GATE TF Syllabus 2025: Textile Engineering & Fibre Science

A. General Aptitude

Verbal Aptitude

Basic English grammar: tenses, articles, adjectives, prepositions, conjunctions, verb-noun
agreement, and other parts of speech Basic vocabulary: words, idioms, and phrases in context
Reading and comprehension Narrative sequencing

Quantitative Aptitude

Data interpretation: data graphs (bar graphs, pie charts, and other graphs representing data), 2-
and 3-dimensional plots, maps, and tables Numerical computation and estimation: ratios,
percentages, powers, exponents and logarithms, permutations and combinations, and series
Mensuration and geometry Elementary statistics and probability

Analytical Aptitude

Logic: deduction and induction, Analogy, Numerical relations and reasoning

Spatial Aptitude

Transformation of shapes: translation, rotation, scaling, mirroring, assembling, and grouping Paper
folding, cutting, and patterns in 2 and 3 dimensions

B. Textile Engineering and Fibre Science(TF)

ENGINEERING MATHEMATICS

  • Linear Algebra: Matrices and Determinants; Systems of linear equations; Eigenvalues and Eigenvectors.
  • Calculus: Limit, continuity and differentiability; Successive differentiation; Partial differentiation; Maxima and minima; Errors and approximations; Definite and improper integrals; Sequences and series; Test for convergence; Power series; Taylor series.
  • Differential Equations: First order linear and non-linear differential equations; Higher order linear differential equations with constant coefficients; Euler-Cauchy equation; Partial differential equations; Wave and heat equations; Laplace’s equation.
  • Probability and Statistics: Random variables; Poisson, binomial and normal distributions; Mean, mode, median, standard deviation; Confidence interval; Test of hypothesis; Correlation analysis; Regression analysis; Analysis of variance; Control charts.
  • Numerical Methods: Numerical solutions of linear and non-linear algebraic equations; Numerical integration by trapezoidal and Simpson’s rules; Single-step and multi-step numerical methods for differential equations.

TEXTILE ENGINEERING AND FIBRE SCIENCE

Section 1: Textile Fibres

Classification of textile fibres; Essential requirements of fibre forming polymers; Gross and fine
structures of natural fibres like cotton, wool, silk; Introduction to bast fibres; Properties and uses of
natural and man-made fibres including carbon, aramid and ultra-high molecular weight
polyethylene fibres; Physical and chemical methods of fibre and blend identification and blend
analysis.

Molecular architecture, amorphous and crystalline phases, glass transition, plasticization,
crystallization, melting, factors affecting Tg and Tm; Polymerization of nylon-6, nylon-66, poly
(ethylene terephthalate), polyacrylonitrile and polypropylene; Melt spinning processes for PET,
polyamide and polypropylene; Preparation of spinning dope; Principles of wet spinning, dry
spinning, dry-jet-wet spinning and gel spinning; Spinning of acrylic, viscose and other regenerated
cellulosic fibres such as polynosic and lyocell; Post spinning operations such as drawing, heat
setting, tow-to-top conversion; Spin finish composition and applications; Different texturing
methods.

Methods of investigating fibre structure such as density, x-ray diffraction, birefringence, optical and
electron microscopy such as SEM and TEM, I.R. spectroscopy, thermal methods such as DSC,
DMA, TMA and TGA; Structure and morphology of man-made fibres; Mechanical properties of
fibres; Moisture sorption of fibres; Fibre structure-property correlation.

Section 2: Yarn Manufacture, Yarn Structure and Properties

Principles of ginning; Principles of opening, cleaning and blending; Working principles of modern blow room machines; Fundamentals of carding; Conventional vs. modern carding machine; Card setting; Card clothing; Periodic mass variation in card sliver; Card auto leveller; Principles of rolleer drawing; Roller arrangements in drafting systems; Periodic mass variation in drawn sliver; Draw frame auto leveller; Principles of cotton combing; Combing cycle and mechanisms; Recent developments in combing machine; Principles of drafting, twisting, and bobbin building in roving formation; Modern developments in roving machine; Principles of drafting, twisting and cop building in ring spinning; Causes of end breakages; Modern developments in ring spinning machine; Working principles of ring doubler and two-for-one twister; Relationship between single yarn twist and folded yarn twist; Principles of compact, rotor, air-jet, air-vortex, friction, core, wrap and twistless spinning processes.

Influence of fibre geometry, fibre configuration and fibre orientation in yarn; Fibre packing density
of yarn; Yarn diameter; Yarn twist and its relation to yarn strength; Helical arrangement of fibres in
yarns; Yarn contraction; Fibre migration in yarns; Stress-strain relation in yarn; Mass irregularity of
yarn; Structure-property relationship in ring, compact, rotor, air-jet and friction spun yarns.

Section 3: Fabric Manufacture, Structure and Properties

Principles of winding processes; Classification of winding methods; Patterning mechanism; Yarn
clearers and tensioners; Different systems of yarn splicing; Warping objectives and classification;
Different types of warping creels; Features of beam and sectional warping machines; Different
sizing systems; Sizing of spun and filament yarns; Drawing-in process; Principles of pirn winding.

Primary and secondary motions of loom; Shedding motion; Positive and negative shedding
mechanisms; Type of sheds; Tappet, dobby and jacquard shedding; Weft insertion; Mechanics of
weft insertion with shuttle; Shuttle picking and checking; Beat-up; Kinematics of sley; Loom timing
diagram; Cam designing; Effect of sley setting and cam profile on fabric formation; Take-up and
Let-off motions; Warp and weft stop motions; Warp protection; Weft replenishment; Principles of
weft insertion systems of shuttle-less weaving machines such as projectile, rapier, water-jet and
air-jet; Principles of functioning of multiphase and circular looms; Types of selvedges.

Basic woven fabric constructions and their derivatives; Crepe, cord, terry, gauze, leno and double
cloth constructions; Drawing and lifting plans.

Fundamentals of weft knitting; Classification of weft knitting technologies; Weft knitted
constructions such as plain, rib, interlock and purl; Different knit stitches such as loop, tuck and
float.

Principle of warp knitting; Classification of warp knitting technologies; Swinging and shogging
motion of guide bar; Basic warp knit construction such as pillar, tricot, atlas, inlay and nets. Fibre
preparation processes for nonwovens; Web formation and bonding processes; Spun-bonding and
melt-blowing technologies; Applications of nonwoven fabrics.

Principles of braiding; Type of braids; Maypole braiding technology.

Peirce’s equations for plain woven fabric geometry; Elastic a model of plain-woven fabric;
Thickness, cover and maximum set of woven fabrics; Geometry of plain weft knitted loop;
Munden’s constants and tightness factor for plain weft knitted fabrics; Geometry of tubular braids.

Section 4: Textile Testing

Sampling techniques for fibres, yarns and fabrics; Sample size and sampling errors.

Moisture in textiles; Fibre length, fineness, crimp, maturity and trash content; Tensile testing of
fibres; High volume fibre testing.

Linear density of sliver, roving and yarn; Twist and hairiness of yarn; Tensile testing of yarns;
Evenness testing; Fault measurement and analysis of yarns.

Fabric thickness, compressibility, stiffness, shear, drape, crease recovery, tear strength, bursting
strength, pilling and abrasion resistance; Tensile testing of fabrics; Objective evaluation of low
stress mechanical characteristics; Air permeability; Wetting and wicking; Water-vapour
transmission through fabrics; Thermal resistance of fabrics.

Section 5: Chemical Processing

Impurities in natural fibre; Singeing; Chemistry and practice of preparatory processes for cotton;
Preparatory processing of wool and silk; Mercerization of cotton; Preparatory processesfor
manmade fibres and their blends; Optical brightening agent.

Classification of dyes; Dyeing of cotton, wool, silk, polyester, nylon and acrylic with appropriate
classes of dyes; Dyeing of polyester/cotton and polyester/wool blends; Dyeing machines; Dyeing
processes and machines for cotton knitted fabrics; Dye-fibreinteraction; Introduction to
thermodynamics and kinetics of dyeing; Brief idea about the relation between colour and chemical
constitution; Beer-Lambert’s law; Kubelka-Munk theory and its application in colour measurement;
Methods for determination of wash, light and rubbing fastness.

Methods of printing such as roller printing and screen printing; Preparation of printing paste;
Various types of thickeners; Printing auxiliaries; Direct styles of printing of (i) cotton with reactive
dyes, (ii) wool, silk, nylon with acid and metal complex dyes, (iii) polyester with disperse dyes;
Resist and discharge printing of cotton, silk and polyester; Pigment printing; Transfer printing of
polyester; Inkjet printing; Printing faults.

Mechanical finishing of cotton; Stiff, soft, wrinkle resistant, water repellent, flame retardant and
enzyme (bio-polishing) finishing of cotton; Milling, decatizing and shrink resistant finishing of wool;
Antistatic and soil release finishing; Heat setting of synthetic fabrics; Minimum application
techniques.

Pollution control and treatment of effluents

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