KR860003149Y1 - Friction press - Google Patents

Abstract

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Description

Friction press

1 is an overall front view of a friction press.

2 is an enlarged cross-sectional view of the main part.

3 is an overall front view corresponding to FIG. 1 showing another example of the slide.

4 is an enlarged cross-sectional view of an essential part corresponding to FIG. 2 showing another example of the vertical screw shaft portion.

* Explanation of symbols for main parts of the drawings

3: slide 6: vertical screw shaft

8: fly wheel 9,10: friction car

23,24: upper and lower cylinder

The present invention relates to an improvement of a friction press.

Background Art Conventionally, various types of friction presses are known, such as disc driven friction presses, roll driven friction presses, Häzenclaver type friction presses and Vincent type friction presses.

The problem common to these was that the rotational force due to friction was not reliably transmitted from the friction wheel to the flywheel.

An object of the present invention is to provide a structure of a friction press with increased pressing force by reliably transmitting rotational force from a friction wheel to a fly wheel.

In order to achieve the above object, the present invention raises and lowers a slide by a screw drive mechanism, and the friction screw press rotates the vertical screw shaft by energy such as rotation of a flywheel installed on an upper portion of the vertical screw shaft of the screw drive mechanism. Thus, the frictional material of the rotational material with respect to the vertical screw shaft and the vertically moving material in the axial direction is provided coaxially with the upper and lower portions of the flywheel, and means for relatively pressing the flywheel and the frictional difference are provided. It is.

Hereinafter, the present invention will be described in detail by the embodiments shown in the drawings.

In FIG. 1, the friction press 1 which concerns on this invention is shown.

(2) is the frame, (3) is the slide guided by the upper and lower guides (4) and (5).

(6) is a screw shaft supported by a rotating material by a bearing (not shown in the frame 2), and a nut member (7) screwed on the screw shaft (6) is provided on the slide head.

The upper portion of the screw shaft 6 is projected upward by the frame 2.

(8) is a fly wheel, (9) and (10) are upper and lower frictional differences arranged coaxially on the upper and lower sides of the flywheel 8, and these are provided in the protruding upper end part 6a of the screw shaft 6. As shown in FIG.

(11) and (12) are the motors for driving the upper and lower friction differences (9) and (10), respectively, and (13) and (14) are the V pulleys (15) and (16) are the transmission V belts.

Next, details of the upper and lower frictional differences 9 (10) and the attachment portion of the fly wheel (8) will be described with reference to FIG.

In FIG. 2, the upper end part 6a of the screw shaft 6 is connected to the taper shaft part 16 and its upper part, and the screw shaft part 17 is provided. The plae wheel 8 has a taper ball 18 having a size fitted to the tapered shaft portion 16 at the center thereof, and annular friction plates 19 and 19 'are attached to the periphery at both the upper and lower sides.

Reference numeral 20 is a fixing nut screwed to the screw shaft portion 17.

The upper and lower friction differentials 9 and 10 are spaced slightly above and below the flywheel 8 so that the protruding upper end portion 2a of the screw shaft 2 can be moved up and down like the bearings 21 and 22. It is.

Reference numeral 23 denotes an upper cylinder which is a piezoelectric means for pressing the upper friction difference 9 to the upper surface of the fly wheel 8.

Reference numeral 24 denotes a lower cylinder serving as piezoelectric means for pressing the lower friction difference 10 against the lower surface of the fly wheel 8.

Reference numeral 25 is a return spring of the upper cylinder 23.

Reference numeral 26 denotes an annular friction plate provided on the lower surface of the upper friction wheel 9, and 27 an annular friction plate provided on the lower friction wheel 10 and the upper surface. Next, the operation of the friction press according to the present invention will be described. The driving motors 11 and 12 are rotating in opposite directions, respectively, and the upper and lower friction differentials 9 and 10 are opposite to each other via the pulleys 13 and 14 and the V-belt 15 and 16, respectively. It is supposed to rotate. At this time, the upper and lower friction differences (9) and (10) are separated from the fly wheel (8), and the screw shaft (6) does not rotate. Then, when the upper cylinder 23 is operated, the upper friction difference 9 is lowered and pressed into the flywheel 8, the screw shaft 6 is rotated in a predetermined direction, the slide is lowered. After the operation of the upper cylinder 23 is finished, the upper friction difference 9 is raised to its original position by the feedback spring 25.

Next, when the lower cylinder 24 operates, the lower friction difference 10 rises and presses on the flywheel 8, and the screw shaft 6 rotates in the opposite direction to the above, and the slide raises. After the operation of the lower cylinder 24 is finished, the lower friction difference 10 is lowered to its original position by its own weight. Moreover, in the friction press of the Example, although the upper friction difference 9 and the lower friction difference 10 were provided above and below the flywheel 8, it may be one of the upper and lower sides, without being particular about this.

In this case, the driving motor is inverted at predetermined time intervals, and synchronized with this to press-contact and space the friction difference to the flywheel. The slide 3 is used not only to press work when the slide is raised, as in the friction press of FIG. 1, but also to a friction press that performs press work when the slide is lowered, as shown in FIG. As shown in the figure, the screw shaft 6 itself can be lifted and the slide 3 can be attached to the lower end thereof.

In the present invention, the slide 3 is moved up and down by the screw drive mechanism as described above, and the vertical screw shaft is driven by energy such as rotation of the flywheel 8 provided on the upper part of the vertical screw shaft 6 of the screw drive mechanism. In the friction press in which (6) is rotated, the friction difference (9) (10) of the rotational material with respect to the vertical screw shaft (6) and the vertical movement material in the axial direction is above the flywheel (8) and Or it is provided coaxially with this below and the means 23 and 24 which contact the flywheel 8 and the friction difference 9, 10 relatively are provided, and therefore, it is fly from the friction difference 9 Energy, such as rotation, can be reliably transmitted to the wheel 8 without slipping, and a high performance press can be provided.

Claims (1)

The slide 3 is lifted and lowered by the screw drive mechanism, and the vertical screw shaft 6 is rotated by energy such as rotation of the flywheel 8 provided above the vertical screw shaft 6 of the screw drive mechanism. In the friction press, the friction difference 9, 10 of the material which is rotated with respect to the vertical screw shaft 6 and the vertical motion material in the axial direction is coaxially with this above and below the flywheel 8. And a means (23) (24) which is provided to relatively contact the fly wheel (8) with the friction difference (9) (10).