The thickness of stainless steel sheets directly affects their surface roughness and flatness, which in turn significantly affects the yield of deep processing such as stamping and bending.

I. Definition and Overview: The thickness of a stainless steel plate is not an isolated parameter.

In the context of steel manufacturing, "stainless steel plate thickness" refers not only to the nominal dimension of the steel plate's cross-section but also to a dynamically coupled variable—it is related to hot/cold rolling passes, tension control, roll stiffness, cooling rate, and the depth of subsequent leveling processes. International standard ISO 404:2013 clearly states that thickness tolerances (such as EN 10029 Class A/B/C) directly constrain the distribution range of surface waviness and micro-roughness (Ra). When the stainless steel plate thickness is <2.0 mm, if the reduction rate in the final cold rolling pass exceeds 18%, it is highly likely to induce the "orange peel effect"; while for hot-rolled plates with a thickness >12 mm, if double-sided straightening is not performed, neutral layer shift will cause the macro-flatness deviation to exceed the 0.3 mm/m² threshold.

It is worth noting that ASTM A480/A480M subdivides "surface condition" into categories such as No.1 (hot-rolled and pickled), 2B (cold-rolled and bright annealed), and BA (bright annealed and smoothed), and each category has strict limitations on the applicable range of stainless steel plate thickness. For example, BA surfaces are only applicable in the range of 0.3–6.0 mm; exceeding this range cannot guarantee consistent specular reflectivity. This confirms that thickness is never a single-dimensional indicator, but rather the starting point of the surface quality generation chain.

II. Technical Performance: Quantitative Mapping Relationship of Thickness-Roughness-Smoothness

Maxwell Steel constructed a regression model (R² > 0.92) for thickness and key surface parameters based on measured data of 304/316L stainless steel plates. The results show that, under the same rolling process, for every 1 mm increase in stainless steel plate thickness, the average surface roughness Ra value increases by 0.12–0.18 μm; while the flatness deviation (in I-Unit) exhibits an exponential growth trend—when the thickness increases from 1.0 mm to 3.0 mm, the average I-Unit value rises from 15 to 42; and when it increases to 6.0 mm, it jumps to over 108.

This phenomenon stems from the thickness dependence of material plastic deformation: thin plates are easily affected by the transmission of micro-defects on the roll surface and have high roughness sensitivity; thick plates, due to uneven internal stress release, are more prone to camber and warping. The table below shows the actual measurement comparison of typical cold-rolled 304 stainless steel plates under standard processes:

*Note: Based on statistics from a stamping production line producing 100,000 automotive parts, including failure types such as wrinkling, cracking, and excessive springback.

III. Application Scenarios: Process Adaptation Logic for Different Thickness Ranges

For the same grade of stainless steel, the downstream applications differ significantly due to variations in stainless steel plate thickness. For example, the 0.3–1.5 mm thickness range is the main specification for electronic casings and kitchenware panels, requiring Ra ≤ 0.15 μm and I-Unit ≤ 20. In this case, a Sendzimir 20-roll mill with online laser closed-loop flatness control is necessary. On the other hand, the 3.0–12.0 mm thickness dominates pressure vessel heads and rail transit structural components, where Ra ≤ 0.6 μm is allowed, but flatness must meet the mandatory clause in ASME BPVC Section VIII Div.1 that "local dent depth ≤ 0.5% of plate thickness".

For 0.8mm 316L sheets used in medical equipment, double-sided electropolishing and vacuum annealing are performed to ensure Ra≤0.05μm; for 6.0mm 304 sheets used in building curtain walls, quadruple straightening and laser scanning compensation are employed to stably control I-Unit at ≤65. This ability to define surface quality according to thickness is the core competitive advantage of professional manufacturers.

IV. Procurement and Selection Guide: How to Avoid Quality Traps Caused by Thickness

When selecting a supplier, the "three-check principle" should be adhered to: First, check standard compliance—confirm whether the stainless steel plate thickness tolerance meets EN 10029 Class A (±0.05mm) or ASTM A480 Table 3; Second, check process control documents—require the supplier to provide rolling force curves, leveling machine elongation records, and surface profilometer test reports for each batch; Third, check deep processing performance—prioritize companies with Tier 2 supplier qualifications for automotive OEMs, as their stainless steel plate thickness control has been verified by the IATF 16949 system.

Special reminder: Avoid the misconception that "thicker is more stable." A customer once used 8mm 304 stainless steel to make a precision mold base. Because they didn't pay attention to the residual stress distribution in the hot-rolled state, a 0.13mm warpage occurred after CNC machining, resulting in a 37% rework rate. The correct approach is—for sheets thicker than 6mm, you must require the supplier to provide stress-relief annealing certification and a 3D deformation simulation report.

Why choose Maxwell Steel? Our expertise stems from our unwavering commitment to millimeter-level thickness precision.

As a national high-tech enterprise specializing in steel manufacturing and export, Maxwell Steel (Jiangsu) Co., Ltd. is equipped with a German SMS 20-roll cold rolling line, a Japanese IHI quadruple straightening unit, and a complete surface inspection platform (including Taylor Hobson Form Talysurf and Keyence LJ-V7080 laser profilometer). We can provide customized solutions for the full range of stainless steel plate thicknesses from 0.3mm to 25mm, and simultaneously supply stainless steel H Beam, Angle Bar, Channel Bar, Flat Bar, and a full range of carbon steel profiles.

Whether you need 304/316L cold-rolled steel sheet conforming to EN 10088-2 or carbon steel H-beams conforming to GB/T 706-2016, our technical team can reverse-engineer the optimal stainless steel plate thickness range and matching surface treatment solutions based on your deep processing parameters (such as die clearance, bending radius, and stamping speed).