SU1588537A1 - Wood screw driver - Google Patents

Abstract

This invention relates to a handheld mechanized tool. The purpose of the invention is to reduce the level of vibration and increase reliability by changing the kinematic connection of the anvil with the spindle. When turning on the screwdriver drive, the rotation of the output shaft 2 together with the drummer 3 is transmitted through the bevelled end cams 4 through the response bevel end cams 11 of the anvil 10. Then the screwdriver is mounted on the screw or screw to be tightened and move the body 1 towards the spindle 5. At the same time the end rectangular cams 6 engage with the rectangular cams 12 of the anvil 10 and the screwing process is carried out. When the moment reaches the limit, the spindle 5 together with the anvil 10 stops, and the rotating drummer 3, interacting with the beveled butt cams 4 with the beveled butt end cams 11 of the anvil 10, presses the latter in axial direction, compressing the spring 9. 1 zp f-ly, 1 ill.

Description

The invention relates to a hand-held mechanized tool and can be used in various industries during locksmithing, installation and finishing works.

The purpose of the invention is to reduce the level of vibration and increase reliability by changing the kinematic connection of the anvil with the spindle.

The drawing schematically shows the proposed screwdriver, a longitudinal section.

The screwdriver comprises a housing 1, a drive (not shown) placed in it with an output shaft 2, mounted on the last hammer 3 with beveled end cams 4, a spindle 5 with rectangular end cams 6 located in the middle part, and a cylindrical shank 7, spring-loaded in axial the direction of the spring 8, and covering the shank 7 of the spindle 5 and axially spring-loaded towards the hammer 3 by the spring 9 with the anvil 10 with mating end cams 11 located on one end to interact with the beveled end cams 4 of the hammer 3, and on the other end, rectangular cams 12 for interaction with rectangular end cams 6 of the spindle 5. The height of the rectangular cams 6 and 7 of the spindle 5 and the anvil 10 is greater than the height of the beveled end cams 4 and I of the hammer 3 and the anvil 10, respectively .

On the cylindrical surface of the spindle 5, protruding from the housing 1, an abutment 13 is fixed for interaction with the housing 1. Between the ends of the hammer 3 and the anvil 10 are antifriction 14 and 15 and elastically damping 16 elements. A central hole 17 is made in the output shaft 2. A finger 18 is fixed in the anvil 10, the end of which is rotatably placed in the central hole 17 of the output shaft 2. A sleeve 19 is placed in the housing 1 to interact with the free end of the spring 9. The sleeve 19 is fixed by a screw 20.

The screwdriver works as follows.

When the screwdriver is turned on, the output shaft 2 with the hammer 3 through the chamfered end cams 4, which engage with the mating chamfer end cams 11, rotates the anvil 10. The operator presses the housing 1 in the axial direction, while moving the spindle 5 until the contact of the stop 13 with the housing 1 , while the spindle 5 compresses the spring 8, and its end rectangular cams 6 engage with the rectangular cams 12 of the anvil 10 and the process of screw tightening (not shown) begins until the tightening torque is reached, by which spring 9 is guided, after which the anvil stops and the hammer 3 continues to rotate, while its beveled end cams 4, interacting with the reciprocal beveled end cams of the anvil 10, squeeze the latter together with the anvil 10 in the axial direction, compressing the spring 9. At this moment, the rectangular the cams 12 move along the end rectangular cams 6 of the spindle 5. When the end of the beveled cams 11 of the anvil 10 meet the end of the beveled cams 4 of the hammer 3 under the action of the spring 9, the anvil 10 returns one position at a higher speed and strikes the elastic-damping element 16, anti-friction elements 14 and 15, while the elastic-damping element 16 absorbs the impact energy. With further rotation of the striker 3 until the interaction of its mechanical end bevel cams 4 with the reciprocal beveled end cams 11 of the anvil 10, the antifriction elements 14 and 15 work as a thrust bearing. Then, the process of squeezing the anvil 10 from the hammer 3 is repeated in the indicated sequence until the operator removes the axial load from the housing 1. After this, the screwdriver is removed from the screw or screw and transferred to the next screw or screw to be screwed.

Claims (2)

Claim 1. Screwdriver, comprising a housing, a drive with an output shaft, an axially spring-loaded spindle with rectangular face cams in the middle part and a cylindrical shank, a hammer with oblique butt-shaped jaws on the output shaft and covering the spindle shank and axially axially in the axle direction the side of the striker anvil with the response oblique face cams, characterized in that, in order to reduce vibration and increase reliability, straight anvil is made at the free end of the anvil mountable cams for periodic interaction with rectangular spindle cams, the height of rectangular spindle and anvil cams is greater than the height of the bevel cams, and the screwdriver is provided with an abutment fixed to the cylindrical spindle surface protruding from the body to interact with the body. 2. Screwdriver on π. 1, characterized in that it is provided with antifriction and elastic-damping elements placed between the drummer and the anvil.