FR2654664A1 - Vice, the clamping force of which is limited to a given value, and particularly a ski - Google Patents

Abstract

The present invention relates to a vice including a brace (1), two parallel jaws (5) which are elongate in a longitudinal direction (y, y'), symmetrical with respect to a plane (P) and capable of applying to an object (2) located between the two jaws (5) a clamping force. This vice is characterised in that each one of the jaws (5) is mounted so that it can move about a longitudinal pivot axis (35, 35', 35'', 62-62', 64), and is articulated on a tie rod (3), which can move between two extreme positions, this tie rod (3), as it moves, causing the pivoting of the jaws (5) about the longitudinal pivot axis (35, 35', 35'', 62-62', 64) between two extreme positions, namely an open position in which they are the maximum distance apart, and a closed position in which they are brought as close together as possible.

Description

 The present invention relates to a vice intended to ensure the maintenance of an object and in particular of a ski.

 In order to facilitate the installation on the skis of the various accessories with which they are usually fitted, it is advantageous to secure them, using a vice whose jaws come to bear on the edges of the ski.

 The clamps of conventional type usually used to immobilize parts during machining consist, most of the time, of two jaws, namely a fixed jaw and a movable jaw, which are moved one by relative to the other, using an endless screw, screwed into one of the jaws and secured in translation with the other jaw and free to rotate relative to the latter, which is rotated using a control rod.

 However, because of the reduction provided by the worm, these clamps, in addition to their slow implementation, have the disadvantage of not allowing the user to perceive the clamping force they exert on objects tight, so that, in the case where these are relatively fragile, which is particularly the case of skis, they are likely to cause them deterioration.

 The object of the present invention is a vice which is both quick to set up and whose clamping force on the object is automatically limited to a determined maximum value, possibly adaptable, depending on the object, and insufficient to cause any deterioration thereof.

 To this end, the present invention relates to a vice comprising a frame, two parallel jaws elongated in a longitudinal direction, (y, y ') symmetrical with respect to a plane P, capable of applying to an object arranged between the two jaws a clamping force characterized in that each of the jaws is mounted mobile around a longitudinal pivot axis and is articulated on a tie rod, movable between two extreme positions, this tie rod causing, during its movement, the pivoting of the jaws around the longitudinal pivot axis between two extreme positions, namely an open position in which they are separated as far as possible, and a closed position in which they are brought as close as possible.

An embodiment of the present invention will be described below, by way of non-limiting example, with reference to the attached drawing in which
Figure 1 is a vertical and cross sectional view of a fixing vice according to the invention shown in the open position.

 Figure 2 is a vertical and longitudinal sectional view of the vice of Figure 1 shown in the open position.

 Figure 3 is a horizontal sectional view, parallel to the base plane of the vice, along line III-III of Figure 1 shown in the open position.

 Figure 4 is a detailed perspective view of a crankshaft used in the vice according to the invention.

 Figure 5 is a vertical and cross sectional view of a vice according to the invention shown in the clamping position.

 Figure 6 is a vertical and longitudinal sectional view of a vice according to the invention shown in the clamping position.

 Figure 7 is a perspective view of a jaw and a tie of the vice according to the invention.

 Figure 8 is an enlarged partial view showing the principle of locking the vice in the clamping position.

 Figures 9 and 10 are vertical sectional views, respectively transverse and longitudinal of an alternative embodiment of a jaw of the vice according to the invention.

 Figures 11 and 12 are vertical and transverse sectional views of two alternative embodiments of a jaw of the vice according to the invention.

 Figure 13 is a vertical and cross sectional view of an alternative embodiment of the jaw return means in the open position.

 Figure 14 is a detail view in vertical and transverse section of the joint of a jaw of the vice according to the invention on the body and the tie thereof.

 In FIGS. 1 to 8, the vice according to the invention is symmetrical with respect to a vertical and longitudinal plane P, and it essentially consists of a frame 1, a tie rod 3 and two jaws 5.

The frame 1 consists of a horizontal base 7, on which are fixed two lateral flanks 9.9 ′ parallel to the plane P. The internal faces of each of these lateral flanks 9.9 ′ have vertical guide grooves 11, arranged symmetrically with respect to the plane P. The tie rod 3 consists of an essentially planar element, arranged transversely along a plane Q, perpendicular to the plane
P, between the two lateral flanks 9.9 ′ and mounted vertically sliding therebetween. I1 is provided at the upper part and at the lower part of each of its vertical edges, with a stud 12, these studs 12 being adjusted in the grooves 11 so as to guide the tie rod 3 during its sliding movement two return springs 15, made up of helical compression springs, are arranged, between the base of the tie rod 3 and the base 7, in respective bowls 17 and 19 provided in the tie rod 3 and in the base 7. These springs, of low stiffness, have the object of bringing the tie rod 3 in the high position, that is to say in the position in which the upper pins 12 are in contact with the upper ends of the grooves 11, when no antagonistic action is 'exercises on the tie rod 3.

 The lower central part of the tie rod 3 is hollowed out of a housing 20, of cross section in the form of an isosceles trapezoid, the small upper base 22 of which is extended downwards by a cylindrical column 24, which extends vertically towards the base 7 and ends with a lower head 26. The column 24 is pierced right through with a vertical light 27 parallel to the plane P and which is crossed by a lever 30. This lever 30r of rectangular cross section is articulated, at one of its ends, around a horizontal and transverse axis 31, on a vertical support 32 forming a support and fixed on the base 7 of the frame 1.

 A crankshaft 40 consists of two extreme cylindrical journals 40a and 40b, aligned along a transverse axis zz ', and of a central crank pin 40c, eccentric with respect to the journals 40a and 40b, parallel to these, and the ends of which are respectively connected to the pins 40a and 40b by two radial arms 40d. The pins 40a and 40b of this crankshaft 40 respectively take place in coaxial housings 42, of corresponding shape, provided in the lateral flanks 9,9 '. The pin 40a has two circular grooves 41,41 'located on either side of the lateral flank 9, when the crankshaft is in place, and these grooves 41,41' receive two elastic split washers 43,43 'ensuring the maintenance in translation of the crankshaft 40 relative to the frame 1.

The crankshaft 40, once its two pins 40a and 40b engaged in the housings 42 of the sides 9, 9 ′, is therefore mobile in rotation about the transverse axis zz ′, between two extreme positions in which it comes into contact with the tie 3, namely an upper position A (Figure 2) and a lower position B. (Figure 6)
A helical compression spring 45 is disposed between the lower head 26 of the column 24 and the lower edge of the lever 30, on which it comes to rest, with the interposition of a rigid washer 34. This compression spring thus applies the lever 30 against the central crank pin 40c of the crankshaft 40.

 The journal 40b of the crankshaft 40 protrudes from the lateral flank 9 by a length sufficient to receive a sleeve 47 of which it is made integral in rotation and in translation by means of a radial screw 49 screwed into the sleeve 47. A control lever 51 is screwed into the sleeve 47 and makes it possible to control the rotation of the crankshaft 40 between its high position A and its low position B.

 It will be noted that in the positions A and B corresponding respectively to the high and low position of the lever 30, the crankshaft 40 is in the stable position. Indeed, in position A (high position) the central crank pin 40c is applied against the upper part of the tie rod 3 by the spring 45. On the other hand in position B (low position) the axis zz 'of rotation of the crankshaft 40 is positioned such that. when the central crank pin 40c of the crankshaft 40 is in contact with the cylindrical column 24, and as shown in FIG. 8, the point of contact M between the central crank pin 40c and the lever 30 is situated on the side of the column 24 relative to the height OH lowered from the axis zz 'on the lever 30. Thus the vertical force applied to the lever 30 by the spring 45 tends to apply the crank pin 40c of the crankshaft 40 against the cylindrical column 24.

 The jaws 5 consist of two identical elements, elongated in the longitudinal direction yy ′, of the same length as the lateral flanks 9.9 ′ and they each comprise a base face 23, connected to an internal face 25 parallel to the plane P, by a rib 27 projecting towards the plane P and downwards.

 Each of the ribs 27 is hollowed out with a median recess 31, of length equal to the thickness of the upper part of the tie rod 3, so as to allow the jaws 5 to be fitted thereon. In addition, the ribs 27 and the tie rod 3 are crossed by respective coaxial longitudinal holes 28 and 29, receiving a pin 21 constituting a longitudinal articulation axis around which each of the jaws 5 can pivot relative to the tie rod 3.

 The base face 23 of each jaw is hollowed out with a longitudinal groove 33, of rectangular section, opening downwards, in which is embedded a cylindrical steel bar 35, of circular section, the diameter of which is greater that the depth of the groove, so that each jaw 5 is supported on the upper edge of a lateral flank 9.9 ′, by means of the bar 35.

 The internal face 25 of each jaw is hollowed out at its upper part, over its entire length, with a longitudinal groove 36, in which is embedded a jaw 37 consisting of an elastomer with a high coefficient of friction.

 A plate 50, covered with a coating 52, with a high coefficient of friction, is fixed on the upper part of the tie rod 3.

In the open position, that is to say in the position shown in Figure 1, the return springs 15 push up the tie rod 3, applying the upper guide pins 12 against the upper ends of the vertical grooves 11. In this position the base face 23 of each jaw 5 is substantially horizontal, and the jaws 5 are in the position of maximum separation. On the other hand, in this position, the spring 45, the lower end of which takes support on the lower head 26 of the column 24, push up the lever 30, by applying it against the central crank pin 40c of the crankshaft 40, the latter coming into contact with the upper part of the tie rod 3. (position A in figure 2 )
To clamp a ski 2 in the vice, it is placed horizontally between the jaws 5 of the vice so that its lower face comes into contact with the coating 52 of the plate 50 disposed on the upper face of the tie rod 3, then we make pivot the control lever 51, in the direction of the arrow F (FIG. 6), so as to rotate the crankshaft 40 clockwise and push back, with the central crank pin 40c, the lever 30, to bring it into the lowered position B (FIG. 6). The lever 30 then exerts, by means of the compression spring 45, a vertical force directed downwards on the head 26 of the column 24 of the tie rod 3. That -this therefore moves downward, first compressing only the return springs 15, of much lower stiffness than that of the spring 45. During this movement the tie rod 3 drives the pins 21 downwards on which the jaws 5 are articulated. The latter therefore pivot around the bars 35, bearing on the upper edges of the lateral flanks 9.9 ′, and the jaws 5 therefore undergo a transverse movement bringing them closer to one another. When the two jaws 5 come into contact with the edges of the ski 2, any additional displacement of the tie rod 3 downwards has the effect of compressing the spring 45, and the compression thereof increases until the central crank pin 40c of the crankshaft 40 is in its position B the lowest.

 The travel of the tie rod 3 is always the same and the tightening force depends on the stiffness of the spring 45 and on the quantity of which it is compressed during the tightening operation, the latter value depending on the width of the ski. In fact, the greater this is, the earlier, during the tightening movement, the jaws 5 come into contact with the ski 2, and the greater the compressed length of the spring 45. The maximum transverse compression force is thus obtained for a ski 2 of width substantially identical to the spacing of the jaws 5 in the open position, since in such an arrangement the spring 45 is compressed from the start of tightening, which corresponds to a length Maximum compressed. Such a transverse tightening value is therefore predeterminable since, for a given spring, it only depends on the width of the ski. It is thus possible, as a function of the compression resistance of the ski to be tightened, to use a spring of suitable stiffness capable of providing a maximum compressive force lying below the resistance of the ski.

 As shown in FIGS. 9 and 10, each of the longitudinal cylindrical bars 35, serving as an axis of articulation for the jaws 5 on the frame 1, can be replaced by two pins 62 force-fitted into housings perpendicular to the base face 23 , jaws 5 and which bear on the upper edge of a lateral flank 9.9 ′.

 It is also possible and as shown in FIG. 11, to dig the longitudinal grooves in the upper fields of the side elements 9, 9 ′, these grooves receiving cylindrical bars 35 ′ of steel. As shown in FIG. 12, it is also possible to machine longitudinal support stops 35 "of semi-cylindrical section in the upper fields of the lateral flanks 9,9 ′.

 Finally, as shown in FIG. 13, the return means in the open position of each of the jaws 5 can consist of a torsion spring 15 ′ disposed around the articulation axis 21 of a jaw 5 on the tie rod 3, the ends of which respectively bear on the tie rod 3 and on the jaw 5.

 Of course the jaws 5 can be pivotally mounted around a longitudinal spindle 64 fixed at its two ends on the frame of the vice, the hinge pin 21 of the tie rod 3 with the jaws 5 being able to then move during the jaw closing movement 5 in a horizontally elongated opening 66 produced in the tie rod 3.

Claims (21)

 1.- Vice comprising a frame (1), two parallel jaws (5) elongated in a longitudinal direction (y, y '), symmetrical with respect to a plane (P), suitable for applying to an object (2) disposed between the two jaws (5) a clamping force characterized in that each of the jaws (5) is mounted movable about a longitudinal pivot axis (35.35 ', 35 ", 62-62', 64), and is articulated on a tie rod (3), movable between two extreme positions, this tie rod (3) causing, during its movement, the pivoting of the jaws (5) around the longitudinal pivot axis (35,35'35 ", 62-62 ', 64) between two extreme positions, namely an open position in which they are spread as far as possible, and a closed position in which they are as close as possible.  2.- vice according to claim 1 characterized in that the pivot axis of each jaw (5) relative to the frame (1) is constituted by at least two contact points existing between each of the jaws (5) and an element (9,9 ') fixed relative to the frame (1).  3.- vice according to claim 2 characterized in that it comprises at least one intermediate element (35.35 ', 35 ", 62-62') disposed between each jaw (5) and the element (9.9 ' ) fixed relative to the frame (1).  4. A vice according to claim 3 characterized in that this intermediate element is integral with the jaw (5).  5. A vice according to claim 3 characterized in that this intermediate element (35 ") is integral with the element (9,9 ') fixed relative to the frame (1).  6. A vice according to claim 3 characterized in that the intermediate element consists of a longitudinal cylindrical bar, embedded in a housing of the jaw (5), and in contact by one of its generatrix with the element (9, 9 ') fixed relative to the frame (1).  7. A vice according to claim 4 characterized in that each of the jaws (5) comprises, at substantially each of its ends, a stud (62.62 ') in contact with the element (9.9') fixed relative to to the frame (1).  8. A vice according to claim 1 characterized in that each jaw (5) is articulated on the tie rod (3) by means of a longitudinal pin (21).  9. A vice according to claim 1 characterized in that the tie rod (3) moves in a plane (Q) perpendicular to the plane of symmetry (P) and to the longitudinal direction (y, y ') of the jaws (5), between two lateral sides (9,9 ') parallel to the plane of symmetry (P) and fixed with respect to the frame (1).  10. A vice according to claim 9 characterized in that the frame (1) and the tie rod (3) are provided with complementary means intended to guide the tie rod (3) during its movement.  11. A vice according to claim 10 characterized in that the lateral flanks (9,9 ') of the frame (1) and the walls of the tie rod (3) facing these flanks are respectively provided with a groove (11) and two guide pins (12).  12 -.- Vice according to claim 1 characterized in that the tie rod (3) is provided with elastic return means (15,15 ') urging it to a position in which the jaws (5) are in the open position.  13. A vice according to claim 12 characterized in that the elastic return means consist of at least one compression spring (15), one end of which bears on the frame (1) and the other end on the tie rod (3).  14.- Vice according to claim 12 characterized in that the elastic return means consist of at least one torsion spring (15 ') coaxial with a hinge pin (21) of the tie rod (3) on the jaw (5), and whose ends are respectively supported on the tie rod (3) and the jaw (5).  15. A vice according to claim 1 characterized in that the movement of the tie rod (3) is controlled by a lever (30) one end of which is articulated on a support (32) integral with the frame (1) and the other end of which is supported on the tie rod (3) by means of an elastic means (45).  16. A vice according to claim 15 characterized in that the lever (30) passes through a light (27) provided in a column (24) integral with the tie rod (3).  17. A vice according to claim 16 characterized in that the elastic means are arranged between the base of the lever (30) and a head (26) provided at the lower end of the column (24).  18. A vice according to claim 17 characterized in that the elastic means consist of a compression spring (45), threaded on the column (24).  19. A vice according to claim 15 characterized in that the lever (30) is actuated by a control member (40) capable of occupying two extreme positions in which it is locked, namely a position (A) in which the jaws (5) are in the open position, and a position (B) in which the jaws (5) are in the closed position.  20.- Vice according to claim 19 characterized in that the control member is a crankshaft (40), consisting of two extreme coaxial journals (40a-40b) along an axis (zz ') perpendicular to the plane of symmetry (P) , these pins being rotatably mounted about the axis (zz ') in housings (42) provided in the lateral flanks (9,9'), and a central crank pin (40c), parallel to the axis (zz '), against which is applied the edge of the lever (30) opposite the elastic means (45), under the action of the latter.  21. A vice according to claim 20 characterized in that the crankshaft is capable of occupying two extreme positions, namely a high position (A), in which its central crank pin (40c) is in abutment against the upper part of the tie rod (3) and the jaws (5) are in the open position, and a low position (B) in which its central crank pin (40c) is in abutment against the column (24), and the contact point (M) of the central crank pin (40c) with the lever (30) is located between the column (24) and the base (H) of a lowered perpendicular straight line (OH), from the axis of rotation (zz ') of the crankshaft (40), on the lever (30).