EP0361098A1 - Method and apparatus for continuously dyeing textile materials made of cotton - Google Patents

Abstract

To make it possible to operate a continuous dyeing apparatus for dyeing cotton in indigo by recycling a wastewater-free wash liquor without unacceptable reduction in the fresh water supply, the textile material is intermediately dried after the wetting and before and/or during the dyeing to equal out the liquid balance by evaporation of water.

Description

The invention relates to a process for the continuous dyeing of cotton goods, in particular cotton warp yarn, preferably for indigo dyeing, with the aid of a washing system which has a sequence of mesh compartment, dyeing compartment and washing compartment, with at least one diving trough with downstream squeezing mechanism and each diving trough for the mesh compartment and dyeing compartment of the dyeing compartment include an air passage adjoining its crushing unit, fresh water for washing the dyed goods being fed to the rinsing compartment and the water not taken away by the washed goods running out of the rinsing compartment as waste water. It also relates to a continuous dyeing system for carrying out the method

A continuous dyeing system basically consists of the following elements: a network compartment with at least one roller skid with a subsequent crushing unit; a coloring compartment with four to six trains or diving tanks, that is roller skids with squeezing device; four to six air passages, each arranged above the diving tank; a rinsing compartment with two to three rinsing troughs with squeezing devices for washing out the unfixed dye component or for rinsing out the chemicals applied in the wetting and dyeing compartments.

In such a continuous dyeing system, cotton yarns can either be combined into a chain and dyed in a broad form, or treated into thumb-thick cables with, for example, 350 to 400 threads. Optionally run z. B. 12 to 24 cables side by side through the continuous dyeing system. After dyeing and then rinsing, the cables are generally dried on a cylinder dryer and then deposited. Spread chains, on the other hand, can be fed continuously into a sizing machine after dyeing and rinsing and after having passed a pre-dryer.

In the mesh compartment, the cotton fabric is treated with a wetting agent that influences the degree of dyeing of the individual threads in the dyeing compartment. The net liquor in the net trough can be controlled, preferably automatically, to a certain level, so that goods of the same net size always reach the dyeing compartment. A storage and mixing container is assigned to the net trough, into which wetting agent and water are introduced with a concentration such that a constant wetting agent concentration can be set in the net trough.

In the dyeing section, four or more diving tanks are generally provided, each with a downstream squeezer, which are continuously supplied with dyeing liquor from a dyeing liquor mixing container or the like to such an extent that the level and concentration of the diving tanks remain constant during the duration of a treatment. The dyeing liquor mixing tank is supplied from stock tanks and from a water inflow.

While there is no significant loss of liquid in the treatment of the goods in the net compartment or in the diving tanks of the dyeing compartment - apart from the solution that was intentionally taken with the goods - there is also in the air passages that follow each diving tank and which are intended for oxidizing the color significant evaporation. The amount of water evaporated in the air passages can be of the order of 5 to 15% based on the dry weight of the goods.

Following the last air passage of the dyeing compartment, the goods run into the rinsing compartment, in which unfixed dye and dyeing chemicals have to be rinsed out. In general, at least about 200% fresh water, based on the dry weight of the goods, is required in conventional continuous dyeing systems of the type described for the rinsing process.

Since about 80% of the liquid, based on the dry weight of the goods, is to be removed with the finished dyed and rinsed goods and because around 10% of the liquid (always based on the dry weight of the goods) is removed in the air passages of the dyeing compartment, even if one Part of the wastewater running out of the rinsing compartment is returned to the dyeing compartment or to the network compartment, an amount of wastewater weighing more than the treated fabric weight is still left, which is generally not only to be fed to a dye and chemical recovery unit, but also to biological wastewater treatment .

The invention is based on the general object to improve the continuous dyeing system or the method for operating such a system so that the washing water flowing out of the washing compartment can be completely attributed to the process, so that neither dye or chemical recovery nor complex biological waste water treatment required are. The solution to such a problem would require that the wash water requirement, ie the fresh water volume, be reduced to the amount that can actually be used during wetting and dyeing. According to the above calculations, that would mean washing in the sink to reduce the amount of fresh water required to less than half of the previous requirement. Even when the rinsing process is optimized, such a reduction no longer leads to sufficient washing results. The object on which the invention is based is therefore to be achieved on the premise that more washing water (running out of the rinsing compartment) is to be added to the wetting and dyeing compartments than liquid with the finished product - also taking into account evaporation in the air passages.

For the process for continuous dyeing of the type mentioned at the outset, the solution according to the invention consists in that the waste water is passed completely into at least one compartment of the dyeing system preceding the rinsing compartment and is evaporated in the area in front of the rinsing compartment except for an amount of liquid carried away from the rinsing compartment by the goods.

It is achieved by the invention that the balance of liquid supplied in the form of fresh water and liquid discharged together with the finished goods can be balanced without waste water. The trick is that the excess water in the balance is brought to the network compartment and / or dyeing compartment and is then evaporated downstream of the flushing compartment after the network compartment.

According to a further invention, the waste water is in each case at least in part either in the air passages of the dyeing compartment or on drying cylinders connected in the goods passage between the immersion trough and air passage at least a section of the dyeing compartment or in one in the goods passage between the network compartment and Dyeing section set cylinder dryer evaporates. The last alternative is particularly preferred because of the possible size of the evaporation capacity.

For the continuous dyeing system of the type mentioned at the outset, the solution according to the invention is that between the power pack and the dyeing part, an intermediate dryer with an evaporation capacity of approximately equal to the value of the difference between the amount of fresh water required for the washing compartment and the amount of the fresh water required for the washing compartment and the amount together with that Goods discharged water is switched. A cylinder dryer and / or an air dryer is preferably provided as the intermediate dryer.

It is thereby achieved that between the network compartment and the dyeing compartment, an amount of water of approximately the same as the difference between the amount of fresh water required for the rinsing compartment and the amount of liquid removed together with the goods is reduced by the amount of evaporation in the dyeing compartment.

According to yet another invention, it can be favorable if either the air ducts of the dyeing compartment together with the intermediate dryer have an evaporation capacity required to completely balance the liquid balance, or if the dyeing compartment - in addition or as an alternative to the intermediate dryer - has at least one in the product passage between the immersion trough and the air duct set drying cylinder.

Details of the invention are explained on the basis of a schematic block drawing.

A continuous dyeing system of conventional type consists of a mesh compartment 1, a dyeing compartment 2 and a rinsing compartment 3. According to the invention, an intermediate dryer 4 can preferably be connected between the mesh compartment 1 and the dyeing compartment 2.

The goods 5 to be treated generally run dry, that is to say, for example, with 7% moisture, based on the dry weight, into the network compartment 1. In the following or in the drawing, this dry condition of the goods is designated 0%. The percentages of moisture given here and below always refer to the dry weight of the treated goods.

At the exit of the network compartment 1, the goods 5 pass through a schematically indicated crushing unit 6 and leave it with about 80% moisture. Thereupon, in the exemplary embodiment, the goods reach an intermediate dryer 4. The intermediate dryer can be designed, for example, as a cylinder dryer with a plurality of drying drums 7. A volume of moisture VT of, for example, about 60% is to be evaporated in the cylinder dryer; if necessary, the goods then reach the dyeing compartment 2 with about 20% moisture.

In the dyeing section 2, the goods 5 are enriched with liquid in immersion troughs or roller skids 8 and, after each runner and also at the end of the dyeing section 2, are brought to, for example, 80% residual moisture in a squeezer 9. In which itself an amount of liquid VL2 of, for example, about 10% can be evaporated at each air runner 10 adjoining the roller skate 8. The 80% moist product at the end reaches the washing compartment 3 from the dyeing compartment 2.

In the rinsing compartment 3, the goods are washed with fresh water 22 and leaves the rinsing compartment 3 at the exit via a squeeze mechanism 11 with an amount of liquid VW of again approximately 80%. The wash water 12 running out of the rinsing compartment 3 reaches a wash water reservoir 14, for example via a filter 13. From there, the wash water is completely returned to the network compartment 1 or to the dyeing compartment 2. Part of the wash water reaches a network liquor tank 16 via a line 15 and from there, if necessary, via a line 17 with a pump 18 into the network compartment 1. The rest of the wash water 12 arrives via a dye liquor mixing tank 19 (or via a vat tank) and a line 20 with pump 21 in the dyeing compartment 2.

According to the above, the following liquid balance results: The amount VF of fresh water 22 supplied in the rinsing compartment 3 is the amount VT of water evaporated in the intermediate dryer 4, the amount VL2 of water evaporated in the air passages of the dyeing compartment 2 and the amount VW of the balance with the liquid 5 carried at the exit of the continuous dyeing system. Accordingly, the equation VF = VT + VL2 + VW applies.

The intermediate dryer 4 according to the invention is thus to be designed such that the amount of liquid to be evaporated in it is VT = VF - VW-VL2.

In the exemplary embodiment symbolized on the basis of the drawing, the fresh water quantity VF = VT + VL2 + VW = 60% + 10% + 80% = 150% (based on the dry weight of the goods 5). Such a low amount of fresh water is sufficient for washing in the washing compartment 3 if the washing process is carried out intensively and optimally. According to a further invention, provision is therefore made for the washing compartment 3 to be equipped with cascade-shaped washing troughs 25, a squeezing mechanism 11 being assigned to each washing trough 25 and a spraying device 27 being directed into the squeezing gap 26 of each squeezing mechanism 11. Each of the spray devices 27 can be supplied via a circulation pump 28. The combined immersion and spraying allows a significant reduction in the fresh water, so that the available amount of VF = 150% can be sufficient for rinsing.

A particularly high evaporation capacity and the possibility of using a relatively large amount of washing water is provided if separate drying cylinders 29 are placed in the goods aisle in the individual sections of the dyeing compartment. This detour route through the drying cylinders 29 is designated 30. In the exemplary embodiment shown, it is assumed that a quantity of water VL1 corresponding to 30% dry weight of the goods 5 is to be evaporated on the additional drying cylinder 29. The evaporation capacity (for example VT or VL2) at another point in the system can be reduced or the amount of fresh water VF supplied can be increased by this 30% without the heat balance sought according to the invention
VF - VT - VL1 - VL2 - VW = 0
changed in result.

Reference symbol list

• 1 = network compartment
• 2 = dyeing compartment
• 3 = rinsing compartment
• 4 = intermediate dryer
• 5 = goods
• 6 = crushing mechanism
• 7 = drying drum
• 8 = roller skate
• 9 = crushing mechanism
• 10 = air passage
• 11 = crushing mechanism
• 12 = wash water
• 13 = filter
• 14 = reservoir
• 15 = line
• 16 = net fleet container
• 17 = line
• 18 = pump
• 19 = dye liquor mixing container
• 20 = line
• 21 = pump
• 22 = fresh water
• 23 = evaporated water (4)
• 24 = evaporated water (2)
• 25 = washing trough
• 26 = pinch gap
• 27 = spray device
• 28 = circulation pump
• 29 = drying cylinder
• 30 = goods route
• VF = amount of fresh water
• VT = evaporated water (4)
• VL1, 2 = evaporated water (2)
• VW = finished goods moisture

Claims (14)

1. A process for the continuous dyeing of cotton goods, in particular cotton warp yarn, preferably for indigo dyeing, with the aid of a dyeing system having a sequence of mesh compartment (1), dyeing compartment (2) and rinsing compartment (3), with at least one immersion trough in each case for the mesh compartment and dyeing compartment (8) with a downstream squeeze mechanism (6, 9) and for each immersion trough (8) of the dyeing compartment (2) an air passage (10) adjoining the squeeze mechanism (9) thereof, with the flushing compartment (3) fresh water for washing the dyed goods (5) is supplied and the water not taken away by the washed goods runs off as waste water from the washing compartment (3),
characterized in that the waste water is completely conducted into at least one compartment (1, 2, 4) of the dyeing system preceding the rinsing compartment (3) and is evaporated in the area in front of the washing compartment (3) except for an amount of liquid carried in the goods (5) from the washing compartment (3). 2. The method according to claim 1,
characterized,
that the waste water is at least partially evaporated in the air passages (10) of the dyeing compartment (2). 3. The method according to claim 1 or 2
characterized,
that the wastewater is evaporated at least in part on drying cylinders (29) connected to the product passage between the immersion trough and the air passage of at least a section of the dyeing compartment (2). 4. The method according to any one of claims 1 to 3,
characterized,
that the waste water is at least partially evaporated in a cylinder dryer (4) placed in the goods passage between the network compartment (1) and the dyeing compartment (2). 5. The method according to any one of claims 1 to 4,
characterized,
that between the network compartment and the dyeing compartment, an amount of water of approximately equal to the - possibly reduced by the amount of evaporation in the dyeing compartment - difference between the amount of fresh water required for the rinsing compartment and the amount of liquid discharged together with the goods is evaporated. 6. The method according to any one of claims 1 to 5,
characterized,
that both the dyeing liquor, including the stock, and the network liquor are supplemented by the wastewater flowing out of the rinsing compartment and that chemicals or dyes are added to the dyeing liquor and network liquor in an amount corresponding to the volume of liquid carried away with the goods. 7. The method according to any one of claims 1 to 6,
characterized,
that the wastewater running out of the washing compartment is cleaned in a lint filter. 8. The method according to any one of claims 1 to 7,
characterized,
that the goods are squeezed to about the same moisture - based on the dry weight of the goods - as at the exit of the washing compartment after each dipping or washing process. 9. Continuous dyeing machine for carrying out the method according to one of claims 1 to 8,
characterized,
that between the power supply (1) and the dyeing part (2) an intermediate dryer (4) with an evaporation capacity (VT) of approximately equal to the value of the amount of the evaporation (VL) in the dyeing compartment (2) reduced difference in the quantity (VF) of for the rinsing compartment (3) required fresh water (22) and the amount (VW) of the liquid discharged together with the goods (5) is switched. 10. Continuefärbeanlage according to claim 9,
characterized,
that a cylinder dryer and / or an air dryer is provided as the intermediate dryer (4). 11. Continuous dyeing machine according to claim 9 or 10,
characterized,
that the air passages (10) of the dyeing compartment (2), together with the intermediate dryer (4), have the evaporation capacity required to completely balance the liquid balance. 12. Continuous dyeing machine according to claim 9 or 10,
characterized,
that the dyeing compartment (2) has at least one drying cylinder (29) placed between the immersion trough (8) and the air passage (10). 13. Continuous dyeing machine according to one of claims 9 to 12,
characterized,
that the rinsing compartment (3) has washing troughs (25) in cascade form, each with a spray device (27) directed into the squeezing gap (26) of each squeezing unit (11) downstream of a washing trough (25). 14. Continuous dyeing machine according to one of claims 9 to 13,
characterized,
that the washing compartment (3) is assigned a washing water outlet (12) leading to a washing water reservoir (14) via a fluff filter (13).

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