JPH09111592A - Device for inserting weft into shuttle loom - Google Patents

Abstract

PROBLEM TO BE SOLVED: To ensure shuttles to be guided to reeds while accurately aligning the shuttles with the reads to provide a lightweight guide system integrable easily inside a room. SOLUTION: This device is so designed as to be usable in a shuttle loom with its respective shuttles 6 made up of pawls 7 and tapes 8. In this case, each of permanent magnets 9 is set up along the longitudinal axis of the tape 8, ferromagnetic bodies 12 are located narrowly without discontinuity under a pannu 3 standing against the longitudinal axis of the tape 8, and each of the magnets 9 has a plane of symmetry parallel with both the magnetized direction and the longitudinal axis of the tape 8, being the longest in the direction of the plane of symmetry. Each of the ferromagnetic bodies 12 has a plane of symmetry parallel with both the magnetized direction and the longitudinal axis of the tape 8, being thickest in the direction of the plane of symmetry.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a loom, and in particular,
The present invention relates to a loom that inserts a weft yarn with a shuttle. More specifically, the invention aims at an improvement in the device for guiding the shuttle through the shed.

[0002]

2. Description of the Related Art In a so-called "with pawl" loom, the reed is
By a reciprocating movement, two shuttles which symmetrically pass through the shed from one end of the fabric to the center are received in a known manner.

Each shuttle includes a claw at its free end for pinching the thread. The "entrance side" claw holds the thread at one end of the fabric and carries it to the center of the shed, where it replaces the "outside" claw with the thread, and the exit side claw uses this weft thread on the opposite side of the fabric. Lead to the end of.

[0004]

There is already a loom in which a shuttle is rigid and a sheath which extends laterally of the reed guides the shuttle. This insertion device works at the shed level without the guide system, but has a significant drawback in addition to the wide width of the loom, i.e. the reciprocating motion is caused by the extremely high kinetic energy of each shed It requires consistent braking and acceleration.

In order to solve the problem of taking up space,
It has been proposed to use a shuttle consisting of a pawl and a flexible tape with a rack driven by a loom. As the shuttle moves, the tape flexes and does not add to the loom bulkiness. However, when using such flexible tapes, the problem arises of how to guide the pawl inside the shed.

In order to solve this problem, in a known method, an area of polypropylene bristles attached to the adhesive tape is arranged below the lower warp surface forming the shed so that the shed can be pressed against it. To do. This area or panne supports the movement of the tape guided by a plurality of hooks distributed along the path of the pawl. These hooks pass through the lower warp surface of the shed and are oriented inside the pannu. However, as the hook passes through the shed, the warp threads may be destroyed, which obviously reduces the production capacity of the loom.

Another disadvantage of using the guide hooks on the tape is due to the mechanical construction of the tape. In fact, the mechanical rigidity of the tape is due to the carbon fiber core of known durability. When the tape passes through the inside of the hook, the friction causes a certain amount of carbon to adhere to the inside surface of the hook. As a result, while the tape is exhausted, these black deposits are carried as the warp passes around the hooks, creating dirty zones in the fabric.

Therefore, one of the problems to be solved by the present invention is to eliminate the use of tape guide hooks.

French patent 2244852, corresponding to US Pat. No. 3,957,089, proposed the use of a magnetically functioning guiding device. The solution is to install an electromagnet containing side steel plates on the reed and close the magnetic field when passing through the pawl orbit. Thus, when the electromagnet is in communication, the magnetic field holds the pawl between the two steel plates mentioned above. Although this method does not require a hook, it requires a large electromagnet, and its power supply must be secured. Therefore, such a solution is difficult to incorporate into conventional reeds of looms.

Furthermore, this method is cumbersome when using decentered pawls with respect to the tape, since it does not have any means for centering the pawls in the guide means, which is especially "positive" pawls. It is a case of using a nail commonly called ".

Similarly, US Pat. No. 4,126,159
Proposed to use magnetic means to attract the reed to the tape. More specifically, this document discloses that the side end of the reed includes an electromagnet that attracts a pawl arranged at the end of the tape.
It describes how to keep the tabs from leaving the pannu when the tape ends reach both ends of the reed. This method
Guide hooks have to be used, thus leading to the disadvantages mentioned above.

[0012] EP 0233141 also comprises a reed in which two magnets are arranged in the contact area of the pawl, while the tape has the lightest possible metal parts embedded in its thickness in the joint area with the pawl. Including equipment. Thus, at the end of the Pannu's stroke, when the metal parts face the parts located on the reed, the tape is attracted and somewhat stabilized. Unfortunately, the discrete and localized placement of metal parts and magnets manifests itself in fluctuations in the strength of the attractive force during the pawl stroke, which constitutes an instability element.

Further, since the shape of the metal part embedded in the tape is large, accurate side guide cannot be performed,
On the other hand, it turns out that the critical point becomes a problem especially regarding the exchange of the weft thread between the pawls.

[0014] The problem to be solved by the present invention is to provide a lightweight guide system which guides the shuttle accurately while aligning the shuttle with the reed, and which can be easily incorporated into the loom.

[0015]

SUMMARY OF THE INVENTION The present invention relates to a weft insertion device that can be used in a shuttle loom in which each shuttle comprises a pawl and a tape, and the tape moves from both sides of the fabric by reciprocating motion, and the pawl is Entering the shed at approximately the same distance as sending the weft, the shed passes through the shed by sliding on the pannu interlocking with the reed, and emerges under the thread on the warp surface below the shed, The guide of the shuttle with respect to the reed relates to a device magnetically secured by a ferromagnetic material and a plurality of permanent magnets arranged on the tape and the reed.

The improved device according to the invention comprises, firstly, that the permanent magnet is located in the longitudinal axis of the tape and the ferromagnetic material is arranged in an elongated and continuous manner below the pannu opposite the longitudinal axis of the tape. -Secondly, each magnet has a plane of symmetry parallel to both the magnetization direction and the longitudinal axis of the tape, and is longest in that direction of symmetry; -Finally, the ferromagnetic material It has a plane of symmetry parallel to both the vertical axis of and and has the greatest thickness in the direction of the plane of symmetry.

In other words, the pawl is guided by the interaction between the magnet located on the tape and the metal part located below the panne. As the pawl advances, the magnet and the elongate part attract each other so that the pawl stays on the trajectory corresponding to the minimum distance between the magnet and the elongate part.

The power supply of each magnet is collected on the longitudinal axis of the tape, and the strip of parts most strongly attracted by the magnet is also located opposite the longitudinal axis of the tape. In this way the magnet and the entire elongated part naturally tend to oppose the thickest area of the elongated part to the longitudinal axis of the tape, which results in optimized centering and self-adjustment. become. In other words, the equilibrium position is automatically centered due to the shape of the parts that is a feature of the invention.

In fact, advantageously, the permanent magnet is a disk and the ferromagnet is a cylinder.

Thus, the tape has a hollow area into which the magnetic disk is inserted. Correspondingly, the reed includes a vertical groove with an opening facing the bottom of the pannu, in which the ferromagnetic material is housed.

Furthermore, the diameter of each disk forming the permanent magnet is 5 to 20 mm. The thickness of each disk is 1-10 mm, preferably 3-5 mm. The diameter of the ferromagnetic body made into a cylinder is 3-10 mm. The permanent magnet is a rare earth and the ferromagnet is steel.

The method for carrying out the invention and the advantages of the invention will be apparent from the description of the specific embodiments shown with reference to the accompanying drawings.

[0023]

BEST MODE FOR CARRYING OUT THE INVENTION As described above, the present invention relates to an improvement of a guide system for a shuttle in a loom with a pawl. That is, as shown in FIG. 1, a loom equipped with the device of the present invention has a reed (1), a comb (2), and a shed (5).
An area (3) that comes into contact with the reed (1) when it is opened and goes under the portion (4) of the shed (5).

The insertion of the weft thread is conventionally obtained by a reciprocating movement of the shuttle (6), the free end of which supports the pawl (7), which can guide the weft thread from one end of the fabric to the center of the shed. The present invention, weft exchange pawl each other is carried out by actuation of the pawl of external components in shuttle with the "normal position (positive)" nails, weft exchange takes place by pulling "negative position (negative) It is self-evident that a shuttle with a pawl can be applied independently. Therefore,
The detailed structure of the pawl is not mentioned here.

As shown in FIG. 1, the claw-fixed tape (8) comprises a plurality of discs (along the longitudinal axis of the tape (8), especially at the height of its end entering the shed. 9)
Support the pawl (7). The magnet (9) is housed in the hollow cavity of the tape to reduce the distance between the reed (1) and the magnet (9) as much as possible. The magnetic force of each magnet (9) is oriented perpendicular to the plane of the tape (8).

By way of example, and not limitation, the magnets typically used are rare earths, 13 mm in diameter and 4 mm thick.

Further, the reed (1) is an extension portion (1) made of shaped steel and arranged directly below the warp surface (4) below the shed.
0). As is conventional, this profile (10) comprises on its upper surface an area (3) formed of polypropylene bristles, which is commonly referred to as panne. When the shed (5) is opened, this pannu (3) receives the lower warp surface (4) of the shed and the warp surface is slightly inside the hair.

In order for the guidance system to function properly,
Of course, the shape steel must be a non-magnetic material such as aluminum.

The pannu (3) also serves as a sliding area for the tape (8) of the shuttle (6).

According to the invention, the shaped steel (10) has a vertical receiving groove (11) just below the panne (3), in which it has a cylindrical shape made of a ferromagnetic material such as soft iron or steel. Insert the rod (12). The groove (11) is arranged in the center of the upper surface of the shape steel (10).

According to another feature of the invention, the ferromagnetic rod (12) has a maximum thickness along the longitudinal midplane (14) of the Pannu.

Typically, the cylindrical rod has a diameter of 4 millimeters.

Thus, the magnet (9) is a ferromagnetic component (12).
Force is exerted symmetrically on both sides of the longitudinal axis of the tape (8). The position shown in Figure 2 constitutes a stable equilibrium position in which the tape (8) returns in case of deviation. In fact, when the tape (8) is slightly displaced to one side of the panne (3), the maximum magnetic force of the magnet is oriented along the longitudinal axis (13) of the tape (8), so that the tape is a ferromagnetic rod. According to the maximum thickness of (12) and the return force that tries to link the magnetic force. Thus, a very effective automatic alignment phenomenon can be obtained for guidance.

From the above, the guide device according to the present invention has the following remarkable advantages. That is, in part, the shuttle can be guided on the panne without the use of a hook that enters the shuttle. Also, the geometry of the magnetic components allows the tape to be automatically centered on the reed.

[Brief description of the drawings]

FIG. 1 is a schematic view of a weft insertion area showing a shuttle that enters a shed.

2 is a cross-sectional view of FIG. 1 with a vertical plane parallel to the warp threads, showing characteristic details of the shuttle according to the invention.

[Explanation of symbols]

 1 Reed 3 Pannu 4 Warp surface 5 Shed mouth 6 Shed 7 Pawl 8 Tape 9 Permanent magnet 11 Vertical groove 12 Ferromagnetic material 13 Symmetrical surface 14 Symmetrical surface

Claims (8)

[Claims] 1. Each shuttle (6) has a pawl (7) and a tape (8).
A weft insertion device that can be used in a shed loom consisting of and, wherein the tape (8) moves from both sides of the fabric by a reciprocating motion, and the pawls (7) feed the wefts at substantially the same distance. Enter the mouth (5), the shuttle (6) is reed (1)
It slides on the pannu (3) interlocking with and passes through the shed (5) to come out under the thread (4) of the warp surface (4) below the shed, and also the reed (1). The guide of the shuttle (6) with respect to (1) is magnetically performed by a ferromagnetic body (12) and a plurality of permanent magnets (9) arranged on the tape (8) and the reed (1). The permanent magnets (9) are arranged along the longitudinal axis of the tape (8) and the ferromagnetic material is elongated and continuous under the pannu (3) facing the longitudinal axis of the tape. Each magnet has a plane of symmetry (13) parallel to both the magnetization direction and the longitudinal axis of the tape, and is longest in the direction of the plane of symmetry (13); Having a plane of symmetry (14) parallel to both the direction and the longitudinal axis of the tape, Apparatus characterized by the most thick on the surface (14) direction. 2. Device according to claim 1, characterized in that the permanent magnet (9) is a disk body. 3. Device according to claim 1, characterized in that the ferromagnetic body (12) is a cylinder. 4. The reed (1) includes a vertical groove (11) opening toward a lower portion of the pannu (3), and the ferromagnetic material (12) is housed therein. The apparatus according to any one of Items 1 to 3. 5. Device according to claim 1, characterized in that the tape (8) has a hollow area for accommodating the permanent magnet (9). 6. The diameter of each disk (9) forming the permanent magnet is 5 to 20 mm, and the thickness of each disk is 1 to 10 mm. The device according to. 7. Device according to claim 3, characterized in that the cylindrical ferromagnetic body (12) has a diameter of 3 to 10 mm. 8. Device according to claim 1, characterized in that the permanent magnet (9) is a rare earth and the ferromagnetic body (12) is made of steel.