EP0706442A1

EP0706442A1 - Tightening tool such as a screwdriver

Info

Publication number: EP0706442A1
Application number: EP95918039A
Authority: EP
Inventors: Hervé Gilbert GOMAS
Original assignee: Facom SA
Current assignee: Facom SA
Priority date: 1994-04-20
Filing date: 1995-04-20
Publication date: 1996-04-17
Anticipated expiration: 2015-04-20
Also published as: FR2718991A1; DE69503453T2; DE69503453D1; US5816119A; EP0706442B1; FR2718991B1; WO1995029041A1

Abstract

Tightening tool comprising a driving part (4) forming the grip of the tool handle and a driven part (5) which includes a blade holder and the complementary distal part of the handle. The driving part and driven part have, in a first position of use, a common axis of rotation (X-X') and means (18, 19) for tilting the driving part (4) in relation to the driven part (5), comprising at least one tranverse pin secured to one of the two parts and movable in a longitudinal groove of the other part provided with a stop. Locking means (11, 26, 12, 29) are provided which adopt a positive locking position of the driving part (4) in a coaxial position relative to the driven part (5) by interlocking of both parts. Said parts can also adopt a position in which the tilting means (18, 19) are released through coaxial shifting of one part in relation to the other up to a predetermined spaced-apart position.

Description

Clamping tool, especially screwdriver.

The present invention relates to a clamping tool of the type comprising a driving part and a driven part which have, in a first position of use, a common axis of rotation, means for tilting the driving part relative to the driven part, and locking means which can assume a positive locking position of the driving part in a position coaxial with the driven part as well as a position of release of the tilting means. It applies in particular to screwdrivers.

In a known screwdriver of this type (FR-A-2570975), the. _ie driving forms the entire handle, and the driven part is formed by the blade of the screwdriver. To allow tilting, the handle has a longitudinal slot, which seriously affects the comfort of gripping the handle in said first position of use.

The object of the invention is to provide economical and reliable means making it possible to exert on a part either a relatively low torque, or a much higher torque, by having a tool identical to the conventional tools in the first. position of use. In particular, in the case of a screwdriver, it is a question of making it possible to carry out a rapid screwing followed by an energetic tightening at the end of screwing, or else a release of a screw followed by a rapid unscrewing.

To this end, the invention relates to a clamping tool of the aforementioned type, characterized in that:

- The driving part comprises a proximal part, forming a handle, of the handle of the tool; - the driven part includes a blade holder

The tool and the complementary distal part of the handle of this tool;

- the two parts are mounted coaxially mobile- ment relative to each other to a predetermined remote position to release the tilting means;

- The tilting means comprise at least one transverse pin secured to one of the two parts and movable in a longitudinal groove of the other part provided with a stop; and the locking means comprise an interlocking between the driving part and the driven part. The clamping tool according to the invention may include one or more of the following characteristics:

- In the locking position of the locking means, the driving and driven parts are in mutual contact by their respective end edges;

- The longitudinal groove is carried by the male part of the socket and the transverse axis is integral with the female part of the socket;

- the transverse pin is close to the end of the part which carries it;

- the nesting includes a mutual guiding of the two parts by a non-circular shape;

- In said predetermined distance position, the two parts cooperate by plane surfaces parallel to a predetermined tilting plane; the tool comprises braking means, in particular a rod, adapted to increase the friction between the two driving and driven parts during their coaxial movements; - Said proximal part of the handle forms a handle having an external shape of revolution;

- The blade holder includes an auxiliary torque transmission device, in particular a pawl; and - The blade passes through said auxiliary device and abuts against the blade holder above this device.

An exemplary embodiment of the invention will now be described with reference to the appended drawings, in which:

- Figure 1 is a longitudinal section of a screwdriver according to the invention, in the locked position of the tilting mechanism;

- Figure 2 is a similar view of the screwdriver of Figure 1, in the unlocked position of the tilting mechanism;

- Figure 3 is a partial elevational view of the tilting mechanism;

- Figures 4 and 5 are cross-sectional views taken respectively along lines IV-IV and V-V of Figure 3;

- Figure 6 shows the screwdriver in the unlocked position of the tilting mechanism ^e t, with the handle being tilted, the view being taken along arrow VI of Figure 2; and

- Figure 7 shows in longitudinal section, on a larger scale, part of a variant.

Referring to Figures 1 to 6, the tightening tool is described by being applied to a screwdriver 1. This screwdriver 1 consists of a handle 2 carrying a blade 3 and has, in its normal position of use, a general axis XX 'assumed to be vertical.

The handle 2 of the screwdriver 1 is divided into a driving part or handle 4 and a driven part or blade holder 5.

The handle 4 consists of an outer casing 6 of revolution around the axis XX ', of a shape adapted to be easily gripped by an operator. This envelope 6, for example made of plastic, has an elongated shape and has two end, upper 7 and lower 8 edges, flat and horizontal. This envelope 6 surrounds a cylindrical core 9 of axis XX ′, for example of steel, the upper end 10 of which is flush with the end 7 of the envelope 6 and of which a lower part 11 projects under the end 8 of this envelope.

On a lower section of the order of a third of its length, the core 9 has a blind axial bore 12 with hexagon as shown in FIG. 4. This bore 12 penetrates clearly into the casing 6 and opens downward.

FIG. 5 shows that the projecting lower part 11 of the core 9 is split along the diameter of the bore 12, so as to form two legs 13 and 14 diametrically opposite and symmetrical with respect to the axis XX ′. These legs are delimited internally by respective flat and parallel surfaces 15, 16 forming part of the above-mentioned hexagon.

Near the free end of the legs 13,14 is pierced in them a through bore 17, horizontal and perpendicular to the surfaces 15 and 16 and of a small diameter compared to that of the bore 12. Inside from this bore 17 are fixed two lugs 18 and 19, affleu¬ rant the outer surface of the legs 13 and 14 respectively¬ ment and slightly projecting internally relative to the surfaces 15 and 16.

The upper end 7 of the casing 6 carries a plug 20 in a spherical cap having a base diameter equal to that of this end 7. This plug 20 is fixed by a cylindrical finger 21 inserted in a blind bore 22 of axis X -X ', formed in the core 9, the bore 22 being of a depth slightly greater than the length of the finger 21.

The blade holder 5 consists of a body 23, for example made of plastic, externally frustoconical and slightly converging downwards, having two planar and horizontal ends at the upper end 24 and lower end 25. This body 23 is crossed along the axis XX ' by a bore having two successive diameter reductions. The bore section 26 having the largest diameter extends over approximately half the height of the body 23 from the upper end 24 thereof, so as to be slightly deeper than the length of the part lower 11 projecting from the core 9. The diameter of the section 26 is equal to the outside diameter of this core. The intermediate bore section 27 has a hexagonal section identical to that of bore 12, and the second reduction in diameter defines a horizontal shoulder 28 near the lower end 25 of the body 23.

A shaft 29 of axis XX ′, for example of steel, with a hexagon cross-section conjugate with the section 27 and the bore 12, is inserted by force from above into the body 23 until it abuts on the 'shoulder 28. An upper section 30 of this shaft 29 protrudes above the upper end 24 of the body 23.

Two diametrically opposite longitudinal grooves 31 and 32 extend upwards along the shaft 29, substantially from the bottom of the bore section 26, without opening upwards. The depth of these grooves allows the insertion of the projecting ends of the lugs 18 and 19 inside the grooves 31 and 32, with the surfaces 15 and 16 of the legs 13 and 14 in contact with two opposite sides of the shaft 29 .

At the end of the upper section 30 of the shaft 29, above the grooves 31 and 32, a circular elastic ring 33 radially elastic is received in a peripheral groove of the shaft 29, so as to increase the friction between this shaft 29 and the adjacent surfaces of the bore 12 and the legs 13, 14.

Over the major part of the length of the shaft 29 extends a blind bore 34. This bore opens out on the lower end of the latter and has a diameter slightly less than that of the lower section of the body 23. The blade 3 of screwdriver is inserted with friction by the down inside this bore 34 and abuts against the bottom thereof.

The operation of the screwdriver 1 is now explained with reference to FIGS. 1, 2 and 6. To start a screwing operation, the screwdriver is used as the usual screwdriver, in the configuration of FIG. 1. The handle 4 is then vertical to the blade holder 5 while being ver¬ rusted therein against any tilting. More specifically, the lower part 11 of the handle 4 is fitted into the bore section 26 of the blade holder 5, while the upper part 30 of the shaft 29 is inserted into the bore 12. This locking can be qualified "positive" because it remains when the user exerts a screwing / unscrewing couple and / or a push down and / or a lever force in any radial plane, that is to say for any habitual action exerted when using a conventional screwdriver.

In this situation, the crowns defined by the surfaces 8 and 24 are in mutual contact, and the external surfaces of the parts 4 and 5 are connected exactly, so that the assembly 6, 20, 23 has the appearance of a handle. classic screwdriver, without protruding element.

To carry out most of the screwing, the handle 4 rotates the blade holder 5 by virtue of the hexagonal shape of the bore 12 and of the shaft 29 and possibly by the cooperation of the pins 18 and 19 and grooves 31 and 32.

It is noted that, in this position, if one strikes the top of the handle, the shock is transmitted directly to the blade holder 5 via the contact surfaces 8 and 24, without risking damaging the internal tilting mechanism.

After the operator has made a coarse tightening, he wants to exert a high torque on the screw. For this, the handle 4 is then unlocked, keeping the blade holder 5 fixed and pulling upwards the handle 4. The pins 18 and 19 slide in the grooves 31 and 32 until they come into abutment at the upper end of these. The upper part of the shaft 29 then being entirely between the legs 13 and 14, the handle 4 can be tilted around the horizontal axis YY 'defined by the pins 18 and 19, as shown in Figure 6. This part 4 thus constitutes a lever arm, and it is easy to exert a high torque on the screw, transmitted to the blade holder 5 via the surfaces 15 and 16. It should be noted that, as the legs 13 and 14 are very short at beyond the pins 18 and 19, they do not protrude relative to the blade holder 5 and therefore do not increase the size of the tool when the handle 4 is tilted. In addition, the handle does not risk tipping unexpectedly during use in the "normal" position.

FIG. 7 represents a variant of blade holder 5 in which a reversible pawl 35 is incorporated. This pawl has a conventional general structure, with a stator constituted by the body 23, a rotor 36 which has a flat vertical surface 37 extending along a cord, a movable corner 38, a spring 39 for biasing this corner towards one end or the other of the surface 37, and a selection ring 40 which internally carries a lug 41 for engaging the spring. The ring 40 is rotatably mounted at the lower end of the body 23 by means of a circular elastic ring 42, and its rotation in one direction or the other defines the active direction of the pawl.

In this variant, the shaft 29 of FIGS. 1 and 2 has come integrally with the body 23. The blade 3 (which, in the example shown, is reversible) freely crosses a central orifice of the ring 40, then crosses at friction between the rotor 36 and the shaft 29, until it stops at the bottom of the bore 34 of this shaft. Thanks to this arrangement, when the screwdriver is mounted and is in its normal position similar to that of FIG. 1, a vertical shock exerted on the the handle of the screwdriver is transmitted directly to the blade 3, without in any way affecting the pawl 35.

Claims

1. Clamping tool, in particular a screwdriver, of the type comprising a driving part (4) and a driven part (5) which have in a first position of use a common axis of rotation (XX '), means (18, 19 ) tilting of the driving part (4) relative to the driven part (5), and locking means (11, 26,

12, 29) able to assume a positive locking position of the driving part (4) in a position coaxial with the driven part (5) as well as a position for releasing the tilting means (18, 19), characterized in that:

- the driving part (4) comprises a proximal part, forming a handle, of the handle (2) of the tool;

- The driven part (5) comprises a blade holder for the tool and the complementary distal part of the handle of this tool;

- The two parts (4, 5) are mounted movable coaxially with respect to each other to a predetermined remote position to release the means (18, 19) for tilting;

- The tilting means (18, 19) comprise at least one transverse spindle (18) integral with one of the two parts and movable in a longitudinal groove (31, 32) of the other part provided with a stop; and - the locking means (11, 26, 12, 29) comprise an interlocking between the driving part (4) and the driven part (5).

2. Clamping tool according to claim 1, characterized in that, in the locking position of the locking means (11, 26, 12, 29), the driving (4) and driven (5) parts are in mutual contact by their respective end edges (8, 24).

3. Clamping tool according to claim 1 or 2, characterized in that the longitudinal groove (31, 32) is carried by the male part of the socket and the transverse axis (18) is integral with the female part of 1 'nesting.

4. Clamping tool according to any one of claims 1 to 3, characterized in that the transverse pin (18) is close to the end of the part (4) which carries it. 5. Clamping tool according to any one of claims 1 to 4, characterized in that the fitting comprises a mutual guide of the two parts (4,

5) by a non-circular shape.

6. Clamping tool according to any one of claims 1 to 5, characterized in that, in said predetermined remote position, the two parts (4, 5) cooperate by planar surfaces (15, 16) parallel to a predetermined tilting plan.

7. Clamping tool according to 1 * any one of claims 1 to 6, characterized in that it comprises braking means, in particular a rod (33), adapted to increase the friction between the two driving (4) and driven parts (5) during their coaxial displacements.

8. Clamping tool according to any one of claims 1 to 7, characterized in that said proximal part (4) of the handle forms a handle having an outer shape of revolution.

9. Clamping tool according to any one of claims 1 to 8, characterized in that the blade holder (5) comprises an auxiliary device (35) for transmitting torque, in particular a pawl.

10. Clamping tool according to claim 9, characterized in that the blade (3) passes through said auxiliary device (35) and abuts against the blade holder (5) above this device.