KR20030036881A - Coupling system for the teeth of an excavator - Google Patents

Abstract

The straight form of the adapter having an angle between approximately 10 ° and 40 °, invading the differentiated intermediate cross section, and having two end faces which meet in a concentric manner in the intermediate cross section which is different from the above mentioned sections In the adapter portion, which is also provided in the axial direction, in the axial direction, the adapter portion comprising each of the straight cross-sections of each of the straight protrusions of the tooth portion, substantially supplementing the concave contour of the rear portion of the groove of the recess A coupling system of excavator teeth, complementing each open groove and extending in the axial direction, with two straight projections, remarkably parallel to each other, in the form of cantilever beams in the mouse of the central housing.

Description

COUPLING SYSTEM FOR THE TEETH OF AN EXCAVATOR}

The present invention relates to a coupling system of excavator teeth, in particular an adapter member secured to a bucket or shovel of an excavator or the like and one or more pins connected to the adapter member. A coupling system of teeth formed by engagement of a tooth member secured by a pin.

More specifically, the invention relates to one of the tooth and adapter parts mentioned above, preferably the tooth member, which extends in the axial direction inside two rectilinear lugs which are parallel to each other and protrude from the mouse of the central housing. And engage with respective rectilinear open recesses, which are also axially formed on the adapter member, wherein the adapter member has a cantilever projection that engages with the central housing of the tooth member. The tooth member protrusion has an inner surface consisting of a flat or arcuate curved surface in contact with the rear of the adapter member groove.

Several patents are known to relate to the grooves of corresponding adapter sections and various aspects of the organization, arrangement, and configuration of the tooth projections, and it is necessary to mention the following: in order to retain the tooth portions engaged in the adapter portions. It has an internal step with a groove in the periphery of the inserting fork adjacent to the inner step of the tooth portion, supporting the face of the adapter without any guide or positioning protrusion, Patent US 4.404.760, which includes the tooth portion with each flat protrusion; A corresponding groove of the adapter part and one of said tooth parts having one of said protrusions having an inner protrusion for insertion of a pin, said inclined with respect to the axis of the ensemble associated with said protrusion having an inner surface with a remarkably conical surface; US5.379.535 including the projections; The straight projection has a longitudinal wall inclined toward the rear portion of the curved convex arc, whereas the projection of the tooth portion has a longitudinal edge inclined outwardly and externally to the concave surface of the curved arc. Comprising US 5.386.653; The relationship between the adapter having a straight groove with a projection and the straight groove for the adapter with the straight groove having a longitudinal wall inclined toward the rear at the rear with a slightly convex two-sided surface with a steep edge US 5.456.029; The rear portion of the adapter portion having a continuous surface that can have a flattened arc or an equilibrium of apex curve arc which generally complements the surfaces of the inner two surfaces of the projection of the tooth portion, and downwards toward the rear portion of the corresponding groove. An inclined EP, comprising the tooth portion having a longitudinal edge which steers in the longitudinal wall to complement those of the projection and has a few steps in the longitudinal wall, while steep in an outwardly inclined step 0 835 963; And in Spain the patent is inclined in a symmetrical and centralized form, whereas the projection arrangement of the tooth portion relative to the groove of the adapter portion is similar to that adopted in the previous European patent, in which the projections are significantly parallel to the electrons. ES 9902161 comprising having the characteristic case of.

As shown in U.S. Pat.Nos. 5.379.535 and 5.423.138, with a variety of systems shown by the coupling of the adapter part to the tooth part by simple grooves and projections from one to the other in general, Achieved: thanks to a more stable system, improving the adhesion performance of the tooth to the adapter; Removal of stresses experienced by the pins due to a more stable system; Increasing the strength of the entire part by providing a larger lever arm.

In all engagements with protrusions and grooves, the problem arises as the tooth portion protrusions separate and protrude from the adapter portion when the adapter portion transfers the stress experienced by the tooth portion, whereby the tooth protrusions at the adapter portion The example shows that this tendency to separate increases the risk of breakage of the protrusion.

In order to overcome this drawback, in the longitudinal wall of the adapter part and at the longitudinally lower and upper edges of the tooth projection, a US patent including a created angle to prevent exclusion therefrom. 5.386.653 has also been filed with EP 0.835.963 which forms the guide arrangement and comprises the toothed protrusion having a longitudinal edge in a stepwise complementary arrangement with respect to the longitudinal wall of the adapter part groove.

In both cases, the tooth portion still tends to open or protrude in the adapter portion groove, but the inclined surface or the guide arrangement keeps them there. In fact, the projections are prevented from detaching from the adapter, but a concentration of force inducing breakage occurs in the support surface of the projection in the adapter portion groove.

Another solution adopted in EP 9902161 is the installation of two straight projections in spite of their respective concentric planes. In this case, when the tooth portion receives the upper vertical force (see Fig. 23), the protrusion is closed in a compressed state, while the protrusion is opened when the lower vertical force is received.

In order to overcome these drawbacks, a solution for steeping the tooth portion projection in an approximate manner has been adopted, i.e., having a straight cross section with a concave portion facing the adapter portion groove, the rear portion of the adapter portion is complemented. In general, the above-mentioned part has a convex shape.

According to the preceding solution, it has two end sections which meet in a form concentrating in an intermediate section which is distinct from the above mentioned section, and the tooth part projections concave in one part and generally supplement the concave shape behind the adapter part groove. According to each straight section of the system developed the subject of the present invention.

A feature of the present invention is that it consists of the two end faces of a straight section of each tooth projection which impinges on the intermediate section at an angle between approximately 10 degrees and 40 degrees.

The present invention includes the fact that the distinct intermediate section of the straight section of the tooth projection may have a curved or straight configuration without excluding other complex configurations (mixed, separated configurations, etc.).

Furthermore, the present invention provides that the end face of the straight cross section of each projection is equal to or different in length in one of the preceding cases, the projection angle of the same or different intermediate cross section with respect to the same straight cross section and one of the two end cross sections. The end section includes the fact that it can have a straight or curved configuration without excluding other possibilities, including those that can have the same or different configurations.

Another feature of the present invention lies in the fact that one of the two projections and the tooth portion can be symmetrical about one point or mirror like.

A still further feature of the present invention lies in the fact that the tooth projection is in communication with an orifice intersecting the cantilevered projection of the adapter portion and has an orifice which is located at one of the intermediate or two end faces and is symmetric in the radial direction.

The less two sides of the straight section of the tooth protuberance are significantly parallel and perpendicular to each other and the straight cross section of each tooth protuberance has the same width along the entire extension but it is a reduced extension with a different width from the general width. It is also a feature of the present invention that it can have one or more regions.

Finally, another feature of the present invention lies in the fact that the longer end cross section in the tooth projection is directed in a direction that can withstand stress.

In order to facilitate understanding of the preceding premises, the object of the present invention is described below with reference to the accompanying drawings, in which:

1 is an angularly exploded perspective view of the tooth portion and adapter shown as mutually engaging portions in accordance with the present invention;

Figure 2 is a side view of the tooth and adapter element of the preceding figure when in the engaged position;

Figure 3 is a plan view of the adapter and tooth portion of the preceding view.

4 is a diagrammatic view showing the entirety of the combined adapter and tooth in which a lower vertical stress is imagined to act on the end of the tooth, in accordance with the present invention.

FIG. 5 is a cross-sectional view taken along the line V-V of FIG. 4 showing the effect of lower vertical stress acting on the tooth protrusion. FIG.

Fig. 6 shows a reaction generated by the stress, and similarity of Fig. 4 showing the entirety of the combined adapter and tooth where a vertical stress is imaginatively applied to the top of the tooth.

Figure 7 shows the effect when the upper vertical stress acts on the tooth protrusion,

Fig. 6 is a cross sectional view taken along the line VII-VII.

Fig. 8 shows the position of the tooth protrusion projected in the adapter part groove and the three positioning potentials of the housing for engagement with the fixing pin, which are indicated by dotted lines when in use, and perpendicular to the central axis of the protrusion and in the vertical part. 5 and 7 are cross-sectional views showing a limiting angle between the end faces of the tooth protrusions with respect to each other.

Fig. 9 is a cross-sectional view similar to the preceding figure, comprising an end section of a straight section of both tooth projections having a constant and linear configuration with respect to the discriminated intermediate section and having a straight configuration;

Fig. 10 shows that the tooth protrusions are symmetrical with respect to one point, have a straight section of the protrusion with the end face, are straight and have different lengths for each, and one of them is in a staggered position with respect to the other, A cross-sectional view similar to the preceding drawing, wherein the discriminated intermediate cross section has a curved shape with a housing position of the retaining pin, indicated by a dotted line.

Fig. 11 is a symmetrical form in which the tooth projection has a straight end surface of a different length from a curved middle section and reflects like a mirror, and the short end surface is in the lower position in this case, A cross section similar to FIG. 10, including not apparent, but including the possibility of placing them in the lower position in other cases.

Figure 12 is a diagram of any of a variety of shapes that a straight section of the tooth projection can adopt.

Fig. 13 shows the rear end of the adapter groove with protrusions that compensate for depression in the differentiated intermediate section and the straight section of the tooth projection in the intermediate section with different widths. Schematic of a half cross section similar to in FIG.

Fig. 1 shows an angled exploded perspective view of the whole part composed of the tooth part 2 and the adapter part 1.

Adapter portion 1 includes a central core (3), the fork (4) to which the adapter portion (1) is coupled to the edge of the shovel or bucket of the excavator on one side and the shape of a tetragonal system on the other side A cantilever protrusion 5 or nose having an extension in the axial direction. The central core 3 has straight grooves 6 on each side and has an orifice in the transverse direction, which surrounds the retention pins, both of which do not reduce the cross section of the nose 5. Are arranged to avoid.

The tooth portion 2 is a projection 10 of a shape surrounded by a working point 11 and a straight line, each of which is stiff from the mouse 9 and comprises a central core 7 including a central housing 8 in an axial direction. .

2 and 3, when the adapter part 1 and the tooth part 2 are coupled to each other, the protrusion 10 having a straight line surrounded by the tooth part 2 is surrounded by a straight line with the adapter 1. Is housed in the groove 6 of the adapter, for example, in the center core 3 of the adapter portion 1 into which the fixing pin 13 is inserted and in a line with the straight protrusion 10 of the tooth portion 2. The engagement is maintained by passages 12, consisting of orifices provided to align.

The foregoing description should be considered to be included in the state of the art, as shown in the citations of the patents at the beginning of this description.

The object of the present invention is that the straight cross section of each of the straight protrusions 10 of the tooth portion 2 fitted with the convex portion of the straight groove rear 15 of the adapter 1 is concave and the portion 14 is 5 and 7 and as shown in more detail in FIG. 8, it has the fact that it has two end faces 10A which are concentrated in an intermediate section 10B. This is also related to FIGS. 4 and 5.

In order to easily understand the above description and the following description, the cross sections 10A and 10B are separated by a virtual dotted line M. FIG.

As shown in FIGS. 4 to 7, the stress F _S acts in the direction perpendicular to the downward direction of the operating point 11 of the tooth portion 2, and the reaction portion Rs1 and the straight groove 6 in the nose 5 are formed. A reaction force (Rs2) is induced at the upper edge of the c), which acts on the end surface 10A of the linear protrusion 10 with respect to the rear portion 15 of the linear groove 6. (Cs). This also appears when the stress Fi acts vertically upward on the working point 11 of the tooth portion 2, in which case the reactions are Ri1 and Ri2 and the component force is Ci. This tendency is indicated by the dotted line in the end face 10A of the straight projection 10 of the tooth portion 2 with respect to the rear 15 of the straight groove 6.

As shown in Fig. 8, the projection angle α of the end section 10A in the discriminated intermediate section 10B of the straight section of the straight projection 10 of the tooth portion 2 is the transverse axis ( It should be located between the limiting angles β (δ) defined with respect to the vertical axis Y perpendicular to X), which is estimated to be β = 10 ° y δ = 40 °.

On the other hand, Fig. 8 shows various possible positions of the passage 12 suitable for insertion of the fixing pin 13.

5, 7 and 8 show a straight cross section of the straight protrusion 10, the end faces 10A are straight and identical to each other, and the middle cross section 10B is curved and at each other by an imaginary straight line M. FIG. The case of separation is illustrated.

FIG. 9 illustrates the case where in the straight section of the straight protrusion 10, the end faces 10A are straight and equal to each other and the intermediate section 10B is also straight as a possible passage 12 for the fixing pin as shown. .

10 and 11 show that the straight protrusion 10 is symmetrically positioned in FIG. 10 with respect to one point, and has the same end face 10A and the end face 10C with different lengths in a straight line shape in the middle section 10B. The case of having a projection angle is illustrated, while FIG. 11 illustrates a form in which a symmetrical array is reflected. The longer end (10A) is located below the shorter end (10C), in which case it can be adopted as the opposite position in the last figure. In all these cases, the longer end surface 10A in the straight projection 10 of the tooth portion 2 is directed in a direction that can withstand the stress.

12 illustrates various modifications of the straight cross section that may be employed when producing the straight protrusion 10. As shown therein, in particular, the straight section of the linear projection 16 shows the end face 16A in a curved form and has an intermediate cross section 16B having a curved arc shape different from that of the end face 16A. Shows. The straight cross section of the straight protrusion 17 shows an intermediate cross section 17B which is distinct from the end face 17A in a curved form and a straight form. The straight cross section of the straight protrusion 18 shows the end face 18A in a straight line and the intermediate cross section 18B in a curved form. As a result, the straight cross section of the straight protrusion 19 shows the intermediate section 19B in a straight line like the straight end face 19A. Obviously, various straight sections can be obtained by combining their lengths, orbits, and end sections according to the angle of inclination with straight, curved, long or short and other intermediate sections.

Fig. 13 shows a projection 21 which complements the receding portion 22 of the straight section of the straight protrusion 20 and the intermediate section 20B, in which the discriminated intermediate section 20B has a different width with respect to the end section 20A. Illustrates the rear portion 15 of the straight groove 6 of the adapter portion 1 having a portion between the tooth portion 2 and the adapter portion 1 similar to those shown in FIGS. 5, 7 and 8. Show half of the cross section fastened to

With this system of tight projections, the robustness of the larger system can be ensured and the risk of breakage can be reduced by successfully operating the projections in a compressed state against the transmission of the force of the tooth 2 to the adapter 1. Will be.

Moreover, even in the special case of the advanced nose 5 in the hexagon, it is possible to adopt the latter without having to remove the material applied to the straight protrusions in the nose 5. In this way, the robustness of the nose 5 is not reduced and the number of edges of the steep slope is not increased, thus reducing the risk of stress concentration and having a simple but efficient geometry.

In the new coupling system, the protrusions are in tight contact and operate in a compressed state when the vertical stress acts on the assembly up or down.

Claims (18)

Teeth formed by the coupling of an adapter member fixed to a bucket or shovel of an excavator and a tooth member connected to the adapter member and fixed by a pin. As a coupling system, One of the members, preferably the tooth member, extends in the axial direction inside two rectilinear lugs parallel to each other and protruding from the mouse of the central housing, and also formed axially on the adapter member. Meshes with respective rectilinear open recesses; The adapter member has a cantilever projection engaged with the central housing of the tooth member; The tooth member protrusion has an inner surface consisting of a flat or arcuate curved surface in contact with the rear of the adapter member groove; The straight cross section of each of the straight protrusions of the tooth member has a concave shape, and is partially engaged with the convex side of the straight groove of the adapter member, and also has two end faces, and these two end faces Coupling system of digger teeth, characterized by converging to a central section distinct from these sections. The method of claim 1, And said two ends of said straight section of said tooth projection are coupled to said intermediate section at an angle between approximately 10 ° and 40 °. The method of claim 1, The intermediate section of the straight section of the tooth projection protrusion is curved, characterized in that the coupling system of the excavator teeth (teeth). The method of claim 1, Excavator teeth coupling system characterized in that the intermediate section of the straight cross-section of the tooth protrusion projection is a straight line. The method of claim 1, And said end section of each straight section of said tooth projection is exactly straight. The method of claim 1, The end of each straight cross section of the tooth protuberance is slightly curved. The method of claim 1, And wherein one of said end faces of each said straight section of said tooth projection is remarkably straight, while the other end is slightly curved. The method of claim 1, The straight section of the tooth projection is transversely symmetrical, whereby the two end sections of the straight section of the tooth projection have the same length and the projection angle of the two end sections at the intermediate section is the same for each of them. A coupling system of excavator teeth. The method of claim 1, The straight section of the tooth projection is asymmetric in the transverse direction, whereby the two end sections of the straight section of the tooth projection have different lengths and the projection angles of the two end sections at the intermediate section differ with respect to each of them. Coupling system of excavator teeth. The method of claim 1, Wherein the straight cross section of the tooth protrusion is asymmetrical and has a different projection angle from the two end faces of the same length in the intermediate cross section. The method of claim 1, And a straight cross section of the tooth projection is asymmetrical and has a projection angle equal to two end faces of different lengths in the intermediate cross section. The method of claim 1, Both projections of the tooth portion have an orifice positioned on the intermediate end or on one of the end faces, the orifice being in communication with the orifice crossing the cantilever projection of the adapter part. A coupling system of excavator teeth, characterized in that arranged. The method of claim 1, The two smaller sides of the straight section of the tooth projection are straight and remarkably parallel to each other. The method of claim 1, And said straight section of said two projections of the tooth portion is symmetrical. The method of claim 1, And said linear cross section of said two projections of said tooth portion is symmetrical with respect to a point. The method of claim 1, And said straight section of each projection of said tooth portion has the same width along its entire extension. The method of claim 1, And wherein said linear cross section of each projection of said tooth portion has one or more areas of reduced extension and has a width that differs from the general width. The method according to claim 9 and 11, The projection of the tooth portion, wherein the long end face is directed in the direction of the stress to withstand the stress.