FR2752182A1 - Liquid spray nozzle for abrasive wheel of grinding machine - Google Patents

Abstract

The spray nozzle and rim clearer (10) is used for abrasive wheel for grinding (1) of boron nitride granules, for use on a grinding machine with five axes of freedom. It is made up of a curved form of which the section reduces from the entry end (11) whatever to a reduced section at the exit end (12). The concave wall (13) is an inwardly curved wall in a manner to globally marry up to the peripheral surface to be sprayed (U). The nozzle is characterised in that it contains lateral holes (15) on the concave surface (13) for projecting the lubricant onto the peripheral surface (2) of the abrasive wheel (1) in order to clear the latter.

Description

WATERING AND CLEANING NOZZLE FOR GRINDING WHEEL
RECTIFICATION
Wn v
DESCRIPTION
Field of the invention
The invention relates to the grinding of metal parts using abrasive wheels and, in particular, wheels with cubic boron nitride, called CBN wheels. It also relates to the machining and grinding of metal parts by means of machining centers with five axes of movement.

Prior art and problem posed
It is known to use grinders with cubic boron nitride to perform various grinding operations. Such grinding wheels are composed of abrasive grains produced artificially at a temperature above 1000 ° C. These grains are coated with a vitrified binder. The lifetime of such a cubic boron nitride wheel is often ten to one hundred times longer than that of a conventional wheel. Its hardness is generally twice that of a conventional corundum grinding wheel.

 The technique for using cubic boron nitride wheels is carried out under special conditions. In particular, the lubricant spray pressure is six times higher than that used by standard grinders. In addition, the machining conditions are relatively fixed, in particular concerning the advance of the table of the machine tool, the penetration depth and the peripheral speed of the grinding wheel between 60 and 100 m / s.

 On the other hand, the grinding machines using this type of grinding wheels must include special equipment, such as a spindle with high speed of rotation, multi-operation tools, watering nozzles of complex shape having to be adapted to the process of machining and at high speed and, finally, grinding nozzles.

 These watering, lubrication and scouring problems become more and more difficult depending on the complexity of the machining process, the number of phases and the different relative movements of the grinding wheel in relation to the part and the tool. of the grinding machine. Frequently, for each different operation, specific watering and cleaning equipment is provided and must be stored near the grinding machine so that it can be positioned on it when the time comes, for example by means of a robotic system.

 This is the case of so-called five-axis grinding machines, that is to say, the movement of the part relative to the tool can be carried out in five different ways among the six theoretical degrees of freedom. Figure 1 shows such a grinder.

It mainly comprises a frame 3 on which is mounted a table 4, movable in translation along a first horizontal axis X. On this table 4 is mounted a workpiece carrier 6 which can support a workpiece, the latter being able to rotate along a second axis horizontal A parallel to the first axis of translation X.

On the other hand, the frame 3 supports a column 7 mounted movable in translation along a third horizontal axis Z. On this column 7 is mounted movable in translation, along a first vertical axis Y, a spindle head 9 on which is mounted a spindle 8, movable in rotation about a second vertical axis B.

This spindle 8 carries the grinding wheel 1 driven in rotation about a third axis of rotation C perpendicular to the first two axes of rotation A and B. It is thus understood that the movements of the grinding wheel 1 around the workpiece can be numerous at during the same machining range. In addition, it should be noted that the point of contact between the grinding wheel and the workpiece can vary by several degrees, depending on the surface of the workpiece to be ground. Indeed, if it is curved, the contact point will rotate around the axis of curvature of the surface to be ground.

 FIG. 2 shows such a situation where the grinding wheel 1 is caused to run through a section of cylindrical surface 19 of a turbine distributor sector of a turboprop. The position of the grinding wheel 1 shown in broken lines shows the distance that the grinding wheel can travel and, thereby, the angle that can be made around the point P, center of the distributor, the contact point U between the grinding wheel 1 and the surface to be machined 19.

 It is thus understood that, the sprinkler nozzle being fixed for this type of operation, the path of the propelled fluid varies in length, from its exit from the nozzle 10 to the machining point U of the grinding wheel 1 on the surface 19.

 The invention aims to remedy these constraints due to the use of grinders with cubic boron nitride on grinders of the five-axis type.

Summary of the invention
To this end, the main object of the invention is a spraying and cleaning nozzle for a cubic boron nitride grinding wheel to be used on a five-axis grinding machine, comprising a portion of shaped pipe. general curved whose section decreases to pass from a section of any inlet end to a section of the outlet end reduced, the concave wall of the nozzle being a flat curved wall, so as to conform generally to the surface wheel peripheral to be lubricated and cleaned.

 For the purpose of cleaning, the nozzle includes lateral holes in the concave wall, so as to spray lubricant on the peripheral surface of the grinding wheel to remove the latter.

 In its main embodiment, the radius of curvature of the concave wall is greater towards the outlet end than towards the inlet end.

 Preferably, the section of the outlet end is elongated and the concave wall is planar and curved.

List of Figures
The invention and its various technical characteristics will be better understood on reading the following description, accompanied by four figures representing respectively
- Figure 1, already described, a five-axis type grinder on which the grinding wheel according to the invention is used;
- Figure 2, a diagram relating to the angular displacement of the machining point between the grinding wheel and the workpiece;
- Figure 3, in front section, the nozzle according to the invention installed during a rectification operation for which it is used;
- Figure 4, in detailed perspective view, the nozzle according to the invention.

Detailed description of an embodiment
Referring to Figure 3, the sprinkler and cleaning nozzle according to the invention 10 is shown in the operating position alongside a grinding wheel with cubic boron nitride 1. The latter is mounted to rotate about a horizontal axis to machine, or more precisely, rectify the surface 5S of a metal part 5.

 Taking into account the direction of rotation of the grinding wheel 1, represented by the arrow F, the nozzle 10 is placed before the machining point U which is at the tangential meeting of the grinding wheel 10 and the part 5.

The inlet end 11 of the nozzle 10 is at the top, so that the watering and cleaning fluid from the grinding wheel 1 descends into the nozzle 10, not only by gravity, but by means of pressure very high, six times higher than for watering ordinary grinding operations. The fluid opens out through the outlet end 12 tangentially to the surface 2 of the grinding wheel 1, at this location. This outlet end being angularly offset from the machining point U, the direction of ejection of the fluid at the outlet end is not, strictly speaking, in the exact direction of this machining point U. Nevertheless, the speed of rotation of the grinding wheel (at least 60 m / s on the periphery of the grinding wheel) and the pressure of projection of the fluid make it sucked against the surface 2 of the grinding wheel 1 by a vacuum due to this high speed of rotation and by the air flows in the vicinity of the grinding wheel 1. As indicated by the small arrows, the fluid therefore tends to remain very close to the surface 2 of the grinding wheel 1 and is sucked between the latter and the part 5 towards the machining point U, where this fluid must do its function of watering and lubrication.

 In this FIG. 3, side holes 15 have also been shown on the concave wall 13 of the nozzle 10 for expelling a portion of the fluid directly against the surface 2 of the grinding wheel 1. They are practically perpendicular thereto. Given the speed and pressure of the fluid in the nozzle 10, the ejection force of the latter against the surface 2 of the grinding wheel 1 by the side holes 15 is such that the fluid has a relatively significant impact effect against this surface 2. The result obtained on this surface 2 of the grinding wheel 1 is a cleaning of the points of this surface 2 before they carry out a new abrasion operation at the machining point U.

This also makes it possible to carry out the vacuum of air, between the grinding wheel 1 and the nozzle 10, facilitating a better trajectory of the coolant.

 As can be seen, the angle of curvature of the nozzle, that is to say of the concave wall 13 and possibly of the convex wall 14 is a little smaller towards the inlet end 11 than towards the outlet end 12. This is an exemplary embodiment, but is particularly suitable in the position of use of the nozzle 10 shown in FIG. 3. Indeed, a large angle of curvature of the concave wall 13 towards the end of outlet 12 of nozzle 10 makes it possible to tangent this outlet end 12 in a relatively fine and precise manner with respect to the grinding wheel 1.

 FIG. 4 shows better the arrangement of the lateral holes 15 on the concave wall 13. The number of lateral holes 15 is not limited to eight, as in this FIG. 4.

 The outlet end 12 therefore consists of a longitudinal slot because the concave 13 and convex 14 walls are flat curved surfaces. In other words, the different sections of the nozzle 10 are rectangular. This is an example of realization. However, this embodiment is particularly suitable when the surface 2 of the grinding wheel 1 is a cylindrical surface. It is conceivable that the concave wall 13 of the nozzle 10 could be of a shape complementary to that of the peripheral surface 2 of the grinding wheel 1.

 Similarly, a side wall 16 has been shown, making the junction between the concave 13 and convex walls 14. This side wall 16 is planar. This is also only an example of an embodiment.

 It is thus understood that the nozzle according to the invention allows both efficient watering of the machining point U of the grinding wheel 1 on the part 5 and a cleaning of the metallic particles stuck on the grinding wheel 1.

 The tangential arrival of the fluid at the outlet of the nozzle 10 allows optimal watering at high peripheral speeds of the grinding wheel 1.

 Obviously, with its tapered profile and its lateral positioning, the nozzle according to the invention makes it possible to avoid risks of collision between the nozzle 1 and the tools of the grinding machine.

 In other words, the position of the nozzle according to the invention is dependent on the position of the grinding wheel 1. More precisely, it is possible to provide that the position of the nozzle 10 is fixed relative to the position of the grinding wheel, in all its movements in relation to the workpiece, the table and the machine tool. Indeed, in traditional methods, the nozzle is fixed on the machine tool or on the table thereof and is therefore relative movements relative to the grinding wheel. On the other hand, the nozzle 10 according to the invention being pressed against the grinding wheel 1, it has very little chance of undergoing contact or impact with a tool of the machine tool, these tools not having to approach the grinding wheel 2 Thus, the position of the nozzle 10, according to the invention, is not changed and the direction and orientation of the jet of cleaning and watering fluid is never changed.

 We can consider different shapes of nozzles adapted to different shapes of grinding wheels.

 The fact that the fluid jet arrives tangentially on the surface 2 of the grinding wheel 1 allows the machining point U to vary angularly, since this jet is practically glued to the surface 2 of the grinding wheel 1 and arrives almost entirely at this point. machining point U whatever the distance separating this machining point U from the end 12 of the nozzle 10.

Claims (4)

 1. Watering and cleaning nozzle (10) for a grinding wheel (1) with cubic boron nitride to be used on a five-axis grinding machine, mainly consisting of a portion of generally curved pipe, the section decreases to pass from any inlet end section (11) to a reduced outlet end section (12), the concave wall (13) being a curved wall, so as to conform generally to the peripheral surface (2) of the grinding wheel (1) to be watered.  2. Nozzle according to claim 1, characterized in that it comprises lateral holes (15) on the concave wall (13) for projecting lubricant onto the peripheral surface (2) of the grinding wheel (1), in order to clean this last.  3. Nozzle according to claim 1, characterized in that the radius of curvature of the concave wall (13) is greater towards the outlet end (12) than towards the inlet end (11).  4. Nozzle according to claim 1, characterized in that the concave wall (13) of the nozzle (10) is planar and curved, the section of the outlet end being elongated.