KR200182204Y1 - Fastening lock assembly for wings - Google Patents

Abstract

The present invention provides a wing tightening lock device that is able to lightly establish and release the tightening lock by the rotation of the rotor with a smaller force, and has excellent durability of the driving control unit of the standing arm of the lock arm.

By the rotation operation of the rotor 13 inserted into the fixed body 3, the slide cam 6 inserted into the rotor 13 in a non-rotational manner is moved linearly to the rear, and the pivot shaft at the rear end of the fixed body 3 is pivoted. By standing-rotating the lock arm 24 connected by (17), the pressing part 18 of the lock arm 24 abuts on the receiving part 20 on the fixed frame body 17 side, and the fixed body 3 ) Into the annular groove (14) of the rotor and the annular groove (9) of the rotor (2) to prevent the removal of the rotor (13) from the fixed body (3) by means of a plurality of bearing balls (15). The lock arm 24 is rotationally pressurized by the spring 25 in the direction in which the passive portion 23 of the proximal end of 6) contacts the rear end 22 of the slide cam 6. The rear end portion 22 of the slide cam 6 is formed in a wall portion that closes the rear opening of the cavity 5, so that the dimension between the outer surface of both end portions of the operation handle 12 is adjusted to the front plate portion of the fixed body 3 ( Match the diameter of 29).

Description

Tightening Locking Device for Wings

The present invention relates to a locking device used for tightening and locking a wing such as a hatch of a ship to a fixed frame such as a hull in a closed state.

In the wing tightening lock apparatus for which the rotor inserted to the fixed body was rotated and the pressing part of the front-end | tip of the lock arm was made to contact the receiving part by the side of the fixed frame body, the thing of various structures is already proposed.

However, in the conventional tightening lock apparatus, it is a structure in which the rotation operation of the rotor with respect to the fixed body is difficult, and the lock arm contacts with the fixed frame body in contact with the opening / closing operation of the wing, resulting in a coarse structure.

Therefore, the object of the present invention is that the establishment and release operation of the tightening lock by the rotation of the rotor can be performed lightly with a smaller force, and the opening and closing operation of the wing can be made smoothly without disturbing the lock arm. At the same time, there is provided a tightening lock device for a wing that is excellent in durability of the drive operation portion of the standing arm of the lock arm.

1 is a front view of a wing lock device according to one embodiment of the present invention, and shows a state of establishment of a lock lock.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a rear view of the tightening lock device of FIG. 1.

4 is a cross-sectional view of the tightening lock device of FIG. 1 and shows a release state of the tightening lock.

5 is a right side view of the tightening lock device of FIG. 1.

(Explanation of symbols for the main parts of the drawing)

1: female thread of the fixing body 2: wing

3: fixed body 4: male thread of slide cam

5: cavity of slide cam 6: slide cam

7: Hollow part of fixed body 8: Guide shaft part of rotor

9: annular groove of rotor 10: front plate of rotor

11: pivot axis 12: operation handle

13: rotor 14: annular groove of fixed body

15: bearing ball 16: split groove of fixed body

17: pivot axis 18: pressing portion of the lock arm

19: fixed frame body 20: receiving part of the fixed frame body

21: side portion of the slide cam 22: rear end portion of the slide cam

23: Passive part of the lock arm 24: Lock arm

25: spring for locking arm

Hereinafter, referring to the reference numerals in the accompanying drawings, the main components of the wing tightening lock device of the present invention, the fixed body (3), slide cam (6), rotor (13), bearing ball (15), It is a lock arm 24 and the spring for pressure 25.

The fixed main body 3 is fixed to the wing 2, and installs the female screw 1 on the inner circumferential surface of the second half of the hollow portion 7 along the axial direction before and after the front and rear portions of the hollow portion 7. Install the annular groove 14 on the inner circumferential surface. The slide cam 6 is fitted into the hollow portion 7 of the fixed body 3, and the male screw portion 4 is provided on the outer circumferential surface of the base end portion along the axial direction before and after, and the cavity having a non-circular cross section along the axial direction. The part 5 is attached to the center part, and the male screw part 4 is fastened to the female screw part 1.

The rotor 13 is rotatably fitted in the hollow portion 7 of the stationary body 3 and guide shaft portion of a non-circular cross section inserted in the cavity 5 of the slide cam 6 in a non-rotational manner. (8) is formed in the latter half portion, the annular groove (9) is provided on the outer peripheral surface of the middle portion, and the operation handle (12) on the front plate portion (10) by the pivot shaft (11) parallel to the front surface of the wing (2). Connect the proximal end of The operation handle 12 is formed in a U shape so that the dimension between the outer surfaces of both proximal ends of the operation handle 12 coincides with the diameter length of the front plate portion 29 of the fixed body 3. Several bearing balls 15 are fitted into the annular groove 14 of the fixed body 3 and the annular groove 9 of the rotor 2 so as to be electrically rotatable, and the rotor 13 from the fixed body 3. To prevent the fall.

The lock arm 24 is fitted into the split groove 16 in the radial direction of the rear end of the fixed body 3, and the proximal end thereof is fixed by the pivot shaft 17 parallel to the front surface of the wing 2. ) The lock arm 24 is fitted with the side portion 21 of the slide cam 6 in a state where the pressing portion 18 at the distal end portion is engaged with the receiving portion 20 on the fixed frame body 19 side. On the other hand, the passive part 23 which abuts on the rear end face 22 of the slide cam 6 in the state where the tightening lock is released is provided at the base end. The rear end surface 22 of the slide cam 6 is comprised by the wall part which closes the back opening of the slide cam 6. The spring 25 for pressurization rotationally pressurizes the lock cam 24 in the direction in which the passive part 23 of the lock arm 24 contacts the slide cam 6.

(Embodiment of design)

In the illustrated embodiment, the tubular fixed body 3 is inserted into the attachment hole 26 of the wing 2 from the front side, and the nut 28 and the front plate portion fastened to the male screw portion 27 on the outer circumferential surface. It is fixed to the wing 2 by sandwiching the wing 2 between (29). The anti-rotation protrusion 30 on the rear side of the front plate portion 29 is fitted into the cutout portion 31 at the edge of the attachment hole 26. A packing 32 is inserted between the front plate portion 29 and the wing 2 of the fixed body 3. The stopper frame part 33 which the side surface of the lock arm 24 abuts at the time of the standing rotation of the lock arm 24 is provided in the side part of the fixed body 3. The division groove 16 is formed on an extension of the stopper frame 33.

An O-ring 34 is inserted between the outer circumference of the front end of the rotor 13 and the inner circumference of the front end of the hollow part 7 of the fixed body 3, and is fixed to the rear surface of the front plate part 10 of the rotor 13. An annular packing 35 is inserted between the front plate part 29 of the main body 3. The cavity 5 of the slide cam 6 and the guide shaft 8 of the rotor 13 are formed in a square cross section. The cavity part 5 is closed by the thick wall part of the back opening, and the rear end surface part 22 which is the drive operation part of the standing rotation of the lock arm 24 is comprised by the said closed wall part. The click member 38 fitted in the radial receiving hole 37 of the front plate portion 10 of the rotor 13 has an inner surface recessed portion 39 of the operation handle 12 when the operation handle 12 falls. ), The operation handle 12 is kept in an unused position. At the lower periphery edge portion of the front plate portion 10 of the rotor 13, a U-shaped groove portion 40 which can receive the operation handle 12 is formed.

The pivot shaft 11 is inserted into the through hole 41 of the proximal end of the operation handle 12 and the through hole 48 in the radial direction of the front plate portion 10 of the rotor 13. The end is tightened and fixed by press working. The pressing spring 25 of the lock arm 24 is composed of a twisting coil spring, the coil portion 43 of which is fitted to the pivot shaft 17, and one straight end portion 44 of the stopper frame. In contact with the side wall surface of the part 33, the other straight end part 45 is in contact with the inner surface of the plate-shaped passive part 23 of the lock cam 24. As shown in FIG. The pivot shaft 17 of the lock arm 24 is biased on the side of the stopper frame portion 33 than the hollow portion 7, and the lock shaft 24 has a lock on the proximal corner of the pivot arm 17 side of the lock arm 24. The notch 46 for relief at the time of the standing rotation of the arm 24 is provided.

As shown in FIG. 4, when the pressing part 18 of the lock arm 24 is released from the fastening lock released from the receiving part 20 of the fixed frame body 19, the passive part of the lock arm 24 ( 23 is in contact with the rear end face 22 of the slide cam 6, and the lock arm 24 is held in the standby position extending in the axial direction of the fixed body 3 by the pressure of the spring 25. . Therefore, the lock arm 24 is not in contact with the edge of the fixed frame body 19 in contact with the opening / closing operation of the wing 2 and becomes unduly cumbersome. The operation handle 12 is placed in the collapsing position parallel to the front of the wing 2.

When the operation handle 12 is pulled out and rotated about the pivot shaft 11, and the rotor 13 is rotated in a predetermined direction by the operation handle 12, the relative rotation with respect to the rotor 13 is prevented. (6) linearly moves backward by the screw motion of the male screw part 4 of the slide cam 6, and the female screw part 1 of the fixed body 3. As shown in FIG. Since the passive portion 23 of the lock arm 24 is pressed against the rear end portion 22 of the slide cam 6 by the rearward movement of the slide cam 6, the lock arm 24 is driven by the spring 25. It stands up against the pressurization. In response to the rotation of the rotor 13, the plurality of bearing balls 15 are driven into the annular groove 14 of the fixed body 3 and the annular groove 9 of the rotor 2. The rotation operation can be made lightly with low frictional resistance.

The side portion of the lock arm 24 located at right angles to the axial direction of the fixed body 3 is in contact with the stopper frame portion 33 of the fixed body 3 so that the pressing portion 18 of the lock arm 24 is fixed to the fixed frame 3. By abutting the receiving portion 20 of the sieve 19, the wing 2 is tightened and locked with respect to the fixed frame body 17. At this time, the packing 47 inserted between the rear edge of the wing 22 and the edge of the opening of the fixing frame 17 is compressed.

Wing tightening lock device of the present invention configured as described above, the rotation operation of the rotor 13 relative to the fixed body (3) by the interposition of the bearing ball 15 can be made lightly, the spring 25 Since the lock arm 24 is held in the standby position by the pressurization of, the opening and closing operation of the wing 2 can be made smooth without the lock arm 24 becoming cumbersome.

Moreover, since the rear end surface part 22 of the slide cam 6 which is the drive operation part of the standing arm of the lock arm 24 is comprised by the wall part which closes the back opening of the slide cam 6, it is suitable for abrasion and deformation. It is reinforced, and the durability of the drive operation part of a standing rotation is high. Moreover, since the operation handle 12 was formed in U shape and the dimension between the outer surface of both base ends of the operation handle 12 was matched with the diameter of the front plate part 29 of the fixed body 3, the arm of a rotation moment The length of is to be set as long as possible. Therefore, the rotor has a smaller force than the case in which the pivot axis for connecting the operation handle and the rotor is not on the diameter of the front plate of the fixed body, and the dimension between both ends of the operation handle is shorter than the diameter length of the front plate. (13) can be rotated lightly.

Claims (1)

The female screw part 1 is provided in the inner peripheral surface of the latter half part of the hollow part 7, along the axial direction before and behind, and the annular groove 14 is provided in the inner peripheral surface of the first half part of the hollow part 7, and the wing 2 is provided. A fixed body (3) fixed to it; A male screw 4 is provided on the outer circumferential surface of the proximal end along the front and rear axial directions, and a cavity 5 of a non-circular cross section is provided in the center along the axial direction, and the male screw 4 is attached to the female screw 1. A slide cam 6 which is fastened and inserted into the hollow portion 7 of the fixed body 3; The rear half of the guide shaft portion 8 of the non-circular cross section, which is rotatably fitted into the hollow portion 7 of the fixed body 3, and is inserted into the cavity 5 of the slide cam 6 in a non-rotational manner. Formed in the outer circumferential surface of the middle portion, and the proximal end of the operation handle 12 is connected to the front half portion 10 by a pivot shaft 11 parallel to the front surface of the wing 2. A rotor 13; A plurality of bearing balls are inserted into the annular groove 14 of the fixed body 3 and the annular groove 9 of the rotor 2 so as to prevent the removal of the rotor 13 from the fixed body 3. (15); The proximal end is connected to the fixed main body 3 by a pivot shaft 17 parallel to the front surface of the wing 2, and is fitted into the radially divided groove 16 of the rear end of the fixed main body 3, thereby pressing the tip end portion. The part 18 abuts against the side portion 21 of the slide cam 6 in the state of establishment of the tightening lock in contact with the receiving portion 20 on the side of the fixed frame body 19, while the slide cam ( A lock arm 24 provided with a passive portion 23 abutting at the proximal end thereof, in contact with the rear end face 22 of 6); The passive part 23 is composed of a spring 25 for rotating and pressing the lock cam 24 in a direction that abuts against the slide cam 6, and the rear end portion 22 of the slide cam 6 is moved by the slide cam 6. Consists of a wall portion that closes the rear opening, the operation handle 12 is formed in a U shape, and the dimension between the outer surfaces of both proximal ends of the operation handle 12 is determined by the diameter of the front plate portion 29 of the fixed body 3. Wing lock device for wings characterized in that the length.