Multiple response optimization of sizing machine settings and sized yarn tensile properties using advanced method of experimental design

Materials

The gray yarn samples were obtained from Bahir Dar Textile Share Company, with the properties explained in Table 1. The yarn samples have been produced by a rotor spinning machine (R923).

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Table 1.

Unsized yarn properties and sizing conditions.

Tenacity (cN/tex)	Elongation (%)	Fiber type	Warp yarn count	Sizing agent	Size box temperature (°C)	Viscosity of size paste (s)
7.56	5.45	30/70 polyester/cotton	15 Ne	Starch	85	12

Methods

In this research, the effects of squeezing roller pressure, wet zone yarn tension, and speed of the sizing machine on the tensile properties of sized yarn were studied. The samples of sized yarn have been produced with a Rotal-Karl Mayer sizing machine model (SRL-SMR-SP). Other sizing machine and size box variables like size liquor concentration, viscosity, temperature, and R.F.% have been kept constant.

Experimental design

In this research, the effects of squeezing roller pressure, wet zone yarn tension, and speed of sizing machine on the gain strength, stretch, and loss elongation of sized yarn have been investigated using advanced methods of analysis. Design expert 11 software with a Box-Behnken design have been employed to design the experiment and examine the results of the experiment extensively. ANOVA, regression analysis, 3D plots (to examine the interaction effects of two factors on the response variables), and each factor’s effect on the response/dependent variable were used in the analysis. The designated factors and levels of the factors are shown in Table 2. Fifteen experimental runs have been formed by the design expert 11 software randomly as indicated in Table 3 and 15 samples of sized yarn have been produced.

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Table 2.

Identified factor with their actual levels.

Factor	Lower level	Average	Higher level
Wet zone yarn tension	340 N	380	420 N
Squeezing pressure	13 kN	15	17 kN
Sizing machine speed	30 m/min	49	68 m/min

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Table 3.

Average test results of sized yarn response values with different combinations of factors.

Factor				Response
Run	Wet zone yarn tension (N)	Squeezing pressure (kN)	Sizing machine speed (m/min)	Gain strength (cN/tex)	Loss elongation (%)	Stretch (%)
1	420	15	30	19.58	34.01	1.9
2	380	17	68	31.27	36.36	1.7
3	380	13	68	40.25	23.52	1.5
4	380	13	30	29.58	26.15	1.5
5	420	13	49	15.01	33.25	1.6
6	380	17	30	44.01	27.93	1.5
7	420	15	68	20.32	25.30	1.5
8	380	15	49	29.11	31.54	1.6
9	340	17	49	28.50	27.93	1.4
10	340	13	49	31.34	17.30	1.3
11	380	15	49	30.87	31.20	1.7
12	340	15	30	33.61	13.22	1.2
13	420	17	49	26.30	39.56	2.0
14	380	15	49	30.34	29.40	1.7
15	340	15	68	29.1	23.86	1.6

Characterization of responses variables

Gain strength and loss of elongation

The tensile strength and elongation properties of sized and unsized yarn were measured by a universal tensile strength tester (STATIMAT ME + tensile tester) according to ISO 2062. ¹³ Five replicates have been taken for each test, and the average value was taken for analysis. The formulas used to calculate the amount of gain strength and loss elongation due to the sizing process are shown in equations (1) and (2). ¹⁴

Gain Strength = ( Sized yarn strengt - Unsized yarn strength Unsized yarn strength ) X 100

(1) ¹⁴

Loss elongation % = ( Unsized yarn elongation - Sized yarn elongation Sized yarn elongation ) X 100

(2) ¹⁴

Stretch

In this research, the stretch of the warp yarn is obtained from the sizing machine. In the Karl Mayer-Rotal sizing machines, the value of stretch is clearly shown on the machine control panel; therefore, the average value of sized yarn stretch is directly obtained from the control panel of sizing machine after 200 m of yarn have been sized for each sample.

Effect of wet zone yarn tension, squeezing roller pressure, and sizing machine speed on gain strength of warp yarn

In the sizing process, the gain strength of the yarn is affected by the sizing machine parameters like tension, squeezing roller pressure, and speed. For better quality sized yarn, uniform tension and optimum squeezing roller pressure are required. ¹⁰ In this section, the effect of these factors on the gain strength of sized yarn has been investigated. Fifteen samples of fabric have been produced according to the design of the experiment, as demonstrated in Table 3.

As illustrated in Table 4, the wet zone yarn tension and squeezing roller pressure have a significant impact on the gain strength of the yarn. Not only the main effect but also the interactions between wet zone yarn tension and squeezing pressure, squeezing pressure and sizing machine speed, and quadratic terms (A², B², and C²) have also had significant effects on the average sized yarn strength. The wet zone yarn tension has the most significant influence on the strength of sized yarn with p < 0.0001.

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Table 4.

Analysis of variance (ANOVA) results for gain strength percentage of sized yarn.

Source	Sum of squares	df	Mean square	F-value	p-Value
Model	750.16	9	83.35	77.08	<0.0001	Significant
A	213.62	1	213.62	197.56	<0.0001
B	24.15	1	24.15	22.34	0.0052
C	4.26	1	4.26	3.94	0.1038
AB	49.91	1	49.91	46.16	0.0011
AC	6.89	1	6.89	6.37	0.0529
BC	137.01	1	137.01	126.71	<0.0001
A2	220.17	1	220.17	203.62	<0.0001
B2	31.11	1	31.11	28.78	0.0030
C2	39.43	1	39.43	36.47	0.0018
Lack of fit	3.78	3	1.26	1.54	0.4163	Not significant

Table 5 shows the predicted R²-value (0.9152) is in reasonable agreement with the adjusted R²-value of (0.9800) and the difference is less than 0.2, which means no over-fitting and a regression model can properly predict the responses for new observation. Figure 2 also shows, there is a linear correlation between the predicted and experimental values which suggests that the regression model is appropriate and all the actual and predicted values are fitted to straight line showing that the errors are very less.

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Table 5.

Coefficients of determination values for gain strength, loss elongation, and stretch of sized yarn.

Parameter	R 2	Adjusted R2	Predicted R2
Gain strength	0.9928	0.9800	0.9152
Loss elongation	0.9870	0.9635	0.8455
Stretch	0.8940	0.8146	0.6377

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Figure 2.

Actual versus predicted values of sized yarn gain strength.

Equation (3) represents regression equations produced by the design expert program in terms of coded parameters for significant factors. The quantitative relationships between variables A, B, and C and their interactions with the response values are described by the regression model equations. It demonstrates a negative relation between the strength of the sized yarn and the wet zone yarn tension, interactions between BC, and the quadratic terms A² and C². Nonetheless, there is a positive association between the sized yarn strength and the squeezing roller pressure as well as the interactions between AB and the quadratic term B².

Gain strength = 30 . 11 − 5 . 17 ( A ) + 1 . 74 ( B ) + 3 . 53 ( AB ) − 5 . 85 ( BC ) − 7 . 72 ( A 2 ) + 2 . 9 ( B 2 ) − 3 . 27 ( C 2 )

(3)

The effects of various sizing machine parameters (wet zone yarn tension, squeezing pressure, and sizing machine speed) on average sized yarn strength are demonstrated in Figure 3. Generally, the tensile strength of the yarn is influenced to a greater extent by the wet zonal yarn tension of the sizing machine. The reason is that, in the wet state (sizing zone), the warp yarn is stretched quickly when tension is applied. According to Salama et al. ¹⁷ report, 66.7% of the stretch in the sizing process occurs in the wet tension region of the sizing machine. This results in a reduction in gain strength and an increase in loss elongation. As shown in Figure 3(a), the tensile strength of the sized yarn is influenced by the wet zone tension. As the wet zone yarn tension increases, the yarn strength first increases to some extent and then decreases rapidly. The generation of fiber slippage in the yarn structure, which takes place under high wet tension, is the primary cause of the reduction in sized yarn strength. Since the fiber uniformity ratio in the polyester cotton blend yarn is low, fiber-to-fiber friction decreases as tension increases, which results in poor resistance of the yarn to the applied load. This is also in agreement with. ¹⁸ Figure 3(b) shows a direct correlation between the strength of the sized yarn and the squeezing pressure. This is because higher squeezing pressures allow the size material to penetrate the yarn core more deeply, enhancing inter-fiber binding and the packing density or compactness of the yarn, which is also in agreement with Hari et al. ⁹ and Patil et al. ¹⁹ A high packing density increases fiber cohesion and reduces inter-fiber slippage, which helps increase the strength of the sized yarn, which is also supported by Maatoug et al. ¹⁶

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Figure 3.

Effect of wet zone yarn tension (a), squeezing roller pressure (b) and sizing machine speed (c) of sizing machine on sized yarn gain strength.

The interaction effects of the factors (wet zone yarn tension, squeezing pressure, and sizing machine speed) on average sized yarn strength are demonstrated in Figure 4 using a 3D plot. As indicated in Figure 4(a), the wet zone yarn tension and squeezing roller pressure effects on the strength of the yarn are opposite (i.e. strength increases as squeezing roller pressure increases and decreases as wet zone yarn tension increase). Figure 4(b) shows the interaction of BC has the most significant effect on the yarn strength. At squeezing roller pressure of 17 kN, sizing machine speed of 30 m/min, and constant wet zone tension of 380 N, the gain strength reached a maximum level. That means when the sizing machine speed is at its lowest level, the squeezing pressure should be at its highest level to obtain the maximum gain strength of the yarn. This is because at low speed, the yarn waiting time in the sizing box is greater, and there is enough time for the size material to penetrate into the core of the yarn and higher pressure also assist the penetration of size material in to the core of the yarn.

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Figure 4.

3D plot showing interaction effect of squeezing pressure and wet zone yarn tension (a), and squeezing pressure and sizing machine speed (b) on the sized yarn gain strength.

Effect of wet zone yarn tension, squeezing roller pressure, and sizing machine speed on loss elongation of warp yarn

Elongation refers to the yarn’s change in length at breaking force. It is one of the most essential yarn quantitative characters as it has an influence on how woven materials are produced and used.^20,21 In the sizing process, this change can occur for several reasons. The tension of the sizing machine, the squeezing roller pressure, and the speed of the sizing machine are among the factors dealt with in this research. Table 6 revealed that the linear variables (wet zone yarn tension and squeezing roller pressure), the interaction variables AC and BC, and the quadratic variables A² and C² have a significant effect on the elongation loss of the yarn. The wet zone yarn tension has the lowest p-value of <0.0001, which implies that it has the most significant influence on the loss of elongation of sized yarn compared to sizing machine speed and squeezing roller pressure.

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Table 6.

Analysis of variance (ANOVA) results for loss elongation percentage of sized yarn.

Source	Sum of squares	df	Mean square	F-value	p-Value
Model	664.02	9	73.78	42.07	0.0003	Significant
A-wet zone	310.13	1	310.13	176.86	<0.0001
B	124.50	1	124.50	71.00	0.0004
C	7.47	1	7.47	4.26	0.0940
AB	4.67	1	4.67	2.66	0.1638
AC	93.61	1	93.61	53.38	0.0008
BC	30.58	1	30.58	17.44	0.0087
A2	28.90	1	28.90	16.48	0.0097
B2	9.39	1	9.39	5.35	0.0686
C2	53.82	1	53.82	30.69	0.0026
Lack of fit	6.12	3	2.04	1.54	0.4164	Not significant

The regression model depicted in equation (4) show the quantitative effect of significant factors A and B, their interactions and quadratic terms A² and C² with the response variable values. It shows that wet zone yarn tension, squeezing roller pressure, and interactions between squeezing roller pressure and sizing machine speed have a positive correlation with the elongation loss of the sized yarn. However, the quadratic terms A² and C² have a negative correlation with the elongation loss of sized yarn.

Loss elongation ( % ) = 31 . 69 + 6 . 23 ( A ) + 3 . 94 ( B ) − 4 . 84 ( AC ) + 2 . 76 ( BC ) − 2 . 92 ( A 2 ) − 3 . 94 ( C 2 )

(4)

Table 5 shows that the values of adjusted R² and predicted R² for loss of elongation are found to be 0.9635 and 0.8455, respectively. This indicated a high degree of correlation between the actual and predicted values. Similarly, the difference between the adjusted R² and predicted R² is less than 0.2, which means there is no over-fitting and a regression model can properly predict the responses. In addition, as indicated in Figure 5 there is a linear correlation between the predicted and experimental values, which suggests that the regression model is appropriate for the data.

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Figure 5.

Actual versus predicted values of sized yarn loss elongation.

Figure 6 show that sizing machine speed has no noticeable impact on the elongation loss percentage. However, the wet zone yarn tension and squeezing pressure have a significant effect on the loss of elongation.

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Figure 6.

Effect of wet zone yarn tension (a), squeezing pressure (b) and sizing machine speed (c) on the loss elongation of sized yarn.

Figure 6(a) shows that as wet zone yarn tension increase, the sized yarn loss elongation increases significantly. The loss of elongation is directly related to the degree of stretch and the elasticity of the yarn, which is in agreement with the previous studies.^2,7,17 As the yarn tension in the wet state increases, the stretch on the yarn increases, and consequently, it will loss its elongation properties. This is because, in the wet state, the yarn is easily stretchable on application of tension due to the low sliding resistance of the fibers in the yarn in the wet state. This is also in agreement with previous studies.^2,7

As stated in Figure 6(b), when the squeezing roller pressure increases, the loss of elongation of the sized yarn increases. The reason is that as the squeezing roller pressure increases, the packing density of the yarn and fiber-to-fiber attachment increase, resulting in an interruption in fiber mobility. As a result of this, the yarn’s elasticity properties are reduced significantly. Increasing or decreasing the speed of the sizing machine (Figure 6(c)) does not have a significant effect on the loss of elongation; however, it has a significant effect when it interacts with both wet zone yarn tension and squeezing roller pressure, as indicated in Figure 7(a) and (b).

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Figure 7.

3D plots showing interaction effect wet zone yarn tension and sizing machine speed (a), and squeezing pressure and sizing machine speed (b) on elongation loss of sized yarn.

Moreover, 3D plots were constructed to visualize the interaction effect of two independent variables on the loss elongation of the sized yarn. Figure 7(a) and Table 6 with a p-value of 0.0001 show that the interaction effect of sizing machine speed and wet zone yarn tension on the loss of elongation is more significant than the other interaction. When factor A is 340 N and factor C is 30 m/min, the loss elongation reached a minimum level of 13.22% at a constant squeezing pressure of 15 kN. As shown in Figure 7(b) the interaction effect of squeezing roller pressure and sizing machine speed is also significant.

Effect of wet zone yarn tension, squeezing roller pressure, and sizing machine speed on yarn stretch of warp yarn

The yarns are stretched as the yarns move from the creel to the size box, the size box to the drying cylinders, the drying cylinders to the draw rolls, and the draw rolls to the final beam. Depending on the type of yarn being sized, the net stretch must be kept under control to preserve the elasticity of the sized yarn. ¹⁰ The yarn’s extensibility is quite high when tension is applied in the wet zone, and it is the most crucial factor that influences the degree to which the yarn stretches. An analysis is done on the impact of wet zone yarn tension, squeezing pressure, and size machine speed on stretch in this part.

From Table 7, it is observed that the wet zone yarn tension with a p-value of 0.0004 has the largest effect on the yarn stretch, followed by the interactive effect between wet zone yarn tension and sizing machine speed with a p-value of 0.0021 and squeezing pressure with a p-value of 0.0244.

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Table 7.

ANOVA results for sized yarn stretch.

Source	Sum of squares	df	Mean square	F-value	p-Value
Model	0.5400	6	0.0900	11.25	0.0016	Significant
A	0.2812	1	0.2812	35.16	0.0004
B	0.0612	1	0.0612	7.66	0.0244
C	0.0050	1	0.0050	0.6250	0.4520
AB	0.0225	1	0.0225	2.81	0.1321
AC	0.1600	1	0.1600	20.00	0.0021
BC	0.0100	1	0.0100	1.25	0.2960
Lack of fit	0.0573	6	0.0096	2.87	0.2811	Not significant

As shown in Table 6, the values of adjusted R² and predicted R² for stretch are found to be 0.8146 and 0.6377, respectively. This indicates a high degree of correlation between the actual and predicted values. Figure 8 signifies that the actual and predicted values of stretch are close to the straight-line curve, which indicates that the actual and predicted values are nearly equal and the error is very small.

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Figure 8.

Actual versus predicted values of sized yarn stretch.

As shown in Figure 9, the sizing machine speed has no noticeable impact on the stretch percentage. However, wet zone yarn tension and squeezing roller pressure have a significant effect on sized yarn stretch. The stretch of the yarn is observed to increase significantly as the wet zone yarn tension (sizing zone) increases as shown in Figure 9(a). The reason for this is that in the wet state, the yarn is easily stretchable by the applied tension, and after stretching the yarn in the wet zone, the yarn gets less time to return to its original length before drying. According to Salama et al., ¹⁷ reports, 66.7% of the stretch in the sizing process occurs in the wet tension region of the sizing machine. Figure 9(b) also shows that the stretch percentage of the sized yarn increases as the squeezing roller pressure increase.

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Figure 9.

Effect of wet zone yarn tension (a), squeezing pressure (b) and sizing machine speed (c) on sized yarn stretch.

According to the regression equation, sized yarn stretching has a positive relationship with both wet zone yarn tension and squeezing roller pressure. But the interaction effect between wet zone yarn tension and sizing machine speed shows a negative correlation with the stretch of sized yarn as stated in equation (5).

Y a r n s t r e t c h ( % ) = 1 . 58 + 0 . 1875 ( A ) + 0 . 0875 ( B ) − 0 . 2 ( AC )

(5)

To demonstrate the interaction effect of independent variables on the stretch percentage of the sized yarn, 3D plots are used. Figure 10 show the interaction effect of wet zone yarn tension and sizing machine speed on sized yarn stretch. It revealed that while both wet zone yarn tension and sizing machine speed decreased simultaneously, the stretch percentage of the yarn decreased significantly. When the wet zone yarn is high at higher speed of sizing machine the yarn get short time to return to its original length before drying resulting in permanent stretch.

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Figure 10.

3D plot indicating interaction effect of sizing machine speed and wet zone yarn tension on stretch percentage of sized yarn.

Response optimization

The optimization technique is an influential tool used to find the required design parameters and the best set of operating conditions. It refers to finding the values of decision variables that correspond to and provide the maximum or minimum of one or more desired objectives. The formulation of objective functions and the selected optimization technique determine the predictability of optimal solutions. ²²

To find the optimum response values, multiple response optimization approaches were used and Design-Expert (version 11) statistical software was applied to obtain the best compromise of response. A multiple response approach is adopted from Derringer and Suich. ²³ Accordingly, the optimization of the response variables and factors is stated in Table 8. As shown in Table 8, the optimum values of gain strength (32.7 cN/tex), loss in elongation (18.5%), and stretch (1.4%) were obtained at 340 N wet zone yarn tension, 13 N squeezing roller pressure, and 51 m/min sizing machine speed.

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Table 8.

Optimized values of sizing machine settings and sized yarn tensile properties.

Wet zone yarn tension (N)	Squeezing pressure (kN)	Sizing machine speed (m/min)	Gain strength (cN/tex)	Loss elongation (%)	Stretch (%)
340	13	51	32.7	18.5	1.4