FR2912338A1 - VIBRATING CUTTING DEVICE - Google Patents

Abstract

The tool has an elongated cutting blade (102) fixed to a bar (100) by a transition zone (101). The blade includes a longitudinal cutting edge (103), and defines a longitudinal cutting plane perpendicular to a cross-section plane of the bar. A notch (104) is formed in a part in the blade's cutting edge. A notch (105) is formed in a longitudinal edge (106) of the blade, where the edge (106) is diametrically opposite to the cutting edge that is moved with respect to the notch (104) according to a longitudinal axis of the blade and towards a distal free end of the blade.

Description

VIBRANT CUTTING DEVICE Technical Field The present invention

  relates to a new cutting device comprising a vibrating slender cutting element of the vibrating cutting blade type. This vibrating slender cutting element may, as the case may be, comprise a tapered and cutting cutting edge, or comprise an untapered cutting edge capable of cooperating with another element comprising a sharp tapered edge. The cutting device of the invention finds, for example, but not exclusively, its application as a manual cutting tool, particularly in the food industry. PRIOR ART It is known today to use cutting devices comprising a vibrating blade, and preferably an ultrasonic vibrating blade, and which can be used to slice or cut different materials.

  A first type of cutting device, used for example in the food industry, uses vertical cutting blades, and vibrating means for creating vertical vibrations in the blades. In these cutting devices, the vibration of the blade is relatively simple because the cutting blade vibrates essentially along a single axis (vertical axis). Nevertheless, these cutting devices, comprising a vibrating blade along a single vibratory axis, are generally mounted on slicing machines, and are not suitable for producing manual cutting tools, that is to say cutting tools. intended to be handled by a user during the cutting operation. It has already been proposed manual cutting tools with vibrating blade, for example in international patent applications WO03 / 095028 and WO2005 / 084264. These manual vibrating blade cutting tools are primarily intended for use in the surgical field.

  In the international patent application WO2005 / 084264, the cutting device comprises a flat surgical cutting blade whose distal portion is curved with respect to the central longitudinal axis of the blade, so as to create a functional asymmetry, and means vibrating device for creating longitudinal vibrations in the opposite proximal portion of the blade. These longitudinal vibrations propagate towards the curved distal portion, and due to the aforementioned functional asymmetry, allow vibration of the blade distal end transversely in the plane of the blade. Preferably, to accentuate the transverse vibrations of the distal end of the blade, the cutting blade also comprises upstream of the aforementioned functional asymmetry, a second asymmetry for creating a pivot point in the blade. This cutting device has at least two disadvantages. On the one hand the mechanical assembly between the flat cutting blade and vibrating means, piezoelectric transducer type, is difficult to achieve. On the other hand, the functional asymmetry at the distal end of the blade adversely complicates the manufacture of the blade. In a particular variant embodiment, the cutting device, disclosed in the international patent application WO 03/095028 (FIGS. 19A and 19B), comprises a vibrating monobloc cutting tool, which comprises a bar and a flat cutting blade situated in the extension of the bar and connected to the bar by a transition zone. The device further comprises vibrating means for creating in the bar vibrations which are oriented along the longitudinal axis of the bar. These longitudinal vibrations propagate in the cutting tool, and allow to obtain a vibration of the cutting blade with at least one transverse vibratory component in the plane of the blade. A disadvantage of this cutting device lies in the formation of vibration nodes in the blade, which results in the formation, at the cutting edge of the blade, of static zones in which the blade does not vibrate or almost not . These nodes of vibration in the blade are detrimental to the quality of the cut, and make this solution suitable only for very short blades. OBJECT OF THE INVENTION The object of the invention is to propose a new cutting device comprising an improved vibrating cutting tool, which makes it possible to improve the quality of the vibration of the blade, and thus the quality of the cut, and of which the manufacture is simpler than for the cutting device of the international patent application WO2005 / 084264. This new cutting device can advantageously be used as a manual cutting device; the invention is however not limited to this single application and the cutting device may optionally be adapted to a cutting machine. SUMMARY OF THE INVENTION The invention thus has for its first object a one-piece cutting tool intended to be assembled with vibrating means, so as to constitute the vibrating cutting tool of a cutting device. This cutting tool is known, in particular from the aforementioned international patent application WO 03/095028, in that it comprises a bar and an elongated cutting element situated in the extension of the bar and connected to the bar by a transition zone. said cutting element having a longitudinal cutting edge and defining a longitudinal cutting plane (Y, Z) perpendicular to the plane (X, Z) of the cross-section of the bar, said cutting element having a measured dimension (e) along the axis (X) perpendicular to the longitudinal section plane (Y, Z), which is less than the dimension (DI) of the cross section of the bar measured along the same axis (X). According to the invention, the one-piece cutting tool comprises a first notch which is formed at least partly in the longitudinal cutting edge of the cutting element, and a second notch, which is made in a part of the cutting element diametrically opposed to the longitudinal cutting edge, and which is offset with respect to the first notch, along the longitudinal axis (A) of the cutting element and towards the distal free end of the cutting element; cutting element. It was found that the implementation of these two notches diametrically opposed and offset along the longitudinal axis of the cutting element made it possible to improve the vibratory behavior of the cutting tool. In particular, by judiciously dimensioning these notches, it is possible to avoid the formation of a vibration node (of zero or almost zero amplitude), at least at the longitudinal cutting edge of the elongate cutting element, in a distal zone that extends from the distal end (that is to say the free end of the blade opposite the bar) and over a very long length of the elongate cutting element. Preferably, but optionally according to the invention, the cutting tool has the following additional technical features, taken alone or in combination: the second notch is made in the distal portion of the cutting element which extends between the first notch and the distal end of the cutting element; in an alternative embodiment, the first notch extends entirely into the cutting element; in another variant embodiment, the first notch extends in the bar, in the transition zone and in the cutting element; the cutting tool comprises a third notch which extends wholly or partly in the bar, and which is formed in a portion of the cutting tool diametrically opposed to the longitudinal cutting edge; the first and second notches, and if necessary the third notch, have U-shaped longitudinal profiles, the invention not however being limited to this particular U shape; the cutting element is constituted by a flat cutting blade; the cutting element is centered with respect to the bar; the largest dimension (I) of the cutting element, measured in the longitudinal section plane (Y, Z) along the axis (Y) perpendicular to the longitudinal axis (A) of the cutting element, is less than or equal to the dimension (D2) of the cross section of the bar measured in the longitudinal section plane (Y, Z) along this same axis (Y); - The length (L) of the cutting element is greater than 5 cm, preferably greater than 10 cm, and more preferably still greater than 20 cm. The invention also has for another object a cutting device comprising a vibrating monobloc cutting tool referred to above and vibrating means. The vibrating means make it possible to create, in the bar of the cutting tool, longitudinal vibrations, which are oriented along the longitudinal axis (A) of the cutting element, and which allow a vibration of the cutting element. the cutting element (102) in the longitudinal cutting plane (Y, Z) of this cutting element and with at least one transverse vibratory component which is perpendicular to the longitudinal axis (A) of the cutting element.

  Preferably, the notches of the cutting tool are made so as to obtain a vibration of the cutting element in said longitudinal cutting plane (Y, Z), without vibration node formation at least the longitudinal cutting edge of the cutting element, and in a distal zone (Z ') extending from the distal free end of the cutting element and at least three quarters of the length (L'). ) of the cutting element between this distal free end and the first notch. More preferably still, said distal zone (Z '), devoid of vibration node, extends from the distal free end of the cutting element to the first notch.

  More particularly, the vibrating means are designed to create, in the bar of the cutting tool, longitudinal vibrations with a predefined frequency (f) greater than 10 KHz, and preferably greater than or equal to 20 KHz. BRIEF DESCRIPTION OF THE DRAWINGS The invention and its advantages will be better understood on reading the following detailed description, which description is made solely by way of nonlimiting and non-exhaustive example of the invention, and with reference to the FIGS. 1 is a side view of a vibrating cutting device, according to a first embodiment of the invention, FIGS. 2 and 3 are respectively top and bottom views of the device. FIG. 4 is a perspective view of the cutting device of FIGS. 1 to 3, FIG. 5 represents an (exaggerated) deformation of the cutting tool 15 of FIGS. 1 to 4, FIGS. 6 to 12 respectively represent the (exaggerated) deformations of seven embodiments of a cutting tool, which are not in accordance with the invention and whose vibration behavior is not satisfactory, FIG. 3 represents an (exaggerated) distortion of a second embodiment of a cutting tool according to the invention, - Figure 14 is a side view of a vibrating cutting device, according to a third embodiment variant. FIGS. 15 and 16 are respectively top and bottom views of the cutting device of FIG. 14, FIG. 17 is a perspective view of the cutting device of FIGS. 14 to 16, FIG. represents an (exaggerated) distortion of a cutting tool comprising the same notches as the cutting tool of FIGS. 14 to 17; FIG. 19 represents an (exaggerated) deformation of a fourth embodiment of a tool DESCRIPTION OF THE PREFERRED EMBODIMENT FIGS. 1 to 4 show a vibrating cutting device 1 made according to a first embodiment of the invention.

  This cutting device 1 has the general shape of a hand knife. It can advantageously be. used to manually slice any type of material, and may especially, but not exclusively, be used for manual cutting of food products. This cutting device 1 comprises a one-piece cutting tool 10 with a longitudinal central axis A, which is assembled with vibrating means 11. This one-piece cutting tool 10 is made of metal, for example stainless steel or aluminum. titanium. The one-piece cutting tool 10 comprises a bar 100 and a flat cutting blade 102, which is located in the extension of the bar 100, and is connected to the bar 100 by a junction zone 101. The cutting blade 102 defines a plane of longitudinal section referenced (Y, Z) in Figures 1 to 4. This longitudinal sectional plane (Y, Z) corresponds to the longitudinal median plane of the blade 102, and is perpendicular to the transverse plane (X, Y) parallel to the cross section of the bar 100.

  In the particular example illustrated, the bar 100 is of cylindrical shape. This particular form is not limiting of the invention, the bar 100 may have a completely different geometry in cross-section [plane (X, Y): I) and for example a square, rectangular, oval cross section, etc. ..

  At its proximal end 100a opposite the blade 102, the bar 100 is firmly fixed to the vibrating means 11. These vibrating means 11 make it possible to generate longitudinal vibrations in the bar 100, that is to say vibrations oriented in the direction parallel to the longitudinal axis A of the bar 100. The structure and operation of these vibrating means 11 are known and therefore will not be detailed. It is simply recalled that these vibrating means 11 usually comprise an electrically powered piezoelectric transducer, and a coupling element between this piezoelectric transducer and the bar 100, this coupling element allowing the amplification of the longitudinal vibrations generated by the piezoelectric transducer. piezoelectric transducer. In the particular example illustrated in FIGS. 1 to 4, these vibrating means 11 are advantageously housed in a cylindrical casing, also acting as a gripping handle for the cutting device 1. The cutting blade 102 is formed in a plate of length (L), width (I) and thin (e). With reference to FIGS. 2 and 3, the thickness (e) of the blade 102 is smaller than the dimension DI of the bar 100 in the transverse plane (X, Z) which corresponds to said thickness (e) and which is perpendicular to the plane longitudinal section (Y, Z). This blade 102 has a longitudinal cutting edge 103 (lower edge of the blade in Figure 1), and a longitudinal edge 106 (upper edge of the blade in Figure 1) diametrically opposed to the longitudinal cutting edge 103. Preferably, as illustrated, the width (I) of the blade [largest dimension of the blade 102 in the longitudinal section plane (Y, Z)] is less than or equal to the corresponding dimension D2 of the bar 100 in this same plane, such that the cutting tool 10 can be easily manufactured by simple machining with removal of material from an initial bar which has the same cross section as the bar 100, and whose length corresponds to the total length of the tool Also preferably, but not necessarily, the cutting blade 102 is centered on the bar 100 in the transverse plane (X, Z) (FIG. 2). With reference to FIG. 2, the junction zone 101 connecting the bar 100 and the cutting blade 102 has two curved walls 101a which make it possible to progressively transition material in the plane (X, Z) between the dimension DI in section transverse in this plane of the bar 100, and the thickness (e) lower blade 102. In the particular example illustrated, these two curved walls 101a are symmetrical to each other with respect to the central axis longitudinal A bar 100, this feature is however not limiting of the invention.

  Preferably, but not necessarily, the longitudinal edge 103 of the blade, which forms the cutting edge, has a curved profile on a distal portion 103a which extends from the distal free end 102a of the blade 102 (free end of the blade farthest from the bar 100). This distal curved portion 103a is the portion of the blade that is mainly used for cutting a material. Preferably, but not necessarily, the cutting edge 103 of the blade 102 may be thinned, at least in its distal portion 103a (Figure 1), so as to form a sharp tapered edge. Also preferably, but not necessarily, the distal end 102a of the blade substantially forms a tip, facilitating insertion of the blade into the material upon cutting. According to a first feature of the invention, the cutting tool 10 has a first longitudinal notch 104 and a second longitudinal notch 105. The first notch 104 is constituted by a cutout which is made at least partly in the longitudinal edge in the particular example illustrated, this cutout 104 is made over the entire thickness (e) of the blade 102 (FIGS. 3 and 4), and has a longitudinal profile in the form of a U-shape, length II [Figure 1/25 profile of the cut in the longitudinal section plane (Y, Z)]. In the illustrated example (FIG. 1), the longitudinal U-shaped profile of the first cutout 104 comprises two curved portions 104a and 104b connected by a central portion 104c, preferably substantially rectilinear. With reference to FIG. 1, this U-shaped longitudinal profile has a center of symmetry, the two curved portions 104a and 104b having the same radii of curvature and the bottom of the notch 104 corresponding to the aforesaid central portion 104c forming a plane parallel to the longitudinal central axis A. This is however not limiting of the invention, said longitudinal profile of the notch 104 may be asymmetrical in another variant.

  In the particular example of FIGS. 1 to 4, this first notch 104 extends longitudinally in the proximal portion 102b of the cutting blade 102, in the transition zone 101 and in the distal portion 100b of the bar. This particular positioning of the first notch 104 along the longitudinal axis A is not limiting of the invention.

  In another variant, the first notch 104 may extend longitudinally only in the longitudinal cutting edge 103 of the cutting blade 102. The second notch 105 is constituted by a cutout which is made in the longitudinal edge 106 of the blade, diametrically opposite to the cutting edge 103, and which is offset, with respect to the first notch 104, along the longitudinal axis A and towards the distal end 102a of blade 102. In the particular example illustrated, this cutout 105 is also made over the entire thickness (e) of the blade 102 (Figures 3 and 4), and has a U-shaped longitudinal profile, of length 12 [Figure 1 / profile of the cut in the longitudinal section plane (Y , Z)]. More particularly, with reference to FIG. 1, the second notch 105 preferably has a longitudinal profile which is asymmetrical. This asymmetrical longitudinal profile comprises two curved portions 105a and 105b connected by a central portion 105c, preferably substantially rectilinear. The two curved portions 105a and 105b respectively have two radii of curvature Ra and Rb which are slightly different, and the bottom of the notch corresponding to the central part 105c above forms a plane which is slightly inclined with respect to the central longitudinal axis A (FIG. 1 / angle a) In the particular example illustrated, the second notch 105 is made in the clist portion of the blade 102 which extends between the first notch 104 and the distal end 102a of blade 102, both notches 104 and 105 being spaced from each other, along the longitudinal axis A, a distance (d) non-zero (Figure 1). In another variant, it is conceivable that the second notch 105 is indeed offset, with respect to the first notch 104, along the longitudinal axis A and in the direction of the distal blade end 102a, but in such a way that the two notches overlap on part of their lengths (II, 12) in the cutting plane (Y, Z); in this case, the curved portion 105b proximal of the notch 105 is located at the right of the notch 104 along the Y axis, and the curved distal portion 105a of the notch 105 is located between the distal end 102a of the blade and the distal curve portion 104a of the first notch 104. In operation, when the vibration setting means 11 are active, they generate longitudinal vibrations at a predetermined frequency (f) to excite at least one specific mode of vibration of the cutting tool 10. This excitation frequency (f) is a function of the geometry of the cutting tool 10, and depends in particular on the length L of the cutting blade 102. Preferably, the tool 10, and in particular the cutting blade 102, is dimensioned such that this frequency (f) is: greater than 10KHz, and more preferably greater than 20KHz, so as to make the vibrations inaudible to the human ear (vibrations ultrasound). Said longitudinal vibrations propagate in the bar 100 in the direction of the blade 102, the tool 10 acting as a resonator.

  Under the effect of these vibrations, the blade 102 vibrates in its longitudinal section plane (Y, Z), with a vibration movement comprising two vibratory components: a longitudinal component along the Z axis and a transverse component along the axis Y. As it appears more clearly in FIG. 5, the two notches 104 and 105 make it possible to improve the vibratory behavior of the cutting blade in its cutting plane (Y, Z). This FIG. 4 shows the deformation of the cutting tool 10 during the operation of the vibrating means 11. This deformity has been calculated in the usual way by means of a simulation software using a calculation method by Finished elements. In this FIG. 5, the deformations of the cutting tool have been deliberately exaggerated, in order better to show the vibratory behavior of the cutting tool. The vibration amplitude of the cutting tool in the plane cutting (Y, Z) (that is to say the resultant vibratory components Y and Z) is not identical at any point of the tool, and in particular at any point of the cutting blade 102 These amplitude variations have been symbolized in FIG. 5 by zones having different fillings, each type of filling corresponding to a range of amplitudes which is plotted on a vertical scale. With reference to this scale of amplitudes of FIG. 5, the filling corresponding to the bottom of the scale identifies a region of vibrations of almost zero amplitude characteristic of a vibration node. In contrast, the filling corresponding to the top of the scale identifies a region in which the amplitudes of vibrations (resultant vibratory components Y and Z) are maximum.

  The deformed part of FIG. 5 makes it possible to show that the vibration amplitudes of the blade 102 are advantageously maximum and substantially identical throughout the distal portion (Z1) of the blade 102 which extends substantially between the second notch 105 and the end In addition, over the entire region Z 'of the longitudinal cutting edge 103, which extends between the distal end 12a of the blade 102 and the beginning of the first notch 104, the amplitudes of vibrations are important, and there is no vibration knot formation in this region at the cutting edge 103. The quality of cut is therefore very good. In this FIG. 5, one can also note the formation of a nodal region N (vibration node) in the cutting blade 102; however, this nodal region N is very small, and especially is located at the longitudinal edge 106 opposite the cutting edge 103. It is not detrimental to the quality of cut. By way of comparison, FIGS. 6 to 12 show the deformations of six embodiments of a vibrating cutting tool, which are not in accordance with the invention, and whose vibratory behavior is not satisfactory. . In FIG. 6, the cutting tool is different from the cutting tool 10 of FIGS. 1 to 4, in that its cutting element 102 'is a rectangular flat blade without notch.

  In Figure 7, the cutting tool is different from the cutting tool 10 of Figures 1 to 4, only in that the cutting blade 102 does not have a notch. In FIG. 8, the cutting tool is different from the cutting tool 10 of FIGS. 1 to 4, only in that the cutting blade 102 has only one proximal notch 104. In FIG. 9, the tool of cutting is distinguished from the cutting tool 10 of Figures 1 to 4, only in that the cutting blade 102 has a single proximal notch 104 ', which is made exclusively in the blade 102, and which does not extend in the bar 100. In FIG. 10, the cutting tool is different from the cutting tool 10 of FIGS. 1 to 4, only in that the cutting blade 102 has a single distal notch 105. In FIG. 11, the cutting tool is different from the cutting tool 10 of Figures 1 to 4, only in that the cutting blade 102 has a distal notch 105, and an additional notch 107 in the bar 100. On the 12, the cutting tool is different from the cutting tool 10 of FIGS. 1 to 4, in that the cutting blade has the same shape as in FIG. the blade 102 of Figures 1 to 4, but has only a first proximal notch 104 ', which is made exclusively in the bar 100, and which does not extend into the blade 102.

  In the embodiments of FIGS. 6, 7, 8, 9, 10 and 11, it can be noted the formation of an important vibration node N which extends to the longitudinal cutting edge 103 of the blade, and which fact is detrimental to the quality of the cut.

  In the embodiment of FIG. 12, it can be noted the formation of a zone Z2 of extremely small amplitudes, which extends over the entire width of the blade, and which is detrimental to the quality of the cut. Furthermore, in FIGS. 11 and 12, it can be noted that the zone Z1 at the end of the blade, in which the amplitudes of vibrations are maximum, is disadvantageously very small, and increases the risks of breaking the blade in this distal zone. FIG. 13 shows the deformation of another variant embodiment of a vibrating cutting tool, which is in accordance with the invention. In FIG. 13, the cutting tool is different from the cutting tool 10 of FIGS. 1 to 4 solely by the longitudinal position of the first notch 104; in this variant, said first notch 104 extends exclusively into the cutting blade 102. The vibratory behavior of this variant is very satisfactory and comparable to that of FIG. 5. FIGS. 14 to 17 show another variant. embodiment of the invention, which differs from the variant of Figures 1 to 4, essentially by the implementation of a cutting blade 102 and a bar 100 longer, and by the presence of a third notch 107. This third notch 107 extends in the distal portion of the bar 100, and is made in a portion of the bar 100 diametrically opposed to the longitudinal cutting edge 103 of the blade. This third notch 107 thus has the same orientation as the second distal notch 105. FIG. 18 shows the deformation of a vibrating cutting tool, whose blade 102 has the same geometry as the blade of FIGS. 1 to 4 but which has three notches 105, 04 and 107 identical to those of the device of Figures 14 to 17. In this variant, we can note the formation of nodal z: ones N1, N2 and N3 (vibration nodes).

  On the one hand, these nodal areas N1, N2 and N3 are very small. On the other hand and especially the two nodal areas NI and N2 are located at the edge 106 opposite the longitudinal cutting edge 103, and the nodal area N3 is very far from the distal end 102a. The vibrations of the blade 102 at the cutting edge 103 are advantageously large and substantially homogeneous over a very wide zone Z 'which extends from the distal free end 102a of the cutting element 102 and over a longer distance. three quarters of the length L 'of the cutting element 102 between this distal free end 102a and the first notch 104. FIG. 19 shows the deformation of a cutting tool, which is in accordance with FIG. the invention, and which differs from the cutting tool of Figures 14 to 18, only by the longitudinal positioning of the first notch 104. In this variant, said first notch 104 extends exclusively into the cutting blade 102. The vibratory behavior of this variant is very satisfactory. The invention is notlimited to the particular embodiments which have just been described with reference to the appended figures, but extends to any cutting device defined in the appended claims. In particular, and in a non-exhaustive manner, the invention is not limited to the particular geometry of the cutting blade 102 of the appended figures, and in particular to the particular curved profile of the cutting edge 103 of this blade 102, said blade flat which may be generally made in any thin plate (e), and the cutting edge 103 may for example be rectilinear over its entire length or may have a curvilinear profile different from that of the accompanying figures. More generally still, in the context of the invention, the cutting blade 102 may be replaced by any elongate cutting element which is located in the extension of the bar 100, which defines a longitudinal sectional plane (Y, Z) perpendicular to the plane (X, Z) of the cross section of the bar, and whose dimension (e) in cross section and in the direction (Z) perpendicular to this section plane (Y, Z) is smaller than the dimension (D,) corresponding, for example, and without limitation, the cutting blade 102 can be replaced by a cylindrical cutting rod which has a smaller diameter in cross-section than the diameter of the bar 100, and which is connected to the bar 100 by a frustoconical transition zone.

  The invention is not limited to the shape and the particular dimensions of the notches 104, 105 and 107 U of the accompanying figures. It is up to the person skilled in the art to adapt the shape and dimensions of the notches 104, 105, 107, the longitudinal positions of the notches 104 and 105 in the blade 102, and where appropriate the longitudinal position of the notch 107 in the distal portion 100b of the bar 100, depending on the geometry and dimensions of the cutting tool 10, so as to obtain at the longitudinal cutting edge 103, a zone of vibration Z 'extended, which does not include vibration node, and wherein the vibration amplitudes are large and preferably substantially homogeneous. In the alternative embodiments of the accompanying figures, the cutting element 102 (blade) has a longitudinal cutting edge 103 which is relatively thin and preferably tapered so as to be sharp. This is not limiting of the invention. In another variant of the invention, the cutting device may comprise another cutting elongate element (fixed or movable) adapted to cooperate with the cutting element 102 vibrating and allowing cutting by shear between these two cutting elements. In this case for example, it is not necessary that the cutting edge 103 of the vibrating cutting element 102 be sharp and sharp.

Claims (15)

  1. Monobloc cutting tool (10) to be assembled with vibrating means (11), so as to constitute the vibrating cutting tool of a cutting device (1), said cutting tool (10). ) having a bar (100) and an elongated cutting element (102) located in the extension of the bar (100) and connected to the bar (100) by a transition zone (101), said cutting element (102) having a longitudinal cutting edge (103) and defining a longitudinal sectional plane (Y, Z) perpendicular to the plane (X, Z) of the cross-section of the bar, said cutting element (102) having a dimension (e), measured according to the axis (X) perpendicular to this longitudinal section plane (Y, Z), which is smaller than the dimension (DI) of the cross section of the bar measured along the same axis (X), characterized in that it comprises a first notch (104) which is made at least partly in the longitudinal cutting edge (103) of the section (102), and a second notch (105), which is formed in a portion (106) of the cutting element (102) diametrically opposed to the longitudinal cutting edge (103), and which is offset from the first notch (104) along the longitudinal axis (A) of the cutting element (102) and towards the distal free end (102a) of the cutting element (102).   2. Cutting tool according to claim 1, characterized in that the second notch (105) is formed in the distal portion of the cutting element (102) which extends between the first notch (104) and the end distal (102a) of the cutting element (102).   3. Cutting tool according to one of claims 1 or 2, characterized in that the first notch (104) extends entirely in the cutting element (102).   4. Cutting tool according to one of claims 1 or 2, characterized in that the first notch (104) extends in the bar (100), in the transition zone (101) and in the cutting element (102).   5. Cutting tool according to one of claims 1 to 4, characterized in that it comprises a third notch (107) which extends wholly or partly in the bar (100), and which is made in part the cutting tool (10) diametrically opposed to the longitudinal cutting edge (103).   6. Cutting tool according to one of claims 1 to 5, characterized in that the first and second notches (104, 105), and optionally the third notch (107), have U-shaped longitudinal profiles.   7. Cutting tool according to claim 6, characterized in that the longitudinal profile U of the second notch (105) is asymmetrical.   8. Cutting tool according to one of claims 1 to 7, characterized in that the cutting element (102) is constituted by a flat cutting blade (102).   9. Cutting tool according to one of claims 1 to 8, characterized in that the cutting element (102) is centered with respect to the bar (100). 20   10. Cutting tool according to one of claims 1 to 9, characterized in that the largest dimension (I) of the cutting element (102), measured in the longitudinal sectional plane (Y, Z) following the the axis (Y) perpendicular to the longitudinal axis (A) of the cutting element (102) is less than or equal to the dimension (D2) of the cross section of the bar (100) measured in the plane of section longitudinal (Y, Z) along this same axis (Y).   11. Cutting tool according to one of claims 1 to 10, characterized in that the length (L) of the cutting element (102) is greater than 5 cm, preferably greater than 10 cm, and more preferably 30 still greater than 20 cm.   12. Vibrating cutting device (1) comprising a vibrating vibrating tool and vibrating means (11), characterized in that the cutting tool (10) is according to one of claims 1 to 11, and in that the vibrating means (11) make it possible to create, in the bar (100) of the cutting tool (10), longitudinal vibrations, which are oriented along the longitudinal axis (A) of the cutting element (102), which allows the cutting element (102) to vibrate in the longitudinal cutting plane (Y, Z) of this cutting element (102) and with at least one vibratory component transverse which is perpendicular to the longitudinal axis (A) of the cutting element (102).   13. Device according to claim 12, characterized in that the notches (104, 105, ...) of the cutting tool (10) are made so as to obtain a vibration of the cutting element ( 102) in said longitudinal section plane (Y, Z), without vibrating node formation at least at the longitudinal cutting edge (103) of the cutting element (102), and in a distal zone (Z '). ) extending from the distal free end (102a) of the cutting element (102) and at least three-quarters of the length (L ') of the cutting element (102) between that distal free end (102a) and the first notch (104).   14. Device according to claim 13, characterized in that the notches (104, 105, ...) of the cutting tool (10) are made so as to obtain a vibration of the cutting element ( 102) in said longitudinal section plane (Y, Z), without vibration node formation at least at the level of the longitudinal cutting edge (103) of the cutting element (102), and in a distal zone (Z ') which extends from the distal free end (102a) to the first notch (104).   15. Device according to one of claims 11 to 14, characterized in that the vibrating means (11) are designed to create, in the bar (100) of the cutting tool (10), longitudinal vibrations with a predefined frequency (f) greater than 10 KHz, and preferably greater than or equal to 20 KHz.