ROCK-CUTTING TOOL AND METHOD FOR MINE AND OIL DRILLING

Abstract

The invention relates to a rock-cutting tool and a method for manufacturing this tool, which comprises knives comprising a layer of polycrystalline synthetic diamond (PSD), a diamond impregnation layer with diamond particles and bonding cobalt, characterized in that the PSD layer is supported directly, along a planar interface, on the diamond impregnation layer whose interface surface is planar by machining and with which the diamond particles are flush.

Claims

1. A rock-cutting tool with knives comprising: at least one front layer of polycrystalline synthetic diamond (PSD), and a rear diamond impregnation layer with diamond particles and bonding cobalt, wherein: the PSD layer is supported directly, along a planar interface, onto the rear diamond impregnation layer whose interface surface is planar by machining and on which the diamond particles are flush, and the flush diamond particles of the rear diamond impregnation layer are covalently bonded with the polycrystalline synthetic diamond.

2. The rock-cutting tool according to claim 1, wherein diamond impregnation layers and PSD layers alternate.

3. The rock-cutting tool according to claim 1, wherein the diamond particles of the diamond impregnation layer are distributed homogeneously and are not in contact with one another.

4. The rock-cutting tool according to claim 1, wherein the diamond impregnation layer comprises tungsten carbide.

5. A method for manufacturing a knife of a rock-cutting tool, the method comprising: preparing diamond pellets with a powder containing tungsten, carbon and cobalt; preforming a diamond impregnation layer by cold pressing said diamond pellets in a mold; sintering the preformed diamond impregnation layer to set the diamonds; machining the sintered diamond impregnation layer until obtaining a planar surface with flush diamonds; depositing a layer of diamond powder on said planar surface; and converting the layer of diamond powder into a layer of polycrystalline synthetic diamond (PSD) covalently bonded to said flush diamonds.

6. The method according to claim 5, wherein each pellet contains only one diamond particle.

7. The method according to claim 5, wherein sintering of the diamond impregnation layer is done by a hot isostatic method.

8. The method according to claim 5, wherein converting the layer of diamond powder into a PSD layer is catalyzed by cobalt.

9. The method according to claim 5, wherein the diamond impregnation layer is machined on several faces until obtaining planar surfaces with flush diamonds.

Description

The invention will be better understood using the following description of several embodiments of the invention, in reference to the appended drawing, in which:

[0021] FIG. 1 is a perspective schematic view of the tool according to the invention;

[0022] FIG. 2 is a perspective view of a knife of the tool of FIG. 1;

[0023] FIG. 3 is a perspective view of the diamond impregnation layer of the knife of FIG. 2;

[0024] FIG. 4 is a flowchart that schematically illustrates the method of the invention; and

[0025] FIG. 5 is a perspective view of an alternative embodiment of a knife of the tool according to the invention.

[0026] In reference to FIG. 1, a rock-cutting tool 1 has three blades 2 with four knives 3 at the free end of each blade. The tool 1 is intended to be rotated around its axis AA′. In reference to FIG. 2, each knife is made up of a front or forward layer 5 made from polycrystalline synthetic diamond (PSD) and a back or rear diamond impregnation layer 6 with diamond particles 7. In reference to FIG. 3, the front surface 8 of the rear layer 6, adjacent to the front layer 5, is planar and diamond particles 12 are flush therewith.

[0027] Oil drilling uses tools that dig a cylindrical hole. The tools used generally have a cutting head that rotates at a faster or slower speed in one direction. The tool 1 has three blades 2 that will be in contact with the rock formation to be drilled. In particular, the knives 3 will provide drilling of the rock formation.

[0028] The PSD layer 5 is very hard and forms the cutting edge that will first cut the rock formation. This layer 5 is, however, relatively brittle and is supported by a layer that is more resistant to mechanical stress.

[0029] Typically, a tungsten carbide support layer is used as a support, this material having excellent resistance to mechanical stress. However, tungsten carbide does not withstand abrasion well and wears out quickly in contact with rock, which reduces the lifetime of the PSD layer. Although a priori less resistant to mechanical stress, due to its biphasic nature, the diamond impregnation layer 6 here is used to support the PSD layer 5, which has at least two advantages: the diamond particles 7 present in a tungsten carbide matrix, also containing cobalt to guarantee the bonding of the assembly, increase the abrasion resistance of the support and actively participate in the drilling of the rock, on the one hand, and on the other hand, the presence of these diamond particles makes it possible to reduce the difference in thermal expansion coefficient between the support layer 6 and the PSD layer 5, which limits the mechanical stress that appears when the tool heats up to several hundred degrees during its rotation in contact with the rock. This results in a certain improvement in the lifetime of the tool.

[0030] The method used to manufacture knives 3 makes it possible to give them other advantageous properties.

[0031] In reference to FIG. 4, step 401 for granulating a powder 9 with diamond particles 7 results in diamond pellets 10 that are next molded and cold-compressed in step 402 for preforming the diamond impregnation layer This preformed layer is next subjected, in step 403, to sintering, at the end of which a diamond impregnation layer 11 is obtained. This layer 11 is next machined in step 404 until the surface 8 is made planar so as to expose flush diamond particles 12 therein. A layer of diamond powder 13 is deposited on the surface 8 in step 405, then a step 406 allows the conversion of the diamond powder 13 into a polycrystalline synthetic diamond 5.

[0032] The powder 9 used in step 401 comprises carbon, tungsten and cobalt. The granulation is done such that each diamond particle 7 is coated in a tungsten carbide matrix, the cobalt serving as binder, and even such that each pellet 10 contains only one diamond particle 7. The choice of the starting size of the diamond particles 7, as well as filtering tools subsequently used, determines the size of the pellets 10. The use of such pellets 10 makes it possible to obtain an excellent homogeneity of the distribution of the diamond particles 7 in the entire diamond impregnation layer 11. These particles 7 could even not touch one another, i.e., the average distance between two diamond particles 7 would be constant in the entire impregnation layer 11.

[0033] These pellets 10 are introduced into a mold, the shape of which corresponds to the desired shape of the diamond impregnation layer 11, then cold-compressed to preform this layer 11. The diamond impregnation layer is therefore a layer of tungsten carbide, containing cobalt, and in which diamond particles are distributed homogeneously.

[0034] The sintering step 403 consists of heating the powder 9 containing the carbon and the tungsten making up the pellets 10 without melting these elements. The heat makes it possible, however, to melt the cobalt, which is also present therein, in order to weld/bond all of the elements to one another. The cobalt plays a binding role here. Sintering techniques are well known in powder metallurgy. It is for example possible to carry out sintering by hot isostatic compression in a gaseous atmosphere (hipping), which makes it possible to obtain a dense layer 11, setting the diamond particles 7 in a reinforced way.

[0035] At this stage, the diamond particles 7 having been introduced in the form of “encapsulated” pellets, the surfaces of the impregnation layer 11 expose only tungsten carbide and cobalt. Before forming the PSD layer 5 on one of these surfaces, a machining step 404 is carried out in order to planarize this surface 8 and in order to make the diamond particles 12 set in the diamond impregnation layer 6 flush. The machining can for example be done by grinding or laser.

[0036] The machined diamond impregnation layer 6 can then be placed back in an appropriate mold where the diamond powder 13 is deposited on the machined face 8 of the layer 6 and where this diamond powder 13 is converted into PSD 5.

[0037] The conversion of the diamond powder 13 into a PSD layer 5 consists of forming covalent chemical bonds between carbon atoms coming from different diamond particles making up this powder 13, i.e., bonds that will weld the particles of the powder to one another to form a single so-called “polycrystalline” element. In this step, there is no addition of carbon, therefore no new diamond formation, but the bonding of a multitude of diamond particles to one another. This conversion generally takes place at a high temperature and requires a catalyst element, here cobalt. Cobalt can therefore be added to the diamond powder 13 to facilitate the reaction. This is not, however, necessary here, the pressure and temperature conditions used in the conversion step 406 being such that the cobalt contained in the diamond impregnation layer 6 can migrate toward the surface 8 and be used as a conversion catalyst 406. The cobalt used as binder in step 403 here plays a second role, that of catalyst. The homogeneity of the diamond impregnation layer 6 may be interesting to allow a homogeneous migration of the cobalt toward the entire surface where the diamond powder 13 has been deposited, in order to ensure the formation of a PSD that is also homogeneous and solid.

[0038] The conditions necessary for the conversion of step 406 are for example obtained by a high pressure-high temperature (HPHT) method that is well known in powder metallurgy.

[0039] During this conversion, not only will the particles of the diamond powder 13 bond to one another, but the bonds will also be able to form between the particles of the diamond powder 13 and the flush diamond particles 12 of the impregnation layers 6. The PSD layer 5 will therefore by very strongly moored to its support layer 6, owing to the machining layer that has made it possible to create flushness at the interface 8 between the two layers of diamond particles 12.

[0040] This gives the entire knife an additional resistance to mechanical stress, the PSD layer 5 not tending to separate from its support layer 6 under the effect of impacts or the increase in temperature during drilling. The lifetime of the tool is therefore significantly improved, as is its effectiveness faced with a wide variety of rock formations, both soft and hard.

[0041] Depending on the depth to be drilled as well as the nature of the rocks that will be encountered, the shape of the tool may be varied, as well as the shape and number of its blades. In some cases, it can be interested to use multi-layer blades 14 (FIG. 5), i.e., associated several alternating diamond impregnation layers, here the three layers 61, 62 and 63 with several PSD layers 51, 52 and 53.

[0042] The method for manufacturing these multi-layer knives 14 reiterates the same steps 401 to 406 previously described. Some of these steps can be multiplied. For example, the diamond impregnation layer 61 is machined on both of its contact faces with the PSD layers 51 and 52. The diamond impregnation layer 62 is also machined on both of its contact face with the PSD layers 52 and 53. Still more generally, the diamond impregnation layer can be machined on several faces until obtaining planar surfaces with flush diamonds.

[0043] In this multi-layer configuration, the PSD layers 52 and 53 are each supported on either side by two impregnation layers, which further strengthens their impact resistance. Each knife than has several cutting edges.

[0044] The knives described here have a cylindrical shape. It is nevertheless possible, depending on the configuration of the tool, to manufacture knives having various shapes that are more or less complex. The manufacturing method described here can use a wide variety of molds depending on the needs.