KR100291307B1 - Nozzle assembly - Google Patents

Abstract

PURPOSE: Provided is a nozzle assembly which is characterized by being possible to separate and to assemble easily, being possible to change nozzle in accordance with a kind of textile and weight simply, controlling exhausting quantity and exhausting velocity, getting uniform dyeing and increasing quality of dyed material. CONSTITUTION: High-temperature and high-pressure dyeing machine is comprised of a dyeing bath, a heat exchanger, a textile transferring reel, a transfer line(16) and the nozzle assembly(2). The nozzle assembly(2) is comprised of: a tube type case(11) containing an opening part incising half lower part of one side; a big hole nozzle(7) which is fixed and installed on a nozzle sheet(13), occupying half upper part of the case(11) and containing a grooves part(12) on a lower part thereof; a cylindrical connecting member(9) joined to the big hole nozzle(7); and an annular supporting part(10) which is installed on a lower part of the case(11) adjacently, being possible to move on screw type up-and-down and transferring the cylindrical connecting member(9) up-and-down.

Description

Nozzle Assembly {NOZZLE ASSEMBLY}

The present invention relates to a nozzle assembly, and more particularly, to a nozzle assembly that can be easily separated and combined in a high temperature and high pressure dyeing machine.

In general, the high temperature high pressure dyeing machine mainly consists of a dye bath, a heat exchanger and a nozzle, a transfer pipe connected to the fabric, and a fabric conveying rail, and is dyed while rotating a predetermined amount of fabric continuously several times.

In this high temperature and high pressure dyeing machine, about 125kg of cloth is put into one nozzle and dyed in 1 minute within 3 minutes. Therefore, in the case of a thick fabric, the cloth is circulated at a speed of 200 to 250yd / min. Since the feed length is longer than the feed length, it must be processed at a higher speed so that the circulation water per unit time does not decrease.

Therefore, according to this, the rotational speed of the fabric supply rail in the dyeing tank should also be fast, but if the suction power of the nozzle does not match, the fabric will accumulate at the nozzle inlet, so the suction power of the nozzle and the injection speed of the salt solution should be increased to facilitate the process. . In other words, in order to control the rotation speed and nozzle suction input of the rail according to the type and weight of the fabric, the nozzle diameter was changed to a small one, or the amount of fabric to be processed was reduced, so the processing efficiency was considerably low.

Moreover, until now, the nozzles mounted on the high temperature and high pressure dyeing machine are all fixed, so to change the amount of salt solution ejected from the nozzle according to the material of the fabric, the installed nozzles must be taken out and the new nozzles corresponding thereto are used again. However, in order to remove the nozzle from the dyeing machine body, the worker has to climb on the nozzle and loosen the assembly screw one by one. In a small space, it is very difficult and time consuming to release the nozzle with the side member fixed.

Therefore, it was very inconvenient to treat efficiently under appropriate pressure according to the type and weight of the fabric put into the dyeing machine and the dyeing defect rate was high.

The present invention has been made to solve this problem in a high temperature and high pressure dyeing machine, it has been developed a nozzle assembly that can vary the diameter of the nozzle according to the type of fabric to be dyed in a simple manner.

That is, the present invention is to provide a nozzle assembly that can adjust the amount of salt solution by conveniently replacing the nozzle according to the type and weight of the fabric to be dyed by forming a nozzle assembly so that the nozzle can be easily separated and combined in a set-up manner.

1 is a cross-sectional view schematically showing a process flow of a high temperature high pressure dyeing machine equipped with a nozzle assembly according to the present invention;

Figure 2 is a perspective view showing the overall structure of the nozzle assembly according to the present invention,

3 is a longitudinal sectional view of a nozzle assembly in which a large diameter nozzle is assembled as an embodiment of the present invention;

4A, 4B, 4C, and 4D are longitudinal cross-sectional views of nozzle assemblies sequentially illustrating a process of assembling a small nozzle into the large nozzle of FIG. 3 as another embodiment of the present invention;

Figure 5 is a longitudinal sectional view of the nozzle assembly of the present invention assembled in the order of Figure 4 above.

※ Explanation of symbols for main parts of drawing

1: dyeing tank 2: nozzle assembly

7: large diameter nozzle 8: small diameter nozzle

9 connection member 10 support portion

11 case 12 groove

13: nozzle seat 14: salt solution injection portion

15: O-ring 16: transfer pipe

17: small hole 18: opening part

19: protrusion F: fabric

A feature of the present invention is a nozzle assembly mounted on a high temperature high pressure dyeing machine consisting mainly of a dye bath, a heat exchanger, a fabric feed roller, and a feed pipe,

The nozzle assembly has a tubular case having an open portion in which a lower half of one side is cut, a large diameter having a large diameter inlet having a groove portion at a lower end thereof, which is secured to the nozzle seat and occupies the upper half of the case. Nozzle, a cylindrical connecting member that is rotatable and joined to the large diameter nozzle, an annular support for moving up and down the connecting member which is located close to the lower part of the case and is movable up and down by a screw type so as to contact the upper part. It consists of.

In addition, according to the present invention is configured such that the small diameter nozzle having a small inlet is inserted into it can be mounted, and between the connecting member and the large diameter nozzle through the open portion of the case by rotating the support portion up and down The small diameter nozzle is also characterized in that the separation or insertion can be mounted.

In addition, the present invention is characterized in that the large diameter nozzle and the small diameter nozzle is provided with an O-ring for preventing leakage.

In addition, the present invention is also characterized in that the small diameter nozzle inserted into the large diameter nozzle is provided with a protrusion around the lower end thereof and is attached to the lattice groove of the large diameter nozzle.

Hereinafter, with reference to the accompanying drawings in order to more easily understand the features of the present invention will be described.

1 schematically illustrates a process flow in a high temperature high pressure dyeing machine equipped with the nozzle assembly of the present invention, and FIG. 2 shows an overall shape of the nozzle assembly according to the present invention normally installed in pairs in the high temperature high pressure dyeing machine of FIG. As a perspective view showing, since each of the pair of nozzle assemblies is formed in the same structure, only one of the pair of nozzle assemblies is shown for convenience of description.

As shown in FIG. 1, it is located between the fabric conveying rail 6 and the conveying tube 16 in a dye bath 1 having a heat exchanger 4, a pump 5, and a service tank 3. The nozzle assembly 2 of the present invention has a tubular case 11 having an open portion 18 in which a lower half of one side is cut off.

In this case 11, a large diameter nozzle 7 which is configured to diverge upwardly so that the diameter of the inlet is larger than the body and is fixed to the nozzle seat 13 occupies almost the upper half thereof. In addition, the large diameter nozzle (7) is formed so that the cylindrical connecting member (9) movable up and down as shown in Figure 3 is properly bound and has an O-ring (15) made of a conventional rubber component to prevent leakage The salt solution injection portion 14 is formed. In addition, the large diameter nozzle 7 is configured to be firmly attached to the lower end of the small diameter nozzle 8 to be inserted and mounted as necessary by forming a groove-like groove 12 in the lower end thereof.

A screw groove (not shown) is formed in the lower part of the case 11, and a support 10 is built in the vicinity of the case 11. The support portion 10 has an annular shape and forms a plurality of small holes 17 at its periphery end, so that the case 11 is screwed by inserting and rotating a suitable means (not shown) in the small holes 18. It is possible to move up and down through the screw groove of the connecting member 9 which is in contact with the upper portion is moved up and down.

The nozzle assembly 2 of the present invention having such a structure rotates the support part 10 up and down in the case 11 through the opening portion 18 of the case 11 shown in FIG. The small diameter nozzle 8 can be further installed or separated between the large diameter nozzle 7 and the large diameter nozzle 7.

The small-diameter nozzle 8 is formed in the same shape and structure as the large-diameter nozzle 7, but the outer diameter thereof is smaller than the large-diameter nozzle 7, and the inlet end thereof is in close contact with the body of the large-diameter nozzle 7. . In addition, the small-diameter nozzle 8 has a protrusion 19 formed around the lower end thereof so that the small-diameter nozzle 8 is inserted into and fixed in the groove 12 of the large-diameter nozzle 7 when it is inserted into the large-diameter nozzle 7. The small diameter nozzle 8 of such a configuration is prepared in several ways so that it can be mounted by changing the diameter as needed, and the small diameter nozzle 8 having a diameter suitable for the type and weight of the fabric may be adopted.

In addition, the small-diameter nozzle 8 is provided with an O-ring 15 not only in the upper part but also in the protrusion 19 of the lower end.

When the small diameter nozzle 8 is inserted into and connected to the large diameter nozzle 7, the diameter of the salt solution injection portion 14 is reduced, unlike the case shown in FIG. 3, as shown in FIG.

In addition, the connecting member 9 is also used to replace the diameter of the small diameter nozzle (8) to be adopted that is different. Therefore, one connecting member 9 is provided in addition to the number of the small diameter nozzles 8.

As another specific example of the nozzle assembly 2 of the present invention, as shown in Fig. 5, the small-diameter nozzle 8 is constructed by being mounted in the order of Figs. 4A, 4B, 4C, and 4D.

That is, as shown in FIGS. 4A and 4B, the support 10 is rotated downward to remove the connecting member 9 in FIG. 3 through the opening 18 of the case 11, and then the small diameter nozzle 8 is removed. By inserting the large diameter nozzle 7 through the opening portion 18, the small diameter nozzle 8 is attached to the body portion of the large diameter nozzle 7, and forms a salt solution injection portion 14 having a diameter smaller than that shown in FIG. Done.

Then, as shown in Figs. 4C and 4D, a connecting member 9 which matches the diameter of the small nozzle 8 is disposed below the small diameter nozzle 8 through the opening portion 18 of the case 11. The small-diameter nozzle 8 is inserted into the large-diameter nozzle 7 firmly and is firmly attached to the lower-diameter nozzle by rotating the lower support part 10 in the direction of the arrow in close contact with the connecting member 9. (See Fig. 5).

The lower end of the nozzle assembly 2 of the present invention is firmly connected to the transfer pipe 16 to prevent leakage.

In this way, the nozzle assembly 2 of the present invention is usually a fabric, for example, a high-quality fabric having a low surface tension and easily cracking and peeling easily, and being a cotton fabric, a nylon fabric, to be dyed under a low pressure of up to 0.5 kg / cm 2. In the case of woolen fabrics and their blended fabrics, linens, polynosics, terry fabrics, velours, brushed fabrics, etc., as shown in FIG. 3, the dyeing treatment is performed with only the overflow large diameter nozzle 7 mounted thereon, Sensitive high-quality fabrics such as fabrics normally dyed under high pressures up to 1.5 kg / cm 2, such as polyester and cotton blended fabrics, crepe fabrics of high counts and lectures, satin fabrics, jacquards, jersey and lacel knitted fabrics, oxfords, tapetera fabrics, etc. In the case of applying a small nozzle (8) as shown in Figure 5 to apply a jetflow (jetflow) is the salt is ejected at high speed to the fabric through the injection portion 14 salt Of the ejection amount and the speed it is possible to smoothly control.

As such, according to the present invention, the nozzle of the high temperature and high pressure dyeing machine is configured to be easily separated and combined in a set-up manner, so that the nozzles of the dyeing machines having different diameters can be easily used within a short time according to the type and weight of the fabric to be dyed. Therefore, the amount and speed of salt solution can be controlled appropriately and quickly, which improves the treatment efficiency and the dyeing is uniform so that the quality of the dyeing product can be further improved without damaging the dyeing or fabric.

In addition, in the case of the existing high temperature high pressure dyeing machine, a very sensitive dye which could only be dyed under normal pressure could not be treated, and thus an additional pressure dyeing machine was needed. However, when the nozzle assembly of the present invention is used in a high temperature high pressure dyeing machine, the nozzle pressure may be up to 0.3 kg / ㎠. Since it can be lowered, there is a big advantage that does not need a separate atmospheric dyeing machine is excellent in generality.

Claims (5)

In the nozzle assembly (2) mounted on a high temperature and high pressure dyeing machine consisting mainly of a dye bath (1), a heat exchanger (4), a fabric feed rail (6), and a feed pipe (16), The nozzle assembly (2) occupies a tubular case (11) having an open portion (18) in which the lower half of one side is cut, and is fixed to the nozzle seat (13) and occupies the upper half of the case (11). A large diameter nozzle (7) having a large diameter inlet having a groove portion (12) at its lower portion, a cylindrical connecting member (9) rotatable and joined to the nozzle cover (12) of the large diameter nozzle (7), Positioned close to the bottom of the case 11 and screw-movable up and down characterized in that it consists of a ring-shaped support 10 for moving the cylindrical connecting member 11 in contact with the top up and down Nozzle assembly. The nozzle assembly according to claim 1, wherein a small diameter nozzle (8) having a small inlet can be inserted into the large diameter nozzle (7). 3. The small diameter nozzle (8) according to claim 2, wherein the small nozzle (8) can be mounted to or detached from the large diameter nozzle (7) through the opening portion (18) of the case (11) by rotating the support portion (10) up and down. Nozzle assembly, characterized in that. The nozzle assembly according to claim 1 or 2, wherein the large-diameter nozzle (7) and the small-diameter nozzle (8) are each provided with an O-ring (15) for preventing leakage. The small-diameter nozzle (8) inserted into the large-diameter nozzle (7) is provided with a projection (19) around its lower end and is attached to the lattice groove (12) of the large-diameter nozzle (7). Nozzle assembly, characterized in that.