stiff or jerky when moved by hand with no external load applied, misalignment or housing bore error is the cause. For applications requiring precision shimming of shaft supports to achieve correct alignment, refer to the AIMS industrial shim guide — shim stock selection and material considerations apply directly to linear motion system alignment work. Shaft support spacing: Support the shaft at intervals appropriate to its diameter and expected load. Unsupported shaft spans that are too long will allow the shaft to deflect under load, creating a curved travel path that overloads the bearing in the deflection zone. As a general guideline, the support span should not exceed 40–60 times the shaft diameter for standard industrial loads — shorter spans for heavier loads or higher speed applications. Lubrication and Maintenance Recirculating ball linear bearings require lubrication to protect the ball-to-raceway contact surfaces. Without adequate lubrication, the Hertzian contact stress at ball-to-raceway interfaces causes surface fatigue and early failure — typically spalling of the raceway surface. Grease: NLGI 2 lithium-based grease is the standard specification for sealed LM bearings in general industrial applications. Apply a small amount of grease through the nipple fitting (if present) or by removing the end seal and applying directly. Grease quantity matters — over-packing creates churning resistance and heat; under-packing starves the contact. As a general guide, fill approximately one-third of the internal free space. Oil: Light machine oil (ISO VG 32 or VG 46) is used in applications where grease would be displaced by high-speed recirculation, or where the bearing is part of an oil recirculation system. Oil-lubricated open bearings require more frequent replenishment than grease-lubricated sealed bearings. Relubrication intervals: For general industrial applications with sealed UU bearings under moderate load and speed (linear speed <0.5 m/s, load <30% of rated capacity), a relubrication interval of 6–12 months is a reasonable starting point. Increase frequency for higher speeds, higher loads, elevated temperature, or contaminated environments. The symptom of inadequate lubrication is increased operating noise — a clicking or grinding sound that develops gradually as the bearing surface deteriorates. For open bearings or applications in contaminated environments, a penetrating lubricant used as a maintenance flush (to clear contamination before regreasing) can extend bearing life between full replacements. See the AIMS penetrating oil guide for product selection by application context. Polymer plain bearings: Require no lubrication — self-lubricating material releases lubricant under load from the bearing matrix. Do not apply grease or oil to polymer bearings — it attracts dirt, which then acts as an abrasive and accelerates wear. Keep polymer bearings dry and clean. Common Failure Modes and How to Identify Them Understanding how a linear bearing fails helps in diagnosing cause and preventing recurrence in the replacement bearing. Spalling (raceway fatigue): Surface flaking of the raceway or ball surface. Appears as a rough, irregular texture in the ball track zone. Cause: fatigue under load — normal end-of-life mode if the bearing has reached its rated travel life. Premature spalling indicates overloading, contamination, or inadequate lubrication. Scoring and scratching: Linear grooves in the raceway or shaft surface running parallel to the shaft axis. Cause: contamination — hard particles (swarf, grit, debris) trapped between balls and raceway. Prevention: sealed bearings (UU), shaft wipers, and cleaner operating environment. Replacement of the shaft may also be required if the scoring is significant. Pitting and corrosion: Rust pitting on balls or raceway. Cause: moisture ingress into the bearing — condensation in a closed environment, washdown without sealed bearings, or inadequate sealing. Prevention: chrome-plated shafts, sealed UU bearings, stainless variants for extreme environments, and correct storage (bearings stored in factory packaging with desiccant until installation). False brinelling: Evenly spaced indentations in the raceway matching ball spacing. Cause: vibration while stationary — the bearing oscillates slightly under vibration without full rolling motion, causing Hertzian contact damage at rest positions. Common in machinery shipped long distances or stored adjacent to vibrating equipment. Prevention: store and transport with shaft in place or with a dummy shaft through the bearing; isolate from vibration during storage. Excessive noise: Clicking, rattling, or grinding during travel. Cause: contamination, inadequate lubrication, overloading, or worn raceways. If a bearing that previously ran quietly begins to produce noise under unchanged operating conditions, check lubrication first — then inspect for contamination. If noise persists after relubrication, replacement is the correct action. Sourcing Linear Bearings in Australia The LM series is globally standardised — an LM12UU from any reputable manufacturer (THK, NSK, Hiwin, IKO, PMI) will have the same external dimensions and is interchangeable with any housing machined to H7 bore tolerance. This standardisation means replacement sourcing is straightforward: you need the designation, not the brand. For rotating bearings in the drive systems that pair with linear motion assemblies — motor end-shield bearings, gearbox bearings, idler shafts — the AIMS Bearing Cross Reference Guide decodes SKF, NSK, NTN, FAG, Koyo, NACHI and other brand designations for those components. Quality variation exists between manufacturers. Precision grade (P5 or P4) bearings from major Japanese and Taiwanese manufacturers hold tighter tolerances than standard-grade economy bearings. For precision CNC applications or medical/food processing machinery, specify the precision grade. For general industrial slides, transfer carriages, and maintenance replacements, standard grade is adequate and represents significantly better value. For LM8UU through LM40UU, same-day or next-day availability from industrial bearing suppliers in Australia is typical for standard UU variants. LUU (long) versions and larger sizes (LM50UU and above) may require 2–5 working days. Linear guide rail systems (THK, Hiwin) generally require longer lead times if not held in local stock — confirm availability before committing to a design that depends on them. Frequently Asked Questions How does a linear bearing work? A linear bearing allows controlled, low-friction movement along a straight path. In the most common type — the recirculating ball linear bearing (LM series) — a series of steel balls sits in internal raceways within the bearing body. As the bearing moves along a hardened steel shaft, the balls roll along the shaft surface and recirculate through internal return channels, maintaining continuous contact. This rolling contact produces very low friction (typically 0.001–0.004 coefficient of friction) compared to plain sliding contact, making it suitable for high-speed, precise, and repetitive linear motion applications. What are the different types of linear bearings? The three main categories are: recirculating ball linear bearings (LM series — cylindrical bearings running on round hardened steel shafts, the most common type in automation and industrial equipment), polymer or plain linear bearings (self-lubricating bushings for contaminated or maintenance-inaccessible environments), and linear guide rail systems (profiled steel rails with recirculating ball or roller carriages, used for high-load and high-precision machine tool applications). Each type suits different load, speed, precision, and environmental requirements. Can linear bearings be used vertically? Yes. Linear bearings operate correctly in any orientation — horizontal, vertical, or at an angle. In vertical applications, the bearing must be rated to support the weight of the moving element as a continuous load. Grease retention in sealed bearings (UU) is generally adequate for vertical use, though open bearings in vertical orientation may require more frequent relubrication of the upper end as gravity draws grease downward over time. The bearing itself does not resist free travel under gravity — if power loss would allow an unsupported carriage to fall, a brake or counterbalance must be part of the system design. What does LM8UU mean? LM8UU is the designation for a specific linear bearing. LM stands for Linear Motion. The number (8) is the bore diameter in millimetres — this must match the shaft diameter. UU indicates double rubber end seals on both ends of the bearing, which retain grease and exclude contamination. The standard LM8UU has a bore of 8mm, outer diameter of 15mm, and length of 24mm. An LM8LUU is the long version of the same bearing, with a length of 45mm for higher load capacity. What is the difference between LM and LME bearings? LME bearings are a metric variant of the LM series common in European machinery. They have the same bore diameter as the equivalent LM bearing but different outer dimensions — the outer diameter and length follow European metric standards rather than the JIS (Japanese Industrial Standard) used for the LM series. LM and LME bearings are not directly interchangeable if the housing bore has been machined to a specific series. When replacing a bearing, confirm whether the housing was designed for LM or LME dimensions before ordering. LM series is the more common format in Australian industrial equipment and automation. How do I choose the right size linear bearing? Start with the shaft diameter — the bore of the bearing must match the shaft. Then check the dynamic load rating (C) of the candidate bearing against your application load with a suitable safety factor (2–3× for industrial applications). If the standard-length bearing is marginal on load capacity, move to the long (LUU) version of the same bore size. For applications with significant moment loading (offset loads, cantilevered carriages), use two bearings per shaft spaced as far apart as practical. If your calculated load exceeds what the LM series can handle at the required bore size, consider a linear guide rail system instead. What is the difference between polymer and recirculating ball linear bearings? Recirculating ball bearings (LM series) use rolling ball contact for very low friction, high load capacity, and high precision. They require lubrication and are sensitive to contamination. Polymer bearings (igus drylin and similar) use a self-lubricating polymer sliding contact — they require no grease, tolerate contamination and moisture, and are corrosion-resistant, but have lower load capacity and are less precise. Choose recirculating ball for standard automation, CNC, and precision applications in clean environments. Choose polymer for food processing, outdoor, washdown, or maintenance-inaccessible applications where contamination of lubricant is a real concern. How long do linear bearings last? Service life depends on load, speed, lubrication, and contamination. The ISO standard reference life is 50km of travel at 90% reliability under rated dynamic load (C). Reducing the applied load significantly extends life — halving the load increases travel life by approximately eight times (life scales with the cube of the load ratio). In a well-maintained, correctly loaded industrial application, LM series bearings routinely achieve hundreds of kilometres of travel. Common causes of early failure are contamination (swarf, grit), inadequate lubrication, overloading, and misalignment — none of which are inherent bearing weaknesses. Do linear bearings need lubrication? Recirculating ball linear bearings (LM series) do require lubrication. Without lubricant, the ball-to-raceway contact stress causes surface fatigue and early failure. NLGI 2 lithium grease is standard for sealed bearings in general industrial use. Sealed UU bearings come pre-greased and require periodic relubrication (typically every 6–12 months under moderate conditions). Open bearings require more frequent attention. Polymer plain bearings (igus drylin) are self-lubricating and do not require — and should not receive — added grease or oil. What causes linear bearings to fail early? The most common causes of premature linear bearing failure are: contamination (swarf, grit, or abrasive particles entering the ball track — prevented by sealed UU bearings and clean installation), inadequate lubrication (dry contact causes rapid raceway fatigue — maintain correct relubrication intervals), incorrect shaft hardness (using a mild steel rod instead of hardened SUJ2 bearing shaft — the shaft wears rapidly and destroys the bearing), misalignment (parallel shafts out of alignment create a pre-load throughout the stroke, drastically reducing life), and overloading (exceeding the dynamic load rating — always apply a 2–3× safety factor). What is a linear guide rail and how does it differ from a linear bearing? A linear guide rail is a profiled steel rail paired with a precision carriage block — as used in machine tools, CNC machining centres, and precision automation. Multiple rows of recirculating balls or rollers between the carriage and rail provide high load capacity in all directions, including moments. A standard round-shaft LM linear bearing runs on a cylindrical shaft and handles radial loads and limited moments. Linear guide rails offer significantly higher stiffness, load capacity, and moment resistance than round shaft bearings, but require precision ground mounting surfaces and carry a higher cost. They are the correct choice for heavy machine tool applications; LM round shaft bearings suit lighter automation and general industrial use. What is the correct housing bore tolerance for LM linear bearings? The standard housing bore tolerance for LM series linear bearings is H7 (for example, an LM12UU with 21mm OD requires a housing bore of 21mm H7). H7 provides a light interference fit between the bearing outer race and the housing, preventing the bearing from rotating in the housing under load. A bore machined too tight will crush the outer race and cause the bearing to run rough or seize. A bore too loose allows the bearing to spin in the housing, wearing both components. Do not attempt to compensate for an oversized bore by applying adhesive alone — the housing must be correctly sized for the bearing to perform as specified. For GD&T symbols and their meanings under Australian and international standards, see our GD&T Symbols Guide. AIMS Industrial stocks loc-line — see the full range for trade and industrial use.
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Industrial Shim Guide: Types, Materials & How to Choose
What is a shim? A shim is a thin precision-cut spacer used to align, level, or take up clearance between two mating parts. Common applications include aligning pump-to-motor couplings, levelling machinery baseplates, setting bearing preload, taking up wear in journal bearings, and adjusting press-tool die height. Industrial shims come as flat sheets, pre-cut slotted shapes (for in-situ installation under bolted feet), or laminated peelable stacks where individual layers can be removed to fine-tune thickness. A shim is one of the most underrated items in a maintenance fitter's toolkit. Half a millimetre of steel — cut from a roll and slipped under a motor foot — is the difference between a pump that runs reliably for five years and one that consumes bearings every six months. In construction, a plastic packer wedged under a door frame costs almost nothing and saves a door that would never hang correctly. In a precision engine, a valve shim ground to 0.025 mm changes everything about how that engine performs. Despite their simplicity, shims are widely misunderstood. People confuse them with washers and spacers. They stack too many. They reach for a cedar wedge when the job needs precision steel. They choose the wrong material for the environment — and end up with corroded steel in a food plant or deformed plastic under a two-tonne motor. This guide covers the full picture: what shims are, how they differ from washers and spacers, every type you will encounter in Australian industry and construction, how to select the right material, how to choose and measure thickness, the rules around stacking, structural and load-bearing considerations, and specific applications from machinery alignment to excavator pins. Written for the Australian trade and industrial market, with products stocked at AIMS Industrial from Champion and Precision Brand. Shim Materials: Steel, Brass, Stainless & Plastic Compared — Quick Reference Material selection is where shim choices most often go wrong. The wrong material in the wrong environment corrodes, deforms, or introduces contamination. Material Strength Corrosion Resistance Relative Cost Best Applications Cold-rolled steel High Low — will rust Low General industrial, dry indoor environments, machinery alignment Stainless steel 304 High Excellent Medium Food processing, pharmaceutical, washdown environments Stainless steel 316 High Excellent (chloride) Medium–high Marine, coastal, chemical plant, chlorinated water Brass Medium Good (atmospheric) Medium Electrical equipment, precision instruments, non-magnetic applications Aluminium Low–medium Good Medium Aerospace, lightweight applications HDPE / PP plastic Low Excellent Very low Construction framing, door and window installation What Are Shims and What Do They Do? A shim is a thin, flat piece of material inserted between two surfaces to fill a gap, correct alignment, level a component, or achieve a precise fit. The principle is ancient — craftspeople have been using wedges and spacers to compensate for imperfect dimensions since before recorded engineering. The materials and tolerances are modern; the idea is not. The core function of a shim is to compensate for dimensional variation that cannot be designed or manufactured out of a system. No surface is perfectly flat. No concrete slab is perfectly level. No motor foot sits at exactly the right height after installation on a real-world base. Shims correct for the imperfection that engineering drawings assume away — they are the bridge between the ideal dimension and the actual one. In practice, shims perform four distinct functions: Gap filling — closing a space between two mating surfaces with precise control over the final gap dimension (e.g., head gasket shims, cylinder head shims, bearing cap shims) Alignment correction — raising or lowering one side of a machine to achieve shaft concentricity and angularity within specification (e.g., motor foot shimming, pump alignment, gearbox installation) Levelling — bringing a surface to a known datum, typically horizontal, so a machine or structure sits correctly (e.g., levelling a machine tool on a slab, a base plate for a column, a structural beam bearing) Preload and clearance adjustment — setting the force applied to a spring, bearing, or valve element (e.g., valve train shims for tappet clearance, differential bearing preload, hydraulic relief valve pressure setting) The applications span every industrial sector in Australia: manufacturing, food processing, mining, civil construction, marine, agricultural equipment, and automotive. Anywhere two components need to fit precisely — and the precision cannot be machined in after the fact — a shim is the answer. Shims are cheap. The consequence of getting them wrong is not. A misaligned motor on the wrong shim stack runs hot, vibrates, and fails prematurely. A door frame packed with a timber offcut shifts over time and the door sticks. A base plate shimmed with compressed plastic settles and the column goes out of plumb. Use the right shim for the job. Shims vs Washers vs Spacers: Key Differences Explained The confusion between these three items comes from appearance — they all look like flat things that go between surfaces. The function is where they diverge, and understanding the difference matters for selecting the right component. What a Washer Does A washer is a fastener component. Its job is to distribute the clamping load from a bolt head or nut across a larger surface area, preventing the fastener from embedding into soft material or pulling through a large hole. Spring washers (Belleville or helical) add a locking function. Repair washers have an oversized outer diameter for use with damaged holes. Washers are manufactured to loose dimensional tolerances — a standard flat washer to DIN 125 or AS 1237 has a nominal thickness but that thickness is not a precision measurement. You would never use a standard washer to fill a 0.15 mm gap — you have no reliable idea what thickness you are actually installing. Washers go under fasteners. They do not fill precision gaps. What a Spacer Does A spacer maintains a fixed, known distance between two components. Spacers are typically thicker than shims — often a machined cylindrical or tubular component — and their purpose is to hold components at a set distance during assembly. Wheel spacers on a vehicle hub, standoffs in an electronics enclosure, and bearing spacers in a gearbox are all spacers. They are not adjustable. They set a dimension and hold it. What a Shim Does A shim is the adjustment tool. It is manufactured to tight thickness tolerances specifically so that you can select — or cut to — the exact dimension you need to fill a measured gap or correct a measured misalignment. The tolerance of quality shim stock is plus or minus 0.003 mm or better. That is the whole point: you measure, you select, you trust the result. In summary: washer = distributes clamping load under a fastener. Spacer = holds components at a fixed set distance. Shim = fills a measured gap, corrects alignment, achieves a precise fit. There is one area where the terms overlap: in structural and heavy equipment work, a thick steel plate used under a base plate may be called a shim plate in some documentation even though it functions more like a spacer. What matters is the function — precision gap filling and adjustment — and selecting material manufactured to tight enough tolerances to do it reliably. Types of Shims: A Complete Overview The shim category is broader than most people realise. Understanding the different types — and what each is designed for — prevents the wrong type ending up in the wrong application. Shim Stock (Rolls and Flat Sheets) Shim stock is precision-rolled metal available in continuous rolls or flat sheets at controlled thicknesses. The user cuts the shim to any shape required — custom footprints, specific slot positions, unusual profiles. This is the most versatile shim format, and it is what most people mean when they refer to "shim stock." Standard widths for rolls are 150 mm or 300 mm. Sheet sizes vary by supplier — 300 × 300 mm and 300 × 600 mm are common. Thicknesses range from 0.025 mm (1 thou) to 3.0 mm or heavier, with a full range of intermediate gauges. AIMS stocks shim stock in cold-rolled steel, stainless steel 304 and 316, and brass from Precision Brand and Champion. Slotted Shims (Horseshoe Shims / Alignment Shims) Slotted shims — called horseshoe shims or U-shims in the trade — have a slot cut from one edge through to a central opening. The slot allows the shim to slide around a bolt or shaft without removing the fastener. You loosen the hold-down bolt, slide the shim stack in or out, then re-torque. This design is the standard for motor and machinery alignment work. The machine does not need to be completely disassembled to adjust the shim stack — a significant time saving on any alignment job. Slotted alignment shim kits include multiple thicknesses so the technician can build the required correction by stacking. AIMS stocks these kits for standard motor foot sizes. Tapered Shims A tapered shim has a wedge profile — thicker at one end, thinner at the other — giving a uniform taper across its length. Tapered shims are used to correct angular misalignment, where one side of a component sits higher than the other and a uniform-thickness shim would not resolve the angular error. They appear in structural steel work (under base plates on slightly sloped concrete), in some machinery installations, and in automotive applications. Two tapered shims pushed in from opposite ends create an effective shim of adjustable thickness — a useful field technique when standard thicknesses are not available. Laminated (Peelable) Shims Laminated shims consist of multiple thin metal layers bonded together into a single assembly. When the total assembled thickness is too much, individual layers are peeled off to reduce thickness — no cutting required. The precision of each remaining layer is maintained because the layers are controlled during manufacture. Laminated shims are used in production tooling, precision fixtures, and applications where fast, clean adjustment matters without the complexity of managing a loose multi-piece stack. They cost more than plain shim stock but eliminate several practical problems. Plastic Shim Packers (Construction Packers) Plastic packers — called shim packers in the Australian construction trade, or simply "packers" on site — are non-compressible plastic blocks used to level and align frames, windows, doors, and structural elements. Made from HDPE or polypropylene, they are moisture-resistant, do not rot, do not compress under construction loads, and are UV-stable. Plastic packers are stackable and come in standard widths (28 mm, 68 mm, 100 mm) and thicknesses from 1 mm to 20 mm. They are a construction-site daily consumable in Australia — every joinery and framing installation uses them. Valve Shims Valve shims are precision-ground discs used in overhead cam engines to set valve clearance (tappet clearance). They sit between the cam follower (bucket) and the valve stem end. The clearance is measured with a feeler gauge and the shim thickness is selected from a range — typically in increments of 0.025 mm or 0.05 mm — to bring the clearance within the manufacturer's specification. Brake Shims Brake shims are anti-squeal pads bonded to the back of disc brake pads, or inserted between the pad and the caliper piston. They dampen vibration and reduce brake noise. This is a specific automotive application outside AIMS's core industrial range but worth noting as a distinct shim category — a brake shim is not interchangeable with a machinery alignment shim. Cylinder Head and Gasket Shims In high-performance engine building, cylinder head shims adjust compression ratio or correct deck height after machining. They sit between the cylinder head and engine block, on top of the head gasket. These are precision components manufactured to very tight flatness and thickness specifications. Shim Materials: Steel, Brass, Stainless & Plastic Compared Material selection is where shim choices most often go wrong. The wrong material in the wrong environment corrodes, deforms, or introduces contamination. Here is a clear comparison of each material's properties and the applications they suit. Cold-Rolled Steel (CRS) Cold-rolled steel shim stock is the most widely used industrial shim material. It offers high compressive strength, consistent thickness tolerances, excellent formability, and low cost. The manufacturing process — rolling at room temperature — produces a smooth, bright surface finish and tight dimensional control. The limitation is corrosion: uncoated cold-rolled steel will rust in any environment with moisture, chemicals, or salt. In dry indoor environments, steel shims are the default choice. In outdoor, wet, chemical, or food-processing environments, upgrade to stainless steel. Stainless Steel 304 Grade 304 stainless steel (18% chromium, 8% nickel) handles water, most dilute acids and alkalis, organic compounds, and general industrial chemical exposure without significant corrosion. It is the standard material for food processing equipment, pharmaceutical plant, and any application requiring regular washdown with detergents or sanitisers. Stainless 304 shim stock costs roughly two to three times more than equivalent carbon steel, but in corrosive environments that cost premium pays back in reliability. Stainless Steel 316 Grade 316 adds 2–3% molybdenum to the 304 composition, providing superior resistance to chloride-induced pitting corrosion. 316 is the correct choice for marine environments, coastal installations, chlorinated water systems, and chemical plants handling chlorine compounds or strong acids. If the application involves salt water, seawater spray, or aggressive chloride exposure, use 316 — not 304. Brass Brass shim stock is non-magnetic, has good thermal and electrical conductivity, and is soft enough not to score or gall precision mating surfaces. These properties make brass the preferred choice in electrical switchgear, precision instruments, and any application where magnetism would cause problems. Brass is softer than steel — do not use brass shims in high-load structural applications where the shim must resist deformation under compressive stress. Aluminium Aluminium shim stock is lightweight, corrosion-resistant in most environments, and easy to cut and form. It is used in aerospace, automotive, and applications where weight matters. Its lower compressive strength makes it unsuitable for heavy-load industrial shimming — use steel for machinery. Plastic (HDPE and Polypropylene) HDPE packers are the construction trade standard for framing and window installation: non-compressible under typical construction loads, moisture-proof, rot-proof, and UV-stable. Polypropylene packers are slightly stiffer and more brittle in cold conditions. Neither is appropriate under heavy industrial equipment — use steel for any machine base shimming application. Material Strength Corrosion Resistance Relative Cost Best Applications Cold-rolled steel High Low — will rust Low General industrial, dry indoor environments, machinery alignment Stainless steel 304 High Excellent Medium Food processing, pharmaceutical, washdown environments Stainless steel 316 High Excellent (chloride) Medium–high Marine, coastal, chemical plant, chlorinated water Brass Medium Good (atmospheric) Medium Electrical equipment, precision instruments, non-magnetic applications Aluminium Low–medium Good Medium Aerospace, lightweight applications HDPE / PP plastic Low Excellent Very low Construction framing, door and window installation Shim Stock: What It Is and When to Use It Shim stock is the raw form of the shim world — precision-rolled metal that you cut to the exact size, shape, and configuration you need. When no standard off-the-shelf shim fits the job, shim stock is the answer. Why Tolerance Matters The defining characteristic of quality shim stock is thickness tolerance. Precision Brand shim stock maintains thickness within plus or minus 0.003 mm for fine gauges (0.025 mm to 0.25 mm) and plus or minus 0.005 mm for heavier gauges. This means a shim labelled 0.127 mm (5 thou) is reliably 0.124–0.130 mm — narrow enough that you can trust the measurement when stacking shims to reach a calculated alignment correction. Low-grade shim material with wide thickness tolerances undermines the whole point of precision shimming. If your 0.1 mm shim is actually anywhere from 0.095–0.108 mm, your alignment calculation is invalid from the start. Standard Thickness Range Shim stock is available across a wide range of thicknesses. The Australian trade uses both metric and imperial (thou) designations — both systems are in active use. Common thicknesses: 0.025 mm (1 thou) — ultra-fine adjustment, precision instruments, valve shims 0.050 mm (2 thou) — fine machinery alignment, bearing preload 0.075 mm (3 thou) — general alignment work 0.100 mm (4 thou) — general alignment, one of the most used sizes 0.125 mm (5 thou) — very common for motor foot shimming 0.150 mm (6 thou) — standard alignment thickness 0.175 mm (7 thou) — intermediate correction 0.250 mm (10 thou) — heavier correction 0.500 mm, 0.750 mm, 1.000 mm — structural shimming and base work 1.5 mm, 2.0 mm, 3.0 mm+ — heavy structural shimming, excavator pins Conversion note: 1 thou (thousandth of an inch) = 0.0254 mm. If your alignment software outputs results in thousandths of an inch, convert before selecting shims. Many experienced alignment technicians in Australia work in thou by preference — both units are entirely valid. Roll vs Sheet Rolls are better for operations that regularly cut custom shims — continuous supply, easier to handle when cutting strips or long narrow pieces. Flat sheets are more practical for one-off jobs and benchtop cutting — the stock lies flat without the spring-back tendency of a roll. Both formats are available from AIMS across steel, stainless, and brass. When to Use Shim Stock vs Pre-Cut Shims Use shim stock when: the required shim shape is non-standard, the slot position does not match standard slotted shims, a continuous strip is needed, or you need a specific material and thickness not available pre-cut. Use pre-cut slotted shims when: doing standard motor alignment, speed matters, or you are working from a kit. Shimming for Machinery Alignment and Levelling Machinery alignment is the most consequential application for precision shims in Australian manufacturing, processing, and mining. Motor-to-pump alignment, gearbox installation, compressor mounting, conveyor drive shimming — all depend on shims at the machine feet to achieve shaft concentricity and angularity within the coupling manufacturer's specification. Why Alignment Matters A misaligned coupling generates vibration, uneven bearing load distribution, elevated operating temperature, and accelerated seal and coupling wear. Industry data consistently attributes 50% or more of premature rotating machinery failures to misalignment. The bearing that should last 40,000 hours fails in 8,000. The mechanical seal rated for two years goes in six months. The coupling insert that should last years needs quarterly replacement. Proper shimming and alignment is one of the highest-return maintenance activities in any plant. The cost of a set of alignment shims and an hour of a technician's time is a fraction of the cost of a failed bearing, an emergency motor rewind, or unplanned production downtime. Types of Misalignment Shims Correct Parallel (offset) misalignment — shaft centrelines are parallel but offset from each other. Corrected by moving the motor sideways (horizontal) or shimming feet (vertical). Angular misalignment — shaft centrelines meet at an angle. Corrected by shimming the front or rear feet of the motor by different amounts to change the shaft angle. Most alignment jobs involve both types simultaneously. Laser alignment equipment measures both and calculates the exact shim thickness required at each of the four feet. The Alignment Shimming Process Soft foot check first — Loosen each hold-down bolt in turn and measure whether the machine lifts. Soft foot creates measurement errors that make alignment impossible to achieve cleanly. Correct it by shimming the lifting foot until all four feet sit solidly. Measure misalignment — Laser alignment equipment or dial indicators measure offset and angularity. Laser systems calculate the required shim corrections at each foot automatically. Select shims — Choose slotted shims in the required thickness, or stack to achieve the total correction. Keep stacks to three or fewer shims where possible. Insert and torque — Slacken the hold-down bolt, slide the shim in, re-torque to specification, re-measure. Repeat until within coupling tolerance. Document the result — Record the final shim stack at each foot, pre- and post-alignment readings, and date. This is the baseline for the next alignment check. Levelling a Machine Base For new machine installations on a concrete slab, steel shims bring the base plate to level before the void is grouted. Place shim stacks at each support point, level with a precision spirit level or laser level to within 0.05 mm/m or better, then fill the void with non-shrink epoxy grout. The shims become a permanent load-carrying component embedded in the grout. Shim Packers in Construction: Doors, Windows and Frames In the Australian construction trade, "shim packers" or simply "packers" are a daily site consumable on any framing, joinery, or window installation job. The term is distinctly Australian — in the UK they are called packing pieces; in the US, shims or shim wedges. In Australia, ask for packers or shim packers. Why Frames Need Shimming No wall opening or floor surface is perfect. Concrete slabs have surface variation. Wall studs bow slightly. Masonry openings are rarely square. To install a door or window correctly — plumb, level, and square — the frame must be adjusted to compensate for the imperfection of the opening it sits in. Packers fill the gap between the perfect frame and the imperfect opening, allowing precise control of position without modifying either. Getting this right matters: a door frame that is not plumb creates a door that swings open or closed on its own, or binds in the frame. A window sill that is not level causes water pooling. Two minutes spent correctly packing a frame saves significant remediation later. Door Frame Installation Place packers at hinge locations (every hinge position must be backed by a packer so the fixing screw goes into solid material behind the frame), at the strike plate location, and at the head. Start at the bottom: set the first packer to bring the bottom of the hinge jamb to plumb and level, then work upward. Check plumb on both jambs and level on the head before fixing permanently. Window Frame Installation Window sills must be level across their full width — check with a long level and shim up the low end. Jambs must be plumb — shim at the top and bottom of each jamb as needed. Use the same stackable approach: measure the gap at each packer position and select the combination of thicknesses that fills it without gaps or forcing. Standard Packer Sizes Widths: 28 mm, 68 mm, 100 mm — matching common stud and frame widths Thicknesses: 1 mm, 1.5 mm, 2 mm, 2.5 mm, 3 mm, 5 mm, 6 mm, 8 mm, 10 mm, 12 mm, 15 mm, 20 mm Length: typically 100 mm A practical site kit carries 1 mm, 2 mm, 3 mm, 5 mm, and 10 mm packers — which combine to hit any required thickness from 1 mm to 20 mm+ without needing every possible size. Colour-coding by thickness (common in quality packer ranges) makes grabbing the right packer fast without measuring each piece. Precision Shims for Engineering Applications Beyond construction and routine machinery alignment, shims perform critical functions in precision engineering — applications where tolerances are tight and errors have direct mechanical consequences. Valve Train Shimming In overhead cam engines — common in modern diesel and petrol equipment — valve clearance (often called "tappet clearance" in the Australian trade) is set by selecting a shim disc of the correct thickness between the cam follower and the valve stem end. The clearance is measured with a feeler gauge at the specified temperature (usually cold), the existing shim is measured with a micrometer, and the correct replacement is selected from a range covering typically 2.5 mm to 3.5 mm in 0.025 mm steps. Incorrect valve clearance causes noisy valve operation (too much clearance) or poor valve closing and potential burning (too little). This is not a task where close is good enough — which is why valve shims are manufactured to tolerances of plus or minus 0.01 mm or better. Bearing Preload Tapered roller bearings in differentials, wheel hubs, and gearboxes require a specific preload — a controlled compressive force applied during assembly. Shims or collapsible spacers set this preload during build. Too little preload and the bearing runs loose, generating noise and heat. Too much and it overloads and overheats. Setting bearing preload requires proper measurement (rolling torque method) and correct shim selection — not a feel-based approximation. Hydraulic Relief Valve Pressure Setting Pressure relief valves in hydraulic circuits use a spring-loaded element set by shims between the spring end and the valve body. Adding shims raises the relief pressure; removing shims lowers it. Adjustments of 0.1 mm per shim can change the relief pressure by several bar — making this a precision shim application despite its straightforward appearance. Machine Tool Calibration and Fixturing In CNC and manual machining, shims adjust cutting tool heights, align workholding fixtures to a known datum, and compensate for tool variation in production jigs. Required adjustments are often in the 0.01–0.1 mm range — achievable with quality shim stock and proper measurement. Shimming is the standard production-floor method for fine calibration adjustments without the cost and time of machining. How to Choose the Right Shim Thickness Choosing the right shim thickness starts with measurement — not estimation, and not by trying shims until one fits. Here is the process for getting it right. Step 1: Measure the Gap For gaps under 1 mm: Use a feeler gauge (thickness gauge). A feeler gauge set provides blades from 0.05 mm to 1.0 mm or more. Insert blades until the correct thickness is found — the blade should slide through with light, consistent drag. Intermediate gaps are bridged by stacking two blades. For gaps over 1 mm: Use a digital vernier caliper for direct measurement, or a dial test indicator against a known datum. For machinery alignment: Laser alignment equipment measures offset and angularity at the coupling and calculates the exact correction required at each machine foot. Shim selection follows from this calculation — no manual gap measurement is needed in modern laser alignment work. Step 2: Select or Build the Thickness If a single shim at the measured thickness is available, use it. If not, stack shims to achieve the total. Keep the number of pieces to three or fewer. For example, a 0.375 mm gap can be filled with three 0.125 mm shims, or with one 0.25 mm plus one 0.125 mm — the two-piece stack is more stable and easier to handle. Step 3: Test Fit Before Final Assembly Fit the shim or stack into the gap before final torquing. The shim should slide in with slight resistance — not fall in freely (under-size) and not require force (over-size). A shim that must be hammered in is deforming the gap it is supposed to fill precisely. Once the fit is confirmed, torque to specification and re-check the measurement after torquing, as bolting can shift the shim position slightly. Common Thickness Sets to Stock For a typical industrial maintenance situation, stocking 0.025, 0.050, 0.075, 0.100, 0.125, 0.150, 0.200, 0.250, 0.500, and 1.000 mm gives the flexibility to hit almost any required thickness within 0.025 mm by stacking. A slotted alignment shim kit from AIMS covers the range needed for motor foot shimming in ready-to-use horseshoe form. Can You Stack Shims? (and How Many Is Too Many) Yes — stacking shims is entirely acceptable and is standard practice in alignment and gap-filling work. The question is where the practical limit lies and how to do it correctly. Why Stacking Works Quality shim stock is rolled to a known thickness within a tight tolerance. Stacking three 0.125 mm shims gives a total of 0.375 mm, and because each individual shim is accurate to plus or minus 0.003 mm, the cumulative error of the stack is plus or minus 0.009 mm — well within the tolerance of most alignment applications. The dimensional accuracy of a properly stacked shim assembly is entirely adequate for the tasks shims are used for. Where Stacking Causes Problems The limitation of stacking is physical, not dimensional. As the stack grows: The stack becomes less stable under vibration and can shift, particularly if individual shims are not held firmly by the clamping load Slotted shims become harder to insert cleanly as the stack thickness increases In corrosive environments, individual shims can corrode together, making future removal difficult The total number of loose pieces increases — more opportunities for pieces to fall, be mislabelled, or end up in the wrong position during reassembly The Practical Rule Three to four shims maximum in a single stack for alignment and precision work. For corrections exceeding 3–4 mm, use a machined spacer plate or a single thick steel shim rather than a tall stack of thin ones. For corrections under 0.3 mm, a single shim is always better than two if one is available at the right thickness. Stacking Best Practices Place thicker shims at the bottom and thinner shims on top — stable base, fine adjustment at the top Use the same alloy throughout the stack — mixing carbon steel and stainless can lead to galvanic corrosion bonding them together in wet environments In outdoor or corrosive environments, apply a thin coat of anti-seize between shims to prevent bonding Mark the thickness of each shim with a permanent marker before assembly — you will need that information at the next service Consider laminated shims as an alternative to loose stacks for applications requiring fine, repeatable adjustment Are Shims Structural? Load-Bearing Considerations Steel shims carrying structural loads is not unusual — it is the designed intent in many applications. Column base plates, machine mounting pads, and structural steel connections all routinely use steel shims as permanent load-carrying components. The question is whether the right material is selected and whether the application is within its limits. Steel Shims in Structural Applications Cold-rolled steel and stainless steel shims have high compressive strength — well above the bearing stresses typically encountered in structural base plate connections or machinery mounting. A stack of steel shims under a bolted base plate, properly installed and grouted, is a permanent structural element that carries the full column or machine load. For structural steel work in Australia, AS 4100 (Steel Structures) governs base plate connections. Where shims are specified, they should be structural-grade steel, sized to fully cover the bearing area, and grouted in position after the structure is aligned. Check with the structural engineer for specific shim size and material requirements — these will be in the drawings or engineer's notes. Machinery Mounting Loads Under an industrial motor or pump, the machine foot bears the combined static weight of the machine plus dynamic loads from vibration and torque reaction. For a properly installed, bolted-down machine, these loads are largely compressive — and steel shims handle compressive loads well. The shim stack should cover the full area of the machine foot where possible, distributing the load evenly rather than concentrating it. What Cannot Carry Structural Load Timber (cedar, pine, hardwood): Wood under sustained compressive load compresses, creeps, and deforms over time — meaning a machine that is correctly aligned today will be out of specification in six to twelve months. Timber also rots, swells with moisture, and provides no predictable compressive performance. Cedar shims are a legitimate tool for temporary positioning during installation; they are not a permanent solution in any structural or machinery application. Plastic packers under heavy machinery: HDPE construction packers are rated for construction-level loads in frame and window installation. They are not rated for the sustained compressive loads of industrial machinery. Do not substitute construction plastic packers for steel shims under motor feet, pump bases, or any heavy industrial equipment. Shims for Excavators and Heavy Equipment Heavy earthmoving equipment — excavators, loaders, bulldozers, cranes — uses shims in several critical locations. These are high-load, high-vibration, outdoor environments with mud, water, and aggressive conditions. The shims used here are thick, high-strength steel — nothing like the thin alignment shims used on electric motors. Excavator Pin Shimming Excavator buckets, arms, and booms connect via large-diameter steel pins running through bronze or steel bushes. As the bushes wear — under the constant loading and cycling of digging — lateral play develops at the pin joint. The bucket wiggles side-to-side in the boss rather than tracking straight, reducing dig accuracy, increasing loading on the pin and boss faces, and accelerating further wear in a self-worsening cycle. Steel shims take up this lateral play. The pin is removed, a shim of the appropriate thickness is fitted between the boss face and the machine structure on one or both sides, and the pin is refitted. The shim reduces total lateral clearance to within OEM specification — typically less than 1–2 mm for most excavators. Pin shims for this application are thick (typically 3–6 mm) and manufactured from high-strength steel to handle the side loads in the joint. Always check the OEM service manual for the specific machine and joint: maximum allowable play and the correct shimming procedure vary by machine model. Undercarriage Components Track tension on crawler equipment is adjusted via a hydraulic tensioner, but shims may be used during track reassembly and component replacement to set initial dimensions and compensate for worn components. Undercarriage shimming is a specialist task requiring knowledge of OEM service specifications. Structural Base Plates and Outrigger Support On mobile cranes, elevated work platforms, and other outrigger-supported equipment, base plate shimming may be used to level the machine on uneven ground before operation. These applications use thick steel shims or machined steel plates — not standard alignment shims. Load capacities are high, and correct support is critical for operational safety. How to Measure and Cut Shim Stock The ability to cut your own shim from stock is one of the most useful capabilities in a workshop. The process is simple, but the details matter for a result that is accurate, burr-free, and safe to handle. Measuring and Marking Mark the shim profile on the stock material using a fine-tip permanent marker or a scriber. For straight-edged shims, use a steel rule and scriber. For complex shapes, make a paper or cardboard template first, trace around it, then cut. For slotted shims, mark both the outer profile and the slot position carefully — the slot must align with the bolt centre. Measure twice, cut once. Cutting Methods by Thickness 0.025–0.100 mm (1–4 thou): Sharp scissors or shim-cutting scissors. At these thicknesses, the material cuts like thin metal foil. Handle carefully — the edges are sharp. 0.100–0.500 mm (4–20 thou): Aviation snips (compound action tin snips) for straight cuts, curves, and complex shapes. Left-hand and right-hand snips are available. Keep blades sharp — dull snips fold and buckle the edge rather than cutting clean. 0.500–1.500 mm (20–60 thou): Aviation snips for shorter cuts; a metal-cutting bandsaw for long straight cuts. Stainless steel in this range work-hardens quickly — a bandsaw is cleaner than snips. Over 1.5 mm: Metal-cutting bandsaw, angle grinder with cutting disc, or guillotine shear. Mark the cut line clearly, clamp the stock securely, and use eye and hand protection. Cutting the Slot in a Horseshoe Shim To cut the slot from flat stock for a horseshoe shim, use the drill-and-snip method: drill a clearance hole at the inner end of the slot (matching or slightly larger than the bolt diameter), then cut down both sides of the slot from the outer edge to the drilled hole using aviation snips. The drilled hole gives a clean radius at the inner end of the slot rather than a sharp corner, which can become a stress riser under repeated loading. Deburring Any cut edge on metal shim stock will have a burr. Deburr all cut edges before fitting — a burred edge will damage mating surfaces, prevent the shim from sitting flat, and is a laceration hazard during handling. Use a fine file, a deburring tool, or fine abrasive paper on a flat surface. For thin shim stock, draw a flat file lightly across the edge — one or two strokes is enough. Do not over-file. Marking Shims Before Assembly If the shim is going into an installation that will be disturbed in future — a motor that will need re-alignment, a base plate that may be lifted — mark the shim thickness with a permanent marker before assembly. When the machine comes apart at the next service, you know immediately what is in the stack without having to micrometer every piece. It takes ten seconds and saves significant time later. Common Questions About Industrial Shims What is an industrial shim used for? Industrial shims are thin precision spacers used to fill gaps, align machinery, adjust bearing preload, level baseplates and correct manufacturing tolerances. Common applications include aligning electric motors to pumps, levelling structural baseplates, setting bearing clearance in gearboxes, and adjusting cutting tool height in machining operations. They are made in graduated thicknesses from a few thousandths of a millimetre upwards. What's the difference between a shim and a washer? A washer distributes the clamping load of a fastener over a larger area to protect the surface beneath. A shim is a precision spacer used to fill a measured gap or adjust an alignment. Washers come in a few standard thicknesses for each diameter; shims come in many graduated thicknesses so you can stack them to achieve any required gap. They look similar but serve different purposes. What materials are shims made from? Common shim materials include stainless steel for general use, brass for electrical isolation and corrosion resistance, mild steel for non-critical work, aluminium for light-duty applications, and various plastics where electrical insulation or chemical resistance matters. Laminated shims are made up of layers that can be peeled off to fine-tune thickness without changing the part. How thick are industrial shims? Shims come in a wide range of thicknesses. Precision shims for machinery alignment start from very thin material and graduate upwards in fine increments — often in increments of a few hundredths of a millimetre at the thin end, stepping up to half-millimetre and one-millimetre sizes at the thicker end. Stacking shims of different thicknesses allows you to achieve almost any required gap. Where do you buy industrial shims? Industrial shims are stocked by industrial supply distributors who stock alignment, fastener and bearing maintenance product ranges. They are sold in pre-cut sizes, laminated peel-off forms, and as flat strips you cut to size on the job. For shaft alignment and motor-pump coupling work, slotted shims that slip under a baseplate without removing the fastener are the standard choice. AIMS Industrial stocks a range of industrial shims. Where to Buy Shims in Australia AIMS Industrial stocks a comprehensive range of precision shims and shim stock for Australian industrial, construction, and engineering applications. The range includes shim stock rolls and flat sheets in cold-rolled steel, stainless steel 304 and 316, and brass across a full range of thicknesses from 0.025 mm upward; slotted alignment shim kits for motor and machinery alignment work; plastic HDPE shim packers for construction framing, door, and window installation; and specialty shim products from Champion and Precision Brand. All products are available online with delivery to anywhere in Australia. For technical advice on material selection, thickness specification, or choosing the right shim format for a specific application, contact the AIMS Industrial team. Browse Shims & Shim Stock at AIMS Industrial → For GD&T symbols and their meanings under Australian and international standards, see our GD&T Symbols Guide. For dry and lubricated torque values across all common metric bolt grades, see our Metric Bolt Torque Chart.
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