KR830001974B1 - Ultra-low bath solution liquid dyeing method - Google Patents

Abstract

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Description

Ultra-low bath solution liquid dyeing method

1 is an explanatory diagram of the configuration of an apparatus for carrying out the method of the present invention and the relationship between the circulating action of a chromosome and the action of other main parts.

2 is an explanatory diagram of the content rate of a chromosome to be moved in a tank in a meandering direction.

The present invention relates to a method of lapping (Lappt) in the liquid conveying method.

According to the conventionally known liquid dyeing process, a large amount of saline solution is required for the dyeing of blood dye, and dyeing, preparation and heating and cooling of water are not only wasteful of energy, but also dyeing. Salt blisters flowing in the passage of the liquid of the process are entangled or entangled by vortices caused by the collision between the liquid and the retained liquid, thereby impairing work efficiency.

In addition, in the above-described conventional process, when the dye is drawn up in the retaining liquid, a large amount of the salt solution is impregnated into the cloth, thereby increasing the load upon pulling and further degrading the product quality after dyeing.

The above-mentioned defects are remarkable especially when the dyeing method is performed at a high temperature, and thus the failure rate of the work is high, and most of the dyes have to be discarded.

In order to improve such a known dyeing method, for example, by using a low-bath ratio method of liquids, and by using a computer to control the auxiliary work, management and dyeing means around the dyeing, etc., as well as the scale of implementation It is very large and it is difficult to achieve energy saving with so-called ultra low bath ratio.

It is an object of the present invention to provide an easy dyeing method by removing the above defects.

Hereinafter, the implementation of the method of the present invention will be described in detail with reference to the drawings. In FIG. 1, an object chromosome (hereinafter referred to as an object) 0 is formed between the liquid flow path 1 and the tank 2. The recess is configured to feed in the direction of the arrow.

That is, the pipe 3 and the liquid flow path for sending the salt solution L collected at the inner bottom part L 'of the tank 2 to the upstream portion U of the liquid flow path 1. The pump 4 is arrange | positioned so that the liquid (not shown) may flow continuously to the downstream part d of (1).

Next, the conveying belt 5 which will be described later is constituted by a permeable mesh, and the belt 5 is conveyed from the lower portion of the downstream portion d as described above in the upstream portion U. Conveyor 6 is temporarily constructed inside the tank 2 described above.

The conveyor 6 is configured to be shiftable, so that when the object 0 flows down the inside of the above-described liquid flow path 1 at about 400 m / min, the conveyer 6 is usually carried at its speed of 4 m / min. To operate.

In the above-described configuration, the tank 2 has a drum shape that is horizontally long, and one side of the drum is disposed obliquely so that the salt solution L is collected at the inner bottom portion L 'and the downstream portion d of the liquid flow path 1 And a porous shoe tower for the liquid permeation near the middle of the conveyance 6), which is configured to be freely adjustable through the handle H.

Next, the second flow path 8 diverging from the vicinity of the junction between the pipe 3 and the discharge port M of the salt liquid flow is disposed in parallel with the liquid flow path 1, and the liquid flow path 8 The trays 9 and 10 are added.

12 is a reel when the object 0 is finished and pulled up, and 11 is a heat exchanger of the salt solution. Since the apparatus for carrying out the method of the present invention has been configured as described above, the salt solution L of the tank 2 is sucked through the pipe 3 'and penetrates the tank 2 by the pump 4 at the time of operation. The liquid flow path 1 described above is heated in a heat exchanger 11 and then flows from the discharge port M of the salt liquid flow corresponding to the inner diameter of the liquid flow path 1 and the speed at which the object 0 is sent. Since the object (0) reaches the lower part of the downstream part (d) of the liquid passage (1) together with the discharged heated salt (L), the object (0) is discharged to the object (0). It is twisted and drawn down on the mesh transfer belt 5 which pulls down the shoe tower 7 and then naturally drops the liquid L, and the salt solution L is refluxed at the inner bottom of the tank 2. do.

In this case, most of the salt solution L is separated from the object 0 and refluxed by the above-described shoe tower 7 and simultaneously contained in the object 0 while being transported by being picked up by the belt 5. The surplus liquid portions (shown as X, Y, Z ...) also naturally flow out, so that the lightweight object 0 itself is transported, thereby making it possible to speed up such circulation.

In this way, the object 0 is pulled up by the tension of the reel 12 and enters the liquid flow path 1 again, so that the object 0 is uniformly dyed by the first circulation.

Conveyor belt 5 which can be shifted or operated at high speed to enable dyeing at a so-called "ultra low bath ratio", in which the amount of the salt solution L required in the above-described dyeing method can be set 3.5 times as large as that of the object (0). It depends on the action of.

It is thought that in the low bathing ratio method in which the bleb flows only in the salt liquid flow, the bath ratio is in principle 8 to 10 times the liquid amount, and if it is less than this, the efficiency cannot be improved.

In other words, the object (0) twisted inside the above-described shoe tower (7) under this high speed because the time required for circulating the object (0), which is itself light, even once dyed, does not exceed 1.5 minutes in its practice. Violent wrinkles can be prevented in advance, and the speed of the high-speed conveying belt 5 can be manually or automatically adjusted during the operation, so that the object (0) moves in the direction of the large arrow (Fig. 1). There is no confusion in the flow and no tangling or entanglement.

The problem here is that during the above-mentioned dyeing operation, most of the saline solution L flows down the convex 6 so that the object 0 is in a deliquescent state. Part) and its lower layer part (b), so that the homogeneous effect of dyeing is hindered.

This difference is particularly problematic when the amount of the object (0) is large.

That is, the second liquid flow path 8 and the trays 9 and 10 for the shower head constructed in this embodiment are removed and returned to the circulation action of the liquid flow path 1 and the object 0 of the first person. About 180% of the above conflicting part (a) when the transfer belt (5) takes over the polyester (0) when trying to finish knit dyeing of 100% polyester as the object, the lower part (b) At 190%, and at 160% in the conflicting portion a 'near the rails 12 raised to the rail 12 of the device, at about 150% in the lower layer b', almost all There is a 10% difference.

In this embodiment, since there are the second liquid flow path 8 and the trays 9 and 10 described above, the object (0) on the conveying belt 5 can simultaneously carry the same amount of the salt liquid L as the first liquid flow described above. The entire action of the width of the c) is combined with a plurality of trays 9 and 10 such as liquid or rain.

In this action, the difference in the content of the contents at both sides of the upper layer (a, a ') and the lower layer (b, b') of the fabric at the time of knit dyeing of 100% of polyester selected at random was not seen. Do not.

In this way, the contact opportunity between the salt solution (L) and the object (0) is remarkably increased to significantly increase the dyeing quality.

It is obvious that the portion of the salt solution L radiated from the trays 9 and 10 flows down the conveyor 6 as in the case of the first liquid flow.

According to the method embodiment of the present invention, as described above, the amount of the salt solution used is minimized to enable high-speed circulation of the chromosome, and even if the forge of the chromosome is thick or thin, entanglement or entanglement during the process does not occur. Therefore, it is possible to easily obtain a desired high homogeneous dyeing product.

Claims (1)

The chromosome flowing down the first liquid passage along with the salt solution sent out from the tank is taken up on the conveyor belt conveyed in the tank in an upstream and shiftable manner in the upstream direction of the flow path, and then dehydrated. At the same time, most of the dripping liquid in the vicinity of the belt is separated from the chromosome, falls to the bottom of the tank, and is refluxed in the liquid flow path described above. Dyeing method of ultra low bath ratio circulating with liquid.

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