JPH06100246A - Tow jointing device - Google Patents

Abstract

PURPOSE:To increase drawing strength after jointing the sections of tow to each other by superposing the ends of two strings of tow, twining and jointing tow fibers to each other via the air blown to the superposed section, and providing a current plate for preventing the air from flowing in the breadthwise direction of the tow fibers. CONSTITUTION:When two strings of tow T (T1 and T2) are jointed to each other, the lengthwise direction of each tow T is kept in agreement with the lengthwise direction of current plates 20 on a placement section 18, and each tow T is guided to a device body 12. Then, after the joint ends of the tow T are superposed on the section 18, a cover plate body 16 is turned to conceal the body 12, thereby clamping and fixing the adjacent sections R of a tow superposed section TJ. Thereafter, the air is blown from the blow holes 32 of an injection nozzle 30, and an undulation like waving is generated on each fiber at the section TJ, thereby twining the undulation with adjacent fibers. Then, the nozzle 30 is caused to travel along guide rods 40 for generating a fiber twined section over the whole of the section TJ. In this case, the flow of the blown air in the breadthwise direction of fibers is prevented with current plates 20, thereby providing the high twined density of fibers.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tow (fiber bundle) joining device.

[0002]

As a method of joining tows, US Pat. No. 3,867,810 discloses a method for joining tows.
A joining method by air entanglement is disclosed. That is, this is a method in which the ends of two tows are overlapped with each other, air is jetted to the overlapping portion, and the two tows are joined by this air jet.

By injecting air into the polymerized portion,
The fibers in one tow and the fibers in the other tow are intertwined with each other, and certainly the two tows can be joined to each other. However, the entangled state of the fibers in the joined portion was not so dense, and the pull-out strength (stretch resistance) was poor.

[0004]

[Means for Solving the Problems] Therefore, in order to solve the above problems, the following means were taken. That is, in the tow joining device of the present invention, the end portions of the two tows are superposed on each other on the placing portion, and the fibers constituting the tow are entangled by injecting air to the overlapping portion to form the tow. An apparatus for joining, wherein a straightening vane for preventing jetted air from flowing in the lateral direction of the fiber is provided on the mounting portion.

According to a second aspect, above the placing portion,
It is preferable to provide a holding means for preventing floating of the superposed portion of the tow.

As described in claim 3, it is possible to provide a slide means for allowing the air jet nozzle to move in the lateral direction of the fiber.

As described in claim 4, it is preferable to provide a fixing means for pressing the adjacent portion of the towed portion in the tow.

The "lateral direction of the fiber" as used herein means
It refers to the direction orthogonal to the longitudinal direction of the fiber.

[0009]

In the tow joining device of the present invention, the end portions of the tows are superposed on the mounting portion. Then, air is jetted toward the overlapping portion. Each fiber in the polymerized portion rises and falls due to the air immediately after being jetted and the return air that has hit the mounting portion and rebounded. As the fibers rise and fall, they entangle with other adjacent fibers.

Further, the blast plate prevents the jetted air from flowing in the lateral direction of the fiber. As a result, there is no concern that the fibers will be scattered in the lateral direction of the fibers under the influence of air. Therefore, as described above, the fibers are sequentially entangled with other fibers in a state where the flow in the lateral direction is regulated, so that the fiber entangled state becomes dense and the tow pull-out strength (stretch resistance) after joining is increased. Strength) is dramatically improved.

According to a second aspect of the present invention, if the pressing means is provided above the placing portion, the overlapping portion of the tow is largely floated by the return air, and the tow may pop out of the apparatus. It doesn't.

If the sliding means for moving the air jet nozzle in the lateral direction of the fiber is provided as in the third aspect, the moving speed of the air jet nozzle can be made substantially constant, and the polymerization is performed. The fiber entangled state in the part can be made substantially the same level in the entire region. In addition, work efficiency is improved.

If the fixing means for pressing the adjacent portion of the overlapping portion of the tow is provided as in the fourth aspect, there is no fear that the tow itself will bounce up or move laterally due to the jet of air. .

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to the drawings, but the present invention is not limited thereto.

The tow joining device (10) showing one embodiment of the present invention is roughly divided into a device body (12) and a rotatably connected device body (12) and a hinge (14). The cover plate (16) (see FIGS. 1 and 2).

The apparatus body (12) is provided with a plate-shaped mounting portion (18) having a substantially square shape in a plane. Prescription section (18)
On top of that, there are seven elongated straightening plates (20).
Is provided so that the long side extends in the horizontal direction and the short side extends in the vertical direction. The seven straightening vanes (20) are provided in parallel at predetermined intervals, and as shown in the figure, the outermost two straightening vanes (20) are slightly higher than the other straightening vanes (20). Has become.

The number (number) of straightening vanes (20) provided on the placing part (18) depends on the width of the tow placed on the placing part (18). I can't say,
When the width of the tow is, for example, 10 to 20 cm, 5
It is preferable to provide 7 to 7.

On the other hand, the cover plate body (16) has a square-shaped toe fixing portion (24) having an air blowing window (22) in the center.
Is equipped with. In addition, in the air blowing window (22),
Holding means (P) is provided. That is, two support bars (26) parallel to the long sides of the straightening plate (20).
However, the air blowing window (2
It is provided in 2). A large number of holding thin shafts (28) are arranged between the two support rods (26) at predetermined intervals so as to extend in a direction orthogonal to the long side of the straightening plate (20). There is. The above-mentioned holding means (P) is constituted by the support rod (26) and the holding thin shaft (28). The pressing means (P) is for suppressing the floating of the tow when air is jetted to the tow, and the details will be described later. When the cover plate (16) is covered with the device body (12), the peripheral portion (18a) of the upper surface of the mounting portion (18) and the lower surface (24a) of the toe fixing portion (24). And will abut each other.

Reference numeral (30) is an air jet nozzle. The air injection nozzle (30) is an elongated hollow rectangular parallelepiped, and has six injection holes (32) on its lower surface. In addition, the air injection nozzle (30)
On the lower surface of, the two injection holes (32) are arranged in the central portion in a direction orthogonal to the longitudinal direction, and the two injection holes (32) are arranged in the same direction on both left and right sides.

The air is supplied to the air injection nozzle (30) through an air hose (34) extending from an air supply device (not shown) and is provided above the air injection nozzle (30). It is carried out from the entrance (36). The air sent into the air jet nozzle (30) is jetted from the jet hole (32).

The size of the injection hole (32) and the pressure of the air injected from the injection hole (32) are not particularly limited, but the preferred range is as follows. That is,
The hole diameter of the injection hole (32) is preferably 1.5 to 4.0 mm, more preferably 2.0 to 3.5 mm. The pressure of the air is preferably 3~6kg / cm ² G, more preferably from 4~5kg / cm ² G. When the diameter of the injection hole (32) is less than 1.5 mm, the tow escapes and the entanglement becomes weak. If the hole diameter exceeds 4.0 mm, the air pressure to be jetted becomes weak and the entanglement becomes weak. If the air pressure is less than 3 kg / cm ² G, the pressure is too weak and the entanglement becomes worse. 6 kg /
When it exceeds cm ² G, the tow escapes and the entanglement becomes weak.

Further, slide pipes (38) are provided on the left and right sides of the air injection nozzle (30). The sliding pipe (38) is provided so that the axial direction thereof is the same as the direction in which the holding thin shaft (28) extends. Reference numeral (40) is a slide guide rod, and is supported by a support shaft (39) extending vertically from the upper surface of the toe fixing portion (24). The slide guide rods (40) have a cylindrical shape, and two guide rods (40) are arranged above the air blowing window (22) so as to be parallel to each other. The slide guide rods (40) are respectively inserted in the slide pipes (38). The slide pipe (3
8), the support shaft (39), and the slide guide rod (40) constitute a slide means (S).

A method of using the joining device (10) having the above-mentioned configuration and a state of use will be described. First, prepare two tows (T1) and (T2) to be joined, and the longitudinal direction of the tows (T1) and (T2) is the length of the straightening plate (20) provided on the mounting part (18). The two tows (T1) and (T2) are guided to the apparatus main body (12) from different directions so as to coincide with the direction, and the end portions, which are the joined portions, are superposed on the mounting portion (18). At this time, the toe (T1) is provided in the plurality of partition portions formed by the flow straightening plate (20),
It is preferable to disperse the ends of (T2) so that they are arranged substantially evenly (see FIGS. 3 and 4).

In this state, if the cover plate (16) is rotated to cover the main body (12), the adjacent portion (R) of the overlapping portion (TJ) in the tows (T1) and (T2) is towed. The lower surface (24a) of the fixed portion (24) and the upper surface of the mounting portion (18) are sandwiched and fixed.

After that, air is sent into the air jet nozzle (30). As a result, air is ejected from the ejection hole (32) provided in the air ejection nozzle (30), and the air is ejected toward the overlapping portion (TJ).

Each fiber in the polymerized portion (TJ) rises and falls like a wave due to the air immediately after being jetted and the return air that has hit the upper surface of the mounting portion (18) and rebounded. As the fibers rise and fall, they entangle with other adjacent fibers.

The air jet nozzle (30) is moved from the end at a substantially constant speed in the direction in which the slide guide rod (40) extends (see FIG. 5). As a result, the fibers in the portion corresponding to the lower part of the air injection nozzle (30) rise and fall in order, and are entangled in order from the end as the air injection nozzle (30) moves. Then, the two tows (T1) and (T2) are joined as the entanglement of the fibers progresses. In addition, since the pressing means (P) is provided above the placing portion (18), there is no concern that the overlapping portion (TJ) will largely float due to the return air.

The blown air is blocked by the straightening plate (20) from flowing in the lateral direction of the fiber. As a result, there is no concern that the fibers will be scattered in the lateral direction of the fibers under the influence of air. Therefore, as described above, the fibers are sequentially entangled with other fibers in a state in which the flow in the lateral direction is regulated, so that the fiber entangled state becomes dense, and the toe after joining (T1), (T2 The pull-out strength (stretch resistance) of () is dramatically improved.

In the present embodiment, since the tows (T1) and (T2) are held by the toe fixing portion (24) of the cover plate (16), the tows (T1) and (T2) are air-conditioned. Even if the tow is being jetted vigorously, there is a concern that the tows (T1) and (T2) may float up significantly due to the return air or may move laterally and jump out of the joining device (10). There is no.

Further, since the air jet nozzle (30) is provided with the above-mentioned slide means (S), the air jet nozzle (30) can be easily and smoothly slid on the guide rod (40). You can move back and forth along with. As a result, the moving speed of the air injection nozzle (30) can be made substantially constant, and the fiber entanglement state in the overlapping portion (TJ) can be made substantially uniform over the entire area regardless of whether the user is an expert or not. Can be at the same level. In addition, work efficiency is improved.

The stretching resistance of the joined tow joined by the joining device (10) was measured. As a result, 1.4 ~
It has been found that it can be stretched 1.5 times. The conditions at that time are as follows.

Width of tows (T1) and (T2); 15 cm Overlap length of tows (T1) and (T2); 30 cm Size of injection hole (32); Diameter 3.5 mm Injection from injection hole (32) Air pressure applied: 5 kg / cm
² G air injection time: 60 seconds.

In this embodiment, a large number of holding thin shafts (28) are provided so as to extend in the direction orthogonal to the long sides of the flow straightening plate (20), but this need not always be the case.
The thin pressing shaft (28) may be provided so as to extend in a direction parallel to the long side of the rectifying plate (20). However, in the sense that the air injection is not obstructed by the holding thin shaft (28), in other words, the air is always jetted directly, the holding thin shaft (2
It is preferable to provide 8) so as to extend in a direction orthogonal to the long side of the rectifying plate (20). Further, instead of the support rod (26) and the pressing thin shaft (28), for example, a net formed by intersecting a large number of strips may be provided. However, if it is a net, the air hits the overlapped portion (TJ) in the tows (T1) and (T2) will weaken, and the overlapped portion (TJ) will be completely pressed, and the entanglement of the fibers will weaken. , Not very good.

The positions of the injection holes (32) in the air injection nozzle (30) are, for example, 5 to 6 injection holes (32) other than those shown in this embodiment. One may be provided in parallel at a predetermined interval in the longitudinal direction of (30). However, considering that the fibers are made to rise and fall, it is preferable to provide two injection holes (32) at each of the central portion and the left and right sides as shown in this embodiment.

In addition to the structure described above, the structure for making the air jet nozzle (30) slidable is as shown in FIG.
Guide plates (46) having dovetail grooves (44) are erected on the left and right sides of the air jet nozzle (30), and the dovetail grooves ( A structure provided with a protrusion (48) to be fitted into the shaft 44) may be used. Needless to say, the slide means (S) is not provided, and the operator holds the air injection nozzle (30) in his hand, and the injection hole (32)
It is also possible to apply more air to the tow evenly.

[0036]

When the tows are joined by the joining device of the present invention, the fiber entangled state in the tow overlapping portion becomes dense, and the pull-out strength (stretch resistance) of the tows after joining is dramatically improved.

[Brief description of drawings]

FIG. 1 is a perspective view of a joining device showing an embodiment of the present invention, showing a state in which a cover plate is opened.

FIG. 2 is a plan view showing a state in which the cover plate body in the previous figure is closed.

FIG. 3 is a schematic plan view showing a state in which a tow is placed on the placing portion.

FIG. 4 is a schematic side view of FIG.

FIG. 5 is a perspective view showing a state when air is being jetted.

FIG. 6 is a cross-sectional perspective view of an essential part showing another structure that makes the air injection nozzle slidable.

[Explanation of symbols]

 10 ...... Joining device 18 ...... Placement part 20 ...... Rectifier plate 24 ...... Toe fixing part 28 ...... Pressing thin shaft 30 ...... Air injection nozzle P ...... Pressing means R ...... Adjacent part (overlapped part) S ... Sliding means T1, T2 ... Toe TJ ... Overlapped portion t ... Toe end

Claims (4)

[Claims] 1. An apparatus for joining the tows by superposing the ends of two tows on a placing part, and injecting air to the overlapping part to entangle the fibers forming the tows. A tow joining device, characterized in that a flow straightening plate for preventing the jetted air from flowing in the lateral direction of the fiber is provided on the mounting portion. 2. The tow joining device according to claim 1, further comprising a pressing means provided above the placing portion to prevent the superposed portion of the tow from floating. 3. The tow joining device according to claim 1 or 2, further comprising slide means for enabling movement of the air injection nozzle in the lateral direction of the fiber. 4. The fixing means for pressing the adjacent portion of the towed portion of the tow is provided.
The tow joining device according to claim 1.