Implementation of pre-heating system in stenters for improved machine performance and energy efficiency

Abstract

In textile finishing, stenter is a hot cake for newer inventions to boost up production via maximum utilization of energy. Prior to main drying or heat-setting chambers, intermediate heating of cylindrical system especially by steam has direct blessing to moisture evaporation, processing speed, fabric quality and so on.

Based on actual operational data, this study reveals the outcomes of pre-heating module installed within a stenter. After employing the pre-heating system to knit fabrics of varying structures and compositions, 23%-61% moisture reduction was found and at the same time the speed of processing fabrics was increased by 17%- 30% without any compromise on fabric quality.

Keywords: Stenter; Pre-heating; Speed; Production; Efficiency.

1. Introduction

Synthetic fibers of polyurethane, polyamide, polyester etc. origin cause dimensional changes of subsequently produced pure or blended fabrics upon wet treatments, mostly due to the relaxation of filament tension.

Thus, to control the desired fabric properties like width, GSM, shrinkage etc. the internal molecular arrangements of those fibers are thermally stabilized and distributed to stress-free positions which is commonly known as ‘Heat-setting’ [1]–[3].

Besides encountering weft distortion and relaxation of knitted loops, all of the wet cellulosic fabrics, man-made textiles and blended/synthetic fabrics are needed to dry and must meet certain tolerance level of finished fabric requirements [4].

Wet cellulosic fabrics have been found with increased drying time as they are generally hygroscopic in nature and hold significant amount of bound moisture. Unbound (free) moisture can be assumed for the synthetics like polyester fabrics which lead to shorter drying times [5].

Typical stretched dryers or stenters are used to cater a variety of services including heat setting & drying of open-width fabrics, moisture management, dimensional control, application of finishing chemicals, shade controlling etc. [6].

Depending on the fabric structure, exposure time, risk of damage etc. factors, the drying of fabric is mainly performed around 150°C to 160°C; where the temperature of heat-setting of blended or synthetic fabrics could be synchronized upto 220°C [7].

Since, hot air is circulated to achieve these desire properties so indirect steam or thermo-heated oil or direct gas heating modes have been applied. Hot-oil and gas fired stenters are commonly preferred over steam driven stenters in terms of advantages and efficiency [8].

During pre-heating/drying, the evaporated water from the fabric surface is carried out to the surrounding air via diffusion mechanism [5].

Though, mechanical de-watering is much economical than pre-drying using heat but the remaining moisture regain is comparatively higher in case of mechanical means as much of the residual water creates chemical bonding with fiber.

Therefore, focusing on the drying economy with lowered moisture regain, thermal means like ‘conduction’ drying was introduced where the open-width fabric is allowed to slide over some limited number of rotating heated metallic cylinders which are placed just after the mechanical moisture removing arrangement like finishing padder.

Despite the desired high rate of heat transfer from the hot cylinder surface to the surface of contact fabric, risk of distortion of delicate fabric surface and unwanted consequence produced by adherence of heat-transferred materials in different portions within fabric drew special attention [9].

Also, as the fabric is simultaneously needed to show plastic nature to achieve desired dimensional stability so the fabric should not be too dried in the cylinders [10].

Regarding these issues, the present work has been concentrated on latest and highly developed pre-heating modules that are smoothly operated in the experimental case of the study.

2. System Description

The study has been conducted in a Bangladeshi knit composite industry having daily finishing capacity of 42 tons. The finishing line is equipped with five (5) stenters from renowned manufacturers. Mixture of hot combustion gases of the burner and recirculating air is responsible for preparing the heated air for drying and the temperature can be adjusted from 100°C to 220°C.

Three (3) of the existing stenters of that factory are incorporated with pre-heating modules (Table 1). After fabric inlet, guide rollers, tension rollers, washing/chemical tanks and finishing padder, the corrosion resistant pre-heating cylinders are placed in the production line. Two pre-heating systems are horizontally installed and the rest is vertically mounted (Figure 1).

Both of the front and back side of the fabric is evenly passed over the hot cylinders and reach the main chambers after the ‘Mahlo’ arrangement. Additional utilities (steam, electricity etc.) are linked to the pre-heating system for level performance. The mechanical speed of the cylinders is properly synchronized with the speed of stenter.

Table 1: Technical specifications of pre-heating system

Parameter	Value
No. of Pre-heating Cylinders	4
Working Width	1600- 3800 mm
Structure of Cylinders	Teflon coated stainless steel
Diameter of each Cylinder	640 mm
Heating Medium	Steam
Maximum Operating Temperature	120°C
Total Steam Consumption	129- 147 kg/h (considering 2500 mm working width)
Total Electricity Consumption	2.8 Kw/h
Durability	20 years (at least)

3. Experimental

Six (6) different types of knit fabrics were selected to undergo two distinct frequent operations namely heat-setting and drying (Table 2; Table 3). During experimentation at the industry, the temperature and the relative humidity of the surrounding environment were measured 33 ± 1°C and 50 ± 4% respectively with the help of wet-and-dry bulb hygrometer.

For both heat-setting and drying, the fabric passage was same. The fabric was carried over feed rollers to 1st padder where the pressure was set to 3-3.5 bar. Then, the squeezed fabric was immersed in 2^nd tank and the set pressure in 2^nd padder was 2-4 bar depending on the operation (heat-setting/ drying).

After that, the fabric was conveyed to pre-heating cylinders. Operating pre-heating temperature was 100°C-105°C. For comparison and evaluating the results of this study, fabrics were examined omitting the action through pre-heating section also.

After passing the pre-heating section, the fabric was directed to main hot chambers of the stenter. Heat setting temperature was chosen above the glass transition temperature and at a time below the melting temperature of elastane.

All of the stenters which were taken into account had 8 (eight) chambers with 3m chamber length in each, and every chamber was equipped with 4 (four) pieces of air-circulating fans. There were two exhausts in each of them; the initial exhaust was connected to the first four chambers where the evaporation rate is comparatively higher than the latter exhaust covering the last four chambers.

Table 2: Description of Samples for Heat-setting

Table 3: Description of Samples for Drying

3.1 Moisture Regain Analysis

Upon absorbing moisture, fiber gets swelled and the cross-sectional area is changed. So, any change in the volume of a material significantly affects its mass. Moisture regain (M_r) can be defined as the ratio of the mass of water present (W) in the material to the oven dry mass (D) of the material, expressed in percentage (Eqn. 1) [11]:

The standard testing atmosphere is 65 ± 2% RH and 27 ± 2°C. Oven drying was carried out at 105 ± 2°C temperature after conditioning the samples at room temperature for some times.

3.2 Production Capacity Assessment

The production (in unit ‘kg/hr’) of a stenter is determined by Fabric speed or running length of fabric per unit time. The higher the speed of fabric processing, the greater the production capacity (Eqn. 2). Also, there exists relation between mechanical speed of fabric and dwell time.

The dwell time of fabric in stenter is inversely proportional to fabric speed when the length of each chamber and total no. of chambers in stenter are constant (Eqn. 3). Any increase in production speed decreases the dwell time in turns; so, greater amount of fabric can be finished via stenter at the same interval.

4. Results and Discussion

4.1 Effects of Moisture Evaporation

The reduction moisture regains of wet fabrics regarding the successive stages of operation including the pre-heating system is illustrated in Figure 2.

Figure 2 interprets that; all of the samples have proven to drop the moisture regain significantly when pre-heated in 100°C-105°C.

The H-2 sample i.e., 60/40 CVC single jersey fabric has shown less moisture regain compared to the rest heat-set samples containing elastane and dominant cotton. The fact behind this is polyester is least hydrophilic. In case of samples H-1 and H-2, the hydrophobic oils are removed after 1^st padding therefore, the hygroscopic nature of them is found to be improved despite comparatively greater pressure in the 2^nd padder.

The presence of higher moisture absorbent viscose fiber in sample H-3 has also contributed to its greater moisture regain. Compared to 2^nd padding, about 46%, 61% and 26% moisture have been found to evaporate from H-1, H-2 and H-3 samples respectively when they passed the pre-heating cylinders.

The quality of the heat-set fabrics of H-1 and H-2 didn’t fall even after processing with 30% and 19% residual moisture regain respectively. If the heat-set samples were directly exposed to highly hot temperatures of main chambers of the stenter without passing through the pre-heating system, there might introduce the risk of damaging of the elastane surface because of the heat shock of molecular chain.

Before drying, the pre-treated/dyed fabrics are softened mostly, maintaining a certain pick-up level. D-1 sample was made of 100% cotton and it regain after 2^nd padding (at 2 bar pressure) has been found equal to that after 1^st padding.

Since, elastane has better moisture regain than polyester so D-3 has displayed comparatively low regain than D-2 when both are subjected to 2.5 bar pressure of the second padder. With reference to 2^nd padding, approximately 41%, 24% and 23% reduction in moisture regain have been calculated for D-1, D-2 and D-3 samples respectively.

4.2 Effects of fabric processing speed

To attain the finished fabric requirements, the variation in fabric processing speed in stenter regarding the situation of operation is demonstrated in Figure 3.

Figure 3 reveals that, the mechanical speed of the stenter i.e., the speed of processing fabrics have eventually increased when the pre-heating using steam was brought in action. Pre-heating lessens the load of main chambers by gradual heating and then transporting the fabric in warm, moist condition.

The increase of speeds in pre-heated operation have been measured as around 30%, 24%, 22%, 21%, 18% and 17% for H-1, H-2, H-3, D-1, D-2 and D-3 samples respectively. Because of reduction in dwell time and increase in processing speed, the production capacity of that facility was remarkably increased. Thus, with the rise in efficiency, financial competitive advantages can easily be achieved.

4.3 Energy efficiency

Steam is used in the pre-heating system for heat conduction. Boilers are used to produce the vaporized state of water which is consumed by dyeing machines, finishing equipments and other facilities.

Since, boilers are common set-up in industries and their capacity is quite enough so this efficient, comparatively inexpensive, easy to maintain energy can be fed to the pre-heating cylinder. Some extra piping, repairing etc. should be done only to adjust the steam from the point of generation to the point of use. In case of carrying steam to distant positions, highly pressurized small diameter piping should be preferred over low pressurized oversized diameter piping.

5. Conclusion

Investigations of the outcomes of incorporating pre-heating system in stenter have been performed in this study. Successfully installed pre-heating module has been proven to increase the productivity of existing facility to at least 17% with sufficient moisture management.

While processing the fabrics through the system, fabrics having below 62 inches width may impose problems in dimensional stability control due to the relaxation in pre-heating cylinders, so this should be carefully considered.

Since, this module can be additionally installed to the working stenters so synchronization of motion between them is another key aspect; even a slight change may affect fabric tension or cause tearing. Also, to maintain comfortable working environment, proper ventilation should be ensured.

In future, performance of pre-heating systems driven by other mechanism like thermo-oil, infra-red, fully electric etc. can be analyzed for comparison. Steps might be taken to develop the cylindrical structure. Besides, assessment of a hot-oil based stenter introduced with same steam pre-heating system (as of this study) can be evaluated.

Acknowledgement

Authors would like to express gratitude to the management of Fakir Knitwears Ltd. (FKL) for providing the opportunity to study on their stenters. We specially acknowledge the support provided by the officers and operators of ‘Dyeing finishing’ section of FKL.