CN219137100U - Injection molding mechanism for producing spun-laced non-woven fabric - Google Patents

Abstract

The utility model discloses an injection molding mechanism for producing a spun-laced non-woven fabric, wherein a water channel A, a water channel B and a water channel C are arranged in the water spraying plate along the length direction, a thin caliber injection head is arranged at an injection head interface of the water spraying plate, which is positioned at the lower part of the water channel A, a medium caliber injection head is arranged at an injection head interface of the water spraying plate, which is positioned at the lower part of the water channel B, a thick caliber injection head is arranged at an injection head interface of the water spraying plate, which is positioned at the lower part of the water channel C, and the medium caliber injection head, the thin caliber injection head and the thick caliber injection head are arranged in a staggered manner.

Description

Injection molding mechanism for producing spun-laced non-woven fabric

Technical Field

The utility model relates to the technical field of water jet non-woven fabric injection mechanisms, in particular to an injection molding mechanism for water jet non-woven fabric production.

Background

The spun-laced non-woven fabric is obtained by spraying high-pressure micro water flow onto one or more layers of fiber webs to enable the fibers to be intertwined together, so that the fiber webs are reinforced and have certain strength, and the obtained fabric is the spun-laced non-woven fabric. The fiber raw materials are widely available, and can be terylene, chinlon, polypropylene, viscose, chitin fiber, superfine fiber, tencel, silk, bamboo fiber, wood pulp fiber, alginate fiber and the like. The hydroentangled nonwoven process, known as spunlacing or hydroentanglement, is a nonwoven processing technique. The hydroentangled nonwoven process produces a hydraulic action by the continuous jet of high pressure water streams under which the aligned fibers begin to surge, shift and rearrange and entangle with each other, and the web is consolidated and has certain physical and mechanical properties. The mechanism of the hydroentanglement reinforcement process is that after the fiber web enters a hydroentanglement area through a net supporting curtain, high-pressure water flow forms continuous 'hydro-pins', the hydro-pins are cylindrical and vertically irradiate the fiber web through a hydroentanglement head and a hydro-pin plate; during this process, the fibers are carried from the surface into the web substrate by the hydro-pins and form entanglement; the fiber net is penetrated by the water needle in different directions after the water needle penetrates, so that the fiber net receives the double functions of water columns on the front side and the back side in the whole water needling process, and tangles in different directions are formed, are irregular and achieve the reinforcing effect, and therefore the water-jet non-woven fabric is formed.

At present, the water jet heads of the injection molding mechanism for producing the water jet non-woven fabrics are arranged in a matrix mode with the same specification, on one hand, the gap between the water jet heads cannot be sprayed, so that the spraying and rebound area is not maximized, and on the other hand, according to different fibers, the spray heads are required to be replaced, so that inconvenience is caused, and therefore, an improved technology is needed to solve the problem in the prior art.

Disclosure of Invention

The utility model aims to provide an injection molding mechanism for producing a spun-laced non-woven fabric, wherein a thin-caliber injection head, a medium-caliber injection head and a thick-caliber injection head are arranged at the bottom of a water spray plate, after the non-woven fabric is spun-laced by the injection heads which pass through three apertures and are mutually staggered, the injection area and rebound area of the non-woven fabric fiber subjected to the spun-laced area are larger, the entanglement among the fibers is greatly improved, the strength of the non-woven fabric is higher, the firmness is better, the corresponding injection heads can be selected to be used, and the flexibility and the application range are greatly improved, so that the problems in the background art are solved.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an injection molding mechanism for water thorn non-woven fabrics production, includes water spray plate, thin bore injector head, well bore injector head and thick bore injector head, water spray plate upper surface sets up water inlet A, water inlet B and water inlet C, water spray plate is inside to be provided with water course A, water course B and water course C along length direction, water course A is linked together with water inlet A, water course B is linked together with water inlet B, water course C is linked together with water inlet C, water spray plate lower surface just is provided with a plurality of injector head interfaces in the lower part of water course A, water course B and water course C, water spray plate just is provided with thin bore injector head in the injector head interface department that is located water course A lower part, water spray plate just is provided with thick bore injector head in the injector head interface department that is located water course C lower part, well bore injector head and thin bore injector head and thick bore injector head staggered arrangement.

Preferably, the injection molding mechanism for producing the spun-laced non-woven fabric provided by the utility model is characterized in that the injection head connector adopts a threaded connector, and the fine-caliber injection head, the medium-caliber injection head and the thick-caliber injection head are in threaded connection with the corresponding injection head connectors.

Preferably, the utility model provides an injection molding mechanism for producing a spun-laced non-woven fabric, wherein the diameter of an injection hole of the fine caliber injection head is 0.07-0.10 mm.

Preferably, the utility model provides an injection molding mechanism for producing a spunlaced non-woven fabric, wherein the diameter of an injection hole of the medium caliber injection head is 0.11-0.14 mm.

Preferably, the utility model provides an injection molding mechanism for producing a spun-laced non-woven fabric, wherein the diameter of an injection hole of the thick-caliber injection head is 0.15-0.18 mm.

Preferably, the utility model provides a jet forming mechanism for producing a spun-laced non-woven fabric, wherein two sides of the water spraying plate are provided with fixing plates.

Compared with the prior art, the utility model has the beneficial effects that:

three water channels are arranged in the water spraying plate, three rows of spraying heads are arranged at the bottom, namely a fine-caliber spraying head, a middle-caliber spraying head and a coarse-caliber spraying head, after the non-woven fabric is subjected to water spraying by the spraying heads with the three apertures of the fine-caliber spraying head, the middle-caliber spraying head and the coarse-caliber spraying head and staggered with each other, the spraying area and the rebound area of the non-woven fabric fiber subjected to the water spraying area are larger, the entanglement among the fibers is greatly improved, and the strength and the firmness of the non-woven fabric are higher; and the jet heads with three apertures are adopted, if no special requirement exists, the jet heads can be used simultaneously to form three rows of water columns with different jet and rebound areas, so that the entanglement among fibers is further improved, and if the process requirement exists, the corresponding jet heads can be selected, so that the flexibility and the application range are greatly improved.

Drawings

FIG. 1 is a schematic cross-sectional view of the present utility model;

FIG. 2 is a schematic view of the bottom structure of the present utility model;

FIG. 3 is a schematic view of the internal waterway structure of the sprinkler tube.

In the figure: the water spraying device comprises a water spraying plate 1, a thin-caliber spray head 2, a medium-caliber spray head 3, a thick-caliber spray head 4, a water inlet A5, a water inlet B6, a water inlet C7, a water channel A8, a water channel B9, a water channel C10, a spray head connector 11 and a fixing plate 12.

Detailed Description

The technical solutions of the present utility model will be clearly and completely described below with reference to the drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, based on the embodiments of the utility model, which a person of ordinary skill in the art would obtain without inventive faculty, are within the scope of the utility model;

it should be noted that, in the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "inner", "outer", "upper", "lower", "both sides", "one end", "the other end", "left", "right", etc. are directions or positional relationships based on the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or element to be referred to must have a specific direction, be configured and operated in a specific direction, and thus should not be construed as limiting the present utility model.

Referring to fig. 1-3, the present utility model provides a technical solution: a jet forming mechanism for producing spun-laced non-woven fabrics comprises a water spraying plate 1, a thin-caliber jet head 2, a medium-caliber jet head 3 and a thick-caliber jet head 4, wherein a water inlet A5, a water inlet B6 and a water inlet C7 are arranged on the upper surface of the water spraying plate 1, a water channel A8, a water channel B9 and a water channel C10 are arranged in the water spraying plate 1 along the length direction, the water channel A8 is communicated with the water inlet A5, the water channel B9 is communicated with the water inlet B6, the water channel C10 is communicated with the water inlet C7, a plurality of jet head interfaces 11 are arranged on the lower surface of the water spraying plate 1 and positioned at the lower parts of the water channel A8, the water channel B9 and the water channel C10, the thin-caliber jet head 2 is arranged at the position of the jet head interface 11 of the water spraying plate 1 and positioned at the lower part of the water channel A8, the medium-caliber jet head 3 is arranged at the jet head interface 11 of the water spraying plate 1 and positioned at the lower part of the water channel C10, the diameter of the jet hole of the thin-caliber jet head 2 is 0.07-0.10 mm, the penetrability is best, the rebound area is minimum, the diameter of the jet hole of the medium-caliber jet head 3 is 0.11-0.14 mm, the penetrability is medium, the rebound area is medium, the diameter of the jet hole of the thick-caliber jet head 4 is 0.15-0.18 mm, the penetrability is minimum, the rebound area is maximum, water is fed through the water inlet A5, the water inlet B6 and the water inlet C7, water is fed through the water channel A8, the water channel B9 and the water channel C10, water is sprayed out from each of the thin-caliber jet head 2, the medium-caliber jet head 3 and the thick-caliber jet head 4, the medium-caliber jet head 3, the thin-caliber jet head 2 and the thick-caliber jet head 4 are staggered, so that the jet area and the rebound area of the whole water penetration area are improved, and the fixing plates 12 are arranged on two sides of the water spraying plate 1 to realize the fixing of the water spraying plate 1.

The spray head interface 11 adopts a threaded interface, and the thin-caliber spray head 2, the medium-caliber spray head 3 and the thick-caliber spray head 4 are in threaded connection with the corresponding spray head interface 11 so as to facilitate the installation and the disassembly of the thin-caliber spray head 2, the medium-caliber spray head 3 and the thick-caliber spray head 4.

The application method and the principle are as follows: the water spraying plate 1 is manufactured through a molding process, and a water channel A8, a water channel B9 and a water channel C10 are reserved in the water spraying plate 1. The upper part of the water spraying plate 1 is provided with a water inlet A5, a water inlet B6 and a water inlet C7, and the lower part is provided with a spray head interface 11. Before use, the fine caliber spray head 2, the middle caliber spray head 3 and the thick caliber spray head 4 are respectively arranged at the spray head interfaces 11 at the bottoms of the water inlet A5, the water inlet B6 and the water inlet C7. When the water jet device is used, the water inlet A5, the water inlet B6 and the water inlet C7 are respectively connected with water inlet pipes, the water jet plate 1 is arranged in a water jet area of the water jet non-woven fabric through the fixing plate 12, and when the non-woven fabric passes through the water jet area, three water inlet pipes simultaneously feed water, and the water pressure is controlled at 50-300 Bar. The water columns with the corresponding diameters are respectively sprayed by the fine-caliber spray head 2, the middle-caliber spray head 3 and the thick-caliber spray head 4, so that the water jet process of the non-woven fabric is realized. The utility model has reasonable structure, the water spray plate 1 is internally provided with three water channels, the bottom is provided with three rows of spray heads, namely a fine caliber spray head 2, a middle caliber spray head 3 and a thick caliber spray head 4, after the non-woven fabric is subjected to water jet of the spray heads with three apertures of the fine caliber spray head 2, the middle caliber spray head 3 and the thick caliber spray head 4 which are staggered with each other, the spray area and the rebound area of the non-woven fabric fiber in the water jet area are larger, the entanglement among the fibers is greatly improved, and the strength and the firmness of the non-woven fabric are higher; and the jet heads with three apertures are adopted, if no special requirement exists, the jet heads can be used simultaneously to form three rows of water columns with different jet and rebound areas, so that the entanglement among fibers is further improved, and if the process requirement exists, the corresponding jet heads can be selected, so that the flexibility and the application range are greatly improved.

The present utility model is not described in detail in the present application, and is well known to those skilled in the art.

Finally, what is to be described is: the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the examples, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present utility model, which is intended to be covered by the scope of the claims of the present utility model.

Claims (6)

1. A spray forming mechanism for production of water thorn non-woven fabrics, its characterized in that: the water spraying device comprises a water spraying plate (1), a fine caliber spraying head (2), a medium caliber spraying head (3) and a coarse caliber spraying head (4), wherein a water inlet A (5), a water inlet B (6) and a water inlet C (7) are arranged on the upper surface of the water spraying plate (1), a water channel A (8), a water channel B (9) and a water channel C (10) are arranged inside the water spraying plate (1) along the length direction, the water channel A (8) is communicated with the water inlet A (5), the water channel B (9) is communicated with the water inlet B (6), the water channel C (10) is communicated with the water inlet C (7), a plurality of spraying head interfaces (11) are arranged on the lower surface of the water spraying plate (1) and are arranged on the lower parts of the water channel A (8), the fine caliber spraying head (2) are arranged at the spraying head interfaces (11) arranged on the lower part of the water spraying plate (1) and the water channel A (8), the medium caliber spraying head (3) is arranged at the position of the spraying head interfaces (11) arranged on the lower part of the water channel B (9), the coarse caliber spraying head (4) is arranged at the lower part of the water spraying plate (1), the medium-caliber spray heads (3) and the thin-caliber spray heads (2) and the thick-caliber spray heads (4) are arranged in a staggered mode.

2. The injection molding mechanism for producing a spun-laced nonwoven fabric according to claim 1, wherein: the jet head interface (11) adopts a threaded interface, and the fine-caliber jet head (2), the medium-caliber jet head (3) and the thick-caliber jet head (4) are in threaded connection with the corresponding jet head interface (11).

3. The injection molding mechanism for producing a spun-laced nonwoven fabric according to claim 1, wherein: the diameter of the jet hole of the thin-caliber jet head (2) is 0.07-0.10 mm.

4. The injection molding mechanism for producing a spun-laced nonwoven fabric according to claim 1, wherein: the diameter of the jet hole of the medium caliber jet head (3) is 0.11-0.14 mm.

5. The injection molding mechanism for producing a spun-laced nonwoven fabric according to claim 1, wherein: the diameter of the jet hole of the thick-caliber jet head (4) is 0.15-0.18 mm.

6. The injection molding mechanism for producing a spun-laced nonwoven fabric according to claim 1, wherein: the two sides of the water spraying plate (1) are provided with fixing plates (12).

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