KR100743230B1 - Beam warper - Google Patents

Abstract

A beam warper is provided to simply wind threads extracted from plural thread bobbins when performing a warp work for weaving the threads. A driving drum(6) is located at a side of a warper(2) body and rotated with the center shaft line as the reference by the driving power from a motor(M). A winding beam(8) has a winding member for winding the original fibers with plural strands and includes a rotation shaft in parallel to the center shaft line and is separately arranged. An arm(12) for installing the winding beam is hinged with the warper body and has a hooking groove(16) having openings. The rotation shaft is detachably inserted into the hooking groove. When the circumference of the winding member is contacted with the outside surface of the driving drum and the drum is driven, the arm receives the friction force of the outside surface of the driving drum. An elastic member(18) is connected with an arm so that the winding member is contacted with the outside surface of the driving drum with a constant tension.

Description

Beam Warfare {BEAM WARPER}

1 is a view showing the overall structure of a beam matchmaker according to an embodiment of the present invention.

FIG. 2 is a side view illustrating a setting posture of the driving drum and the winding beam of FIG. 1.

3 is a view for explaining the operation of the driving drum and the winding beam of FIG.

4 is a view for explaining the arm structure of FIG.

5 is a view for explaining the operation of the elastic member of the beam stabilizer according to an embodiment of the present invention.

6 is a view for explaining the stopper action of the beam stabilizer according to an embodiment of the present invention.

The present invention relates to a beam warping machine, and more particularly, it is possible to take out the yarns from a plurality of yarn bobbins during winding work for weaving, and to simply wind them onto the winding beam, and in particular, the detachment of the winding beam is easy and stable. A beam stabilizer capable of working in a winding position.

In general, the canoning operation is to arrange and wind the yarns according to the length of the fabric designed to prepare the weaving process, and according to the type of yarn and the plant size, beam canon, partial canon and ball canon method. Proceeds to.

The beam warping machine used for the beam warping operation is able to take out multiple strands of yarn from a plurality of yarn bobbins and wind them around the circumferential surface of the winding beam with a constant tension and width.

The structure of the beam warp machine will be briefly described as follows: a main body of the warp machine, a winding beam which receives power from a driving source such as a motor, and winds up yarns wound on a plurality of yarn bobbins, and the winding beam of And a spraying lead positioned at the front side to guide the winding direction of the yarns drawn out from the respective bobbins.

As a general power transmission method for driving the winding beam, there is a direct power transmission method in which a rotating shaft of the winding beam is connected to a motor shaft to be driven by receiving power from the motor.

However, such a direct power transmission method is difficult to attach and detach when replacing the winding beam, and takes too much time in recent years has been proposed to indirectly drive the winding beam in order to improve these problems.

The indirect power transmission method includes a separate driving drum connected with a motor shaft to receive power, and is mounted on the drum in contact with one side of the outer circumferential surface of the winding beam so that the drum is driven by frictional force on the outer circumferential surface of the drum. The winding beam is rotated.

Then, the winding beam is mounted on both sides of the engaging groove side formed in the two arms connected by the hinge unit and the hinged body in a locked state, respectively, and transmits power in contact with the drum on the driving drum by a locking contact force. It is located to receive.

However, the above-described indirect power transmission system consists of a groove portion which is formed in the form of a groove in which the locking groove formed on the arm side is simply opened downward, so that the axis of rotation of the beam is rotated during the driving of the winding beam. There is a problem that the locking position is easily changed while flowing in the locking groove by vibration or shock.

When the locking position of the winding beam is changed in this way, it is difficult to stably maintain the winding posture of the winding beam during the winding operation, and the power transmission efficiency is lowered due to slip phenomenon while being in irregular contact with the driving drum.

Furthermore, if the posture of the winding beam is changed, not only the winding direction of the yarn is shifted, but also the yarn cannot be wound with a constant tension, which is a factor that causes a decrease in winding quality and excessive defective quality.

In addition, the locking groove has a groove structure opened so that the winding beam is inserted into or separated from the lower side of the arm, causing the phenomenon that the locking state is easily released during the replacement or driving of the beam, thereby causing the phenomenon of falling to or falling from the bottom surface. It is difficult to secure stable driveability.

In particular, if the winding beam is detached from the arm during the winding operation, not only the winding operation should be stopped, but also a series of repair processes are required to collect the separated winding beam for reuse, so that satisfactory work efficiency and productivity can be expected. Can't.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is easy to attach and detach the winding beam, in particular to prevent the departure from the arm during the replacement or operation of the beam further improved operation stability It is to provide a beam reliever can secure the.

In order to realize the object of the present invention as described above,

The regular game body,

A driving drum which is located at one side of the main raceway main body and receives rotational power from the motor and rotates about the center axis;

A winding beam having a winding portion for winding several strands of yarn and having a rotation axis parallel to the central axis of the driving drum;

The locking unit is hinged to the main raceway main body and is provided with a locking groove opened to allow the rotary shaft to be hooked in the up and down direction so that the rotary shaft is removably inserted in the groove while the winding portion is in contact with the outer circumferential surface of the driving drum. An arm for mounting the winding beam to receive the frictional force of the outer circumferential surface when the drum is driven in a closed state;

An elastic member connected to the arm side such that the winding portion is in contact with the outer peripheral surface of the drive drum by an elastic tensile force

It provides a beam warfare device comprising a.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiments of the present invention are described to the extent that those of ordinary skill in the art can practice the present invention.

Therefore, since the embodiments of the present invention may be modified in various other forms, the claims of the present invention are not limited to the embodiments described below.

1 is a view showing the overall structure of a beam stabilizer according to an embodiment of the present invention, 2 denotes a regular race body, the body 2 is a conventional krill having a plurality of yarn bobbins (B1) It is arranged as shown in the drawing so as to be able to wind the yarn Y drawn out from each of the bobbins B1 in association with the part B.

On one side of the warp main body 2 is a conventional injection lead (4) to be wound in a state in which a plurality of strands (Y) pulled out from the krill portion (B) arranged one by one.

Although not shown in the drawing, this injection lead 4 has a plurality of gaps through which yarns Y wound on the bobbin B1 sides pass, and the gaps are predetermined in a direction crossing the drawing direction of the yarns Y. The winding direction is made to be guided while reciprocating by the length of. Most of the operation of the injection lead 4 is reciprocated by a predetermined pitch while power of a driving source such as a motor is transmitted through a normal cam and connecting rod.

In addition, although not shown in the drawing, the apparatus and the system of the drive system and the control system for the winding work of the yarn Y are installed inside the warp main body 2.

The driving drum 6 is positioned above the warp main body 2. The driving drum 6 is fixed to the support shaft S1 through a central portion, and both ends of the shaft S1 are inserted into the block-shaped bearing D as shown in FIG. do.

One end of the support shaft S1 penetrating the driving drum 6 is connected to receive power from the motor M, so that the axis of the support shaft S1 is driven when the motor M is driven. It is rotated in either direction with respect to.

A winding beam 8 is positioned on the driving drum 6, and the winding beam 8 is inward as shown in FIG. 3 so as to wind the yarn Y drawn out from the krill portion B. FIG. The winding part R is provided in.

The winding beam 8 is formed of a cylindrical body of synthetic resins or metals having excellent durability and wear resistance, and a rotation shaft S2 is installed through the boss portion 10 formed at the center thereof.

The rotation shaft S2 is not shown in the drawing so that the winding beam 8 may be rotatably supported based on the axis of the rotation shaft S2 in a state where the rotation shaft S2 is installed at the boss portion 10. ) It can be fixed by being fitted to a conventional bearing or bush from the inside.

The winding part R has an outer circumferential diameter smaller than the circumferential diameter of the winding beam 8 so that a plurality of yarns Y may be wound to a predetermined length in a range corresponding thereto depending on the working conditions, and Can be formed together.

The winding beam 8 has a posture in which the rotation shaft S2 is in parallel with the support shaft S1 of the driving drum 6 and is positioned as shown in FIG. 2, and the inside of the winding portion R One outer peripheral side of the driving drum 6 is fitted so that the drum 6 is rotated under the frictional force of the outer peripheral surface when the drum 6 is rotationally driven in either direction. (See Fig. 3).

On the other hand, the winding beam (8) is detachably mounted to the arm (12) so that it can be rotated by receiving the frictional force of the drive drum (6).

As shown in FIG. 4, the arm 12 is composed of two pairs, each of which has an attitude toward the driving drum 6 from the warp main body 2, and one end of each of the arms 12 is hinged to the fixed frame 14. do.

The arm 12 is used in a frame of metals or synthetic resins having rigidity capable of withstanding various loads or external forces in a state where the winding beam 8 is mounted.

In addition, the arm 12 can be easily mounted and detached from the winding beam 8, and in particular, the arm 12 can be mounted in a locked contact state that can prevent the winding beam 8 from being detached during the winding operation.

To this end, in this embodiment, as shown in FIG. 5, one side is opened so that the winding beam 8 can be fitted from the hinge point H above the respective arms 12, and extends from the opening point, up and down. The engaging groove 16 which is dug along the direction is formed so that the rotating shaft S2 of the said winding beam 8 may be mounted by this groove 16. As shown in FIG.

The locking groove 16 is mounted in such a state that the rotary shafts S2 of the winding beam 8 are fitted through the opening points, respectively, and can be hooked in the up and down directions from the inside of the groove, respectively.

As shown in FIG. 3, the winding beam 8 mounted on the arm 12 has any of the drums 6 in contact with the outer circumferential surface of the driving drum 6. When driven rotationally in one direction, the friction force rotates in the same direction as in the drawing.

Such a locking groove 16 structure, for example, is not only easier to attach and detach the winding beam 8 than the conventional arm body structure having a locking groove that is dug downwardly open, and in particular, It is possible to prevent the phenomenon that the beam detaches from the groove portion during the detachment operation or the winding operation.

The arm 12 is configured such that the winding beam 8 is mounted in contact with the driving drum 6 in a constant tension.

To this end, in this embodiment, as shown in FIG. 5, one side of the arm 12 is connected to the elastic member 18 and moved downward based on the hinge point H by the elastic tensile force of the elastic member 18. To keep it in a state.

The elastic member 18 is a conventional tension coil spring is used, and is spaced apart from the hinge point (H) of the arm 12, as shown in Figure 5 between the bottom surface of the arm 12 and the warp main body 2 Can be connected to.

Although the elastic member 18 is not shown in the drawings in addition to the tension coil spring, a conventional torsion spring or a leaf spring may be used, and the arm 12 is directed downward by the hinge point H by the elastic force thereof. Is set. The setting method to enable such an elastic action can be easily carried out by those skilled in the art, so a detailed description thereof will be omitted.

Referring to FIG. 6, the beam stabilizer according to the embodiment of the present invention may further include a stopper 20 for limiting the rotation of the arm 12.

The stopper 20 may be made of a metal body having a long cylindrical or polygonal shape, and is inserted into the hole side of the support frame 22 fixed to one side of the main body 2, and the upper surface of the arm 12 may be attached to the stopper 20. It is positioned to be movable in a horizontal position as shown in the figure to enable the engaging contact.

The stopper 20 may contact the upper surface of the arm 12 to limit the rotation of the arm 12 upward with respect to the hinge point (H) by the locking contact force.

That is, the stopper 20, for example, the arm 12 is caused by various vibrations or shocks when the winding operation is carried out while the winding beam 8 is mounted mounted on the arm 12 side. While moving upward with respect to the hinge point (H) it can be prevented that the winding position of the winding beam (8) is changed or the mounting state is released from the locking groove (16).

As described above, the beam warp machine according to the embodiment of the present invention provides a means for detachably mounting the winding beam from the warp main body in a stable posture during the warp work, so that the winding work of the yarn can be easily performed. In particular, it is possible to prevent the detachment of the winding beam or detachment of the winding beam during the winding operation.

Therefore, it is possible not only to secure the operational stability during normal work for weaving, but also to improve work efficiency and productivity.

Claims (5)

Regular game body; A driving drum which is located at one side of the main raceway main body and receives a power from a motor to rotate and rotate about a central axis; A winding beam having a winding for winding several strands of yarn and having a rotational axis parallel to the central axis of the driving drum; The locking unit is hinged to the main raceway main body and is provided with a locking groove opened to allow the rotary shaft to be hooked in the up and down direction so that the rotary shaft is removably inserted in the groove while the winding portion is in contact with the outer circumferential surface of the driving drum. An arm for mounting the winding beam to receive the outer circumferential frictional force when the drum is driven in a closed state; An elastic member connected to the arm side such that the winding portion is brought into contact with the tension portion toward the outer circumferential surface of the driving drum by an elastic tension force; Beam matchmaker comprising a. The method according to claim 1, And the locking groove comprises a groove portion which is open toward the hinge point of the arm and extends from the opening point to be excavated in the up and down direction. The method according to claim 1, The arm is a beam warbyeonggi consists of a pair of two so as to mount two points along the axis of the rotation axis. The method according to claim 1, The elastic member, a beam canon is used any one of the tension coil spring, torsion spring, or leaf spring. The method according to claim 1, The beam stabilizer further includes a stopper for limiting rotation of the arm, And the stopper is positioned so as to be in contact with one side of the arm when the arm is moved upward with respect to the hinge point to limit the rotation by the locking contact force.

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