CH568815A5 - - Google Patents

Description

  

  
 



   The present invention relates to a device for holding a workpiece to be ground on a machine using the centerless method. Such a device is arranged to drive a part to be ground and to support the latter by its peripheral surface, as is the case for example for a device of the type with two rollers and a shoe used in a centerless machine for grinding the interiors. .



   One of the conventional devices of this kind used until now comprises an assembly of two drive rollers and a shoe, which supports a workpiece to be ground at the peripheral surface thereof and which maintains the radial position of this piece. , orifices being arranged directly in front of one of the end surfaces of the part to be ground and a jet of oil ejected through these orifices pressing this part axially against a fixed plate and thus maintaining the axial position of the part.



   However, with this direct pressing method, especially in the case of a workpiece having an extremely small side surface area, such as for example a miniature ball bearing part, the force which presses this part in the axial direction becomes relatively small so that a sufficient axial holding effect cannot be obtained, which causes many problems in the precision of grinding grinding. In addition, this direct pressure method requires a high pressure hydraulic supply arrangement, 30-50 kg cm2.



   A device of the oblique roller type is also known which uses two rollers and a shoe. With this method. which provides an axial holding force of the workpiece to be ground by the fact that at least of the two rollers is oblique, each of the rollers only comes into contact with the workpiece to be held at one point, so that, at Apart from the disadvantage consisting in that the driving force of the workpiece by the rollers is lower and proves to be insufficient for a strong grinding, there is still the disadvantage of having to adjust the inclination of the rollers to obtain a force of stable axial support.

  The part which must undergo a rectifying grinding of its interior is, in this case, not held by reference to its external diameter, but by reference to one of its end surfaces, so that if the end surfaces of this part do not have a finish grinding oriented exactly at right angles to the axis of the part, the bore of this annular part is corner ground.



   In another method which uses a magnetic holding device, the finished part must be demagnetized after grinding, and in addition, the grinding dust adheres to the machine due to the magnetic flux, so that the machine is scratched; moreover, it is impossible with such a magnetic device to hold a part to be ground having only very weak magnetic characteristics, as is the case, for example for stainless steel. On the other hand, when it is desired to grind workpieces having a diameter smaller than 10 mm, the contact area of the workpiece with the magnetic surface becomes very small so that it is more difficult to hold it in position. correct and the precision of grinding decreases significantly.



   The object of the present invention is to provide a device for holding a part for centerless grinding, which is free from the aforementioned defects, and with which in particular it is easier to machine or grind extremely small parts with precision. by carrying out strong grinding passes if necessary.



   According to the invention, the device for holding a part to be ground according to the centerless method is characterized in that it comprises means for supporting said part on its peripheral surface, means for driving this part, a front plate arranged to provide a sliding support at one end of this part and having an opening to allow passage of a grinding wheel, a support element having a bore and a cylindrical chamber coaxial with this bore, a tip surface located at the other end of said part being parallel to
 the bearing surface of the front plate, and an axial bearing rotor
 under pressure disposed in said bore of the support member of
 so as to be able to move in rotation with said part and to
 be able to slide axially in said bore, this rotor being
 provided,

   on the side opposite to that which it directs towards said room, with a
 part which fits into said cylindrical chamber and which is
 intended to receive a fluid pressure for the transmission of
 which ducts open into said chamber. games
 existing between the sliding cooperation surfaces of the rotor and of the cylindrical chamber being dimensioned with respect to said
 conducted in such a way that said rotor is moved axially with
 a suitable fluid agent.



   The part is thus held in a stable and firm manner,
 correct axial position, using axial pressure
 by a fluid agent, such as oil, air, an oil mixture
 or coolant, this pressure being transmitted to
 the part to be held by means of the rotor. This rotor is
 therefore pressed by fluid pressure or hydraulic pressure against
 the part to be ground which rests at its other end against the
 faceplate, the rotor moving moreover in rotation with
 this part to be rectified, which is thus maintained
 stable and firm manner in the correct axial position.

  The game (or
 air gap) between the rotor and the cylindrical wall of the chamber is
 made wide enough for the hydraulic fluid to
 flow adequately to the outside while maintaining the
 pressure imparted to the rotor at the desired value to maintain
 correctly and firmly the workpiece without disturbances
 produced during the rotation of the rotor.



   Advantageously, said rotor comprises a coaxial bore
 crossing and has recesses in its surface intended to
 come into contact with the part to be ground, a buffer gauge
 coaxial with said part when the latter is in position
 machining being planned so that it can move axially
 ment through said rotor bore to check the dimension
 of the rectified bore in said part.



   In this way, the device has the advantage of allowing
 to control the inside diameter of the part directly during
 grinding or grinding operations. Said hollows
 allow the hydraulic fluid that is in the chamber
 cylindrical to escape to a greater extent during
 gauging process, and thus the axial movement of the gauge
 becomes softer, the pressure acting on the rotor being
 naked to an adequate value since this liquid is not subject to
 confinement in the cylinder (without this measurement the pressure of the
 liquid in the cylindrical chamber would increase or decrease
 in response to the axial movement of the gauge, which movement
 itself would be bothered by the presence of this liquid).



   We also note that abrasive grains and waste are
 always mixed with the liquid spilled out of the device, liquid
 which must be collected again in order to be used again as a liquid
 hydraulic to exert the desired pressure on the rotor. In a device using such a circulation of liquid, it would seem to be necessary, and, in the absence of special measures, it
 would indeed be necessary, that the hydraulic arrangement
 includes a premium filter, resistant to high
 pressures, very closed in texture, and therefore of a high price, likewise
 than a high power pump capable of overcoming the effect of resistance to flow exerted by such a filter.



   In an advantageous embodiment of the invention, therefore, advantageous technical measures are also provided concerning this question, and it proposes to use a hydraulic arrangement comprising a low pressure pump which delivers the liquid to an inexpensive filter, and a high-pressure pump to then pressurize the filtered liquid and thus deliver it to the device for holding the part to be ground with sufficient pressure and in the purified state. This hydraulic arrangement can also serve as a cooling arrangement.



   The accompanying drawing illustrates, by way of example, forms of exe
 cution of the object of the invention; in this drawing:
 fig. 1 is a side view of an embodiment in
 which the holding assembly of the part according to the method
 centerless is mounted on an interior grinding machine,
 fig. 2 is a front view of the device of FIG. 1.



   fig. 3 is a sectional view through some elements
 forming part of the device according to FIGS. 1 and 2,
 fig. 4 is a schematic view, partially in section according to
 line IV-IV of fig. 3,
 fig. 5 is a sectional view similar to FIG. 3 illustrating a
 other embodiment, and
 fig. 6 is a diagram of a hydraulic arrangement with which the device in question is provided.



   To facilitate understanding of the device which will be described,
 it is advantageous to first consider the nomenclature of the main elements referenced in the drawing. It looks like this:
 5 .. lower feed roller
 9 .. upper feed roller
   19 workpiece (to be ground)
 21 faceplate
 22 support element (support plate
 for pressurized arrangement)
   25 hoof
   27 .. ..... opening for grinding wheel penetration
 28 .... bore
 29 .... pressurized support rotor
 30 oil release holes
 31 .............. part receiving pressure
   32.. cylindrical chamber
 33 ..... gauge guide bush
 35. . . . . . . . .

  . gauge
 Considering fig. 1 to 4, which represent a first embodiment of a device for holding a part to be ground according to the centerless method, it can be seen that this device comprises a base I on which is mounted a block 2, a shaft 4, integral with a pulley 3 at one of its ends, being supported in a movable manner in rotation in the block 2, the axis of this shaft 4 being parallel with the axis of a grinding wheel 26 which will be mentioned later. A lower drive roller 5 is attached to the other end of the shaft 4, and a roller shaft 7 is supported parallel to the roller shaft 4 by a block 6 placed higher than the block 2.

  A pulley 8 is fixed to one end of the shaft 7, while an upper drive roller 9 is mounted at the other end of this shaft in alignment with the lower drive roller 5. Said block 6 is mounted. on an end portion of an adjustment arm 10, itself supported in an adjustable manner on a rocking arm 12 mounted on a pivot 11 fixed to a projecting part 1 'of the base 1. An adjustment screw 13, screwed through the front face of the block 6, abuts by its point against the front end of the arm 12 to adjust the position of the upper roller 9 according to the dimensions of the part to be ground.



   A bolt 14 is provided for mounting said adjustment arm 10 on the rocking arm 12. The other end of this arm 12 is drawn downwards by a spring 15; a cam follower 17 is mounted at the end of said arm 12 connected to the spring, this cam follower 17 being maintained in contact with a rotary cam 18 by the action of the spring 15.



   At the lower mouth 20 'of a slide 20 for supplying parts to be ground, there is disposed a guide path 23 for these parts, this path being formed horizontally between a front plate 21 forming part of the device for holding the parts. and a support plate 22 which will be described later. One end of this guide path 23 is open in the grinding position a, between the lower and upper rollers 5 and 9.



  A loading push plate 24 conveys the workpieces 19 from the lower mouth 20 'to the grinding position a, this plate being slidably inserted in the guide path 23 and moving in a synchronized manner with it. the movement that the upper roller 9 performs under the control of the cam 18.



   It can also be seen that a shoe 25, in contact with the periphery of the workpiece 19 and forming part of the elements specifically intended for holding this workpiece, is placed at the grinding location a just below the outlet. guide path 23.



   Figs. 3 and 4 show the detailed construction of the retaining elements of the workpiece to be ground, elements which characterize the particular construction described above. An opening 27 for the passage of a grinding wheel 26 is formed in the face plate 21 just opposite the grinding position a of the workpiece 19; the parts of the part 21 located at the edge of the opening 27 and which are in contact with the part 19 have a wear resistant finish.



   The support member 22 for the pressure arrangement has a bore 28 formed in correspondence with said opening 27 of the face plate 21, the axis of the bore 28 coinciding with the axis of the opening 27. A cylindrical part 29 'of a pressure bearing rotor 29 is inserted in said bore 28 so as to be mounted therein rotatably and slidably in the axial direction. This rotor is supported in the bore in the manner of a plain bearing, and it can be seen that recesses 30 for the discharge of oil are formed in the front surface of the rotor 29 for entry. contact with the workpiece and press against it.

  Furthermore, a rim portion 31 is formed at the end of the peripheral surface of the rotor 29 opposite its bearing surface against the part 19, this part 31 being intended to receive the pressure controlling the axial movement of the rotor and located in a cylindrical chamber 32 formed in the support member for the pressurized arrangement 22. A clearance space d1 remains between the cylindrical wall of the chamber 32 and the peripheral surface of the flange 31 of the rotor 29; this clearance (or air gap) controls the passage of the oil which can escape thereby from the chamber 32 through an exhaust duct. This chamber 32 is closed, due to its particular configuration, by a gauge guide sleeve 33 and a block 34.



   It can also be seen that a buffer gauge 35 is slidably and rotatably mounted in a central bore 33 'of the guide sleeve 33, which makes it possible to directly gauge the internal dimension of the part 19 to be ground, said gauge 35 being formed to fit into the rectified bore of the part 19 through the cylindrical portion 29 'of the pressure bearing rotor 29.

  An advanced and thinned portion 33 "of the gauge guide sleeve 33 is located in the cylindrical portion 29 'of the rotor 29, a space (or clearance, or air gap) d2 for controlling the passage of the oil being provided between the end 33 "of the guide sleeve and a cylindrical inner surface of the rotor 29; this space d2 is wider than the space d1 previously mentioned between the periphery of the rim 31 of the rotor and the surface of the pressurized arrangement support member 22. Oil inlet and outlet channels 36 and 37 are provided. in the support member 22 and the block 34. The channel 36 is connected to an oil passage 38 formed annularly at the periphery of the gauge guide sleeve 33, and this path 38 is connected to the chamber cylindrical 32 via an oil supply duct 39 passing through said sleeve.

   The oil outlet channel 37 is for its part connected to the cylindrical chamber 32 by a duct C.



   As shown in fig. 4, said support member of the pressurized arrangement 22 has a stepped part 22 ', that is to say that, on the part situated to the right of the vertical central axis L perpendicular to the axis of the part to be rectified in the grinding position a, this member 22 advances further than on the part situated to the left of this axis. Thus, when the rotor 29 is withdrawn, its front surface still exceeds the surface of the left part of the support plate 22 while it is already set back from the surface of the right part of this member 22.



   In fig. 1, we can still see at 40 the discharge slides for the finished parts 19.



   The dimension relation concerning the spaces d1 and d2 which controls the oil escape as the rotor advances, the supply duct 39 and the supply duct C connected to said outlet channel 37 through which pressure arrives when the rotor withdraws, as well as the oil discharge duct b opening said cylindrical chamber 32 outwardly, is suitably determined so that the movements of said axial bearing rotor under pressure are effected rapidly.



   The operation of the device is as follows: a workpiece 19, introduced by the slide 20, is transferred to the grinding (or grinding) position a between the lower and upper drive rollers 5 and 9 using the loading pusher blade 24, as shown in FIG. 1.



  When the part is in the grinding position, the upper roller 9 is lowered, due to a rotation of the cam 18, to come to engage with pressure against the periphery of the part to be ground, so that this part 19 is held firmly at three points, by the drive roller 5, the drive roller 9 and the shoe 25.



   Under these conditions, if each of the rollers is rotated, in an anti-clockwise direction, by the action of a motor, the part to be ground 19 will move in rotation in the clockwise direction and it will come to rest at the same time. time against the shoe 25. When pressurized oil is brought into the annular chamber 32, through the oil inlet 36, the annular space 38 and the oil supply duct 39, the hydrostatic pressure generated by the pressurized oil in the cylindrical chamber 32 is applied to the pressure receiving part 31 of the rotor 29, which moves it forward and presses its front surface against the workpiece 19 which thus undergoes a strong thrust axial and is pressed against the front plate 21. This piece to be ground 19 is thus maintained and positioned correctly.

  In synchronism with the establishment of this firm positioning, the grinding wheel 26 is inserted through the opening 27 of the face plate 21 to come to rectify by grinding the inner surface of the workpiece 19.



   The pressurized oil conducted from the inlet channel 36 into the chamber 32 provides an axial compressive force to the rotor 29, and at the same time a part of this pressurized oil is conducted, as coolant and coolant. lubrication of the grinding, up to the part 19 from the chamber 32 through the space d2; on the other hand, the pressurized oil is discharged through the outlet channel 36, and also through the discharge pipe b passing through the clearance space d1.



   When the rotor 29 is pressed towards the workpiece, pressurized oil also penetrates, as lubricant, into the bearing portion for the rotor 29, so that the rotation of this rotor at the same speed that the part to be ground can be done smoothly.



   When a particular specified grinding has been accomplished on the workpiece, the gauge 35 is moved forward, the gauging portion 35 'being inserted into the ground bore of the workpiece 19 to perform a direct sizing check. At this moment, the ground bore of the part 19 is closed by said gauge, but oil passage recesses 30 are provided in the end surface of the rotor 29 so that the oil confined in the cylindrical chamber can discharge through these oil passage hollows and does not influence the direct gauging of the ground part.



   When this part has been ground (or rectified) to the desired size, the supply of pressurized oil is stopped in the inlet channel 36, the pressurized oil being on the other hand brought through the channel 37 into the chamber. 32. As a result, the rotor retracts and its end surface separates from the workpiece.



  Simultaneously, the upper drive roller 9 moves away from the periphery of the workpiece, and a new workpiece 19 is brought into the grinding position a between the two rollers, by the action of the pusher plate 24. which causes it to advance from the bottom of the slide 20. The introduction of the new part to be rectified drives the finished part which is pushed into the discharge slide 40 by the new part in place. The aforementioned operations are repeated cyclically and the parts to be ground are ground (ground) and checked as having the desired size in an automatic and continuous manner.



   Fig. 5 shows an embodiment in which the correct holding in place of the part to be ground is not effected by the pressure bearing rotor 29 taking as reference the end surface of the part to be ground, but is done by taking the peripheral surface of the part to be ground as a reference, by means of lower and upper drive rollers 5 'and 9' which each have a sufficiently large width to fulfill this role of reference. With the latter process, precise internal grinding as well as hard grinding can be performed on parts to be ground of a certain length, even if none of the end surfaces of the parts to be ground have a ground finish condition. .



   Fig. 6 represents the diagram of the hydraulic arrangement with which the device defined above is provided in conjunction with FIGS. 1 to 4 (as well as the variant according to fig. 5). 41 shows the grinding machine on which the workpiece holder is mounted, and 47 an oil reservoir for oil which has been used as hydraulic fluid to apply pressure to the rotor and as lubricant and coolant
 The reservoir 47 is provided with a magnetic debris separator 48, and the oil is sucked out of this reservoir by a low pressure pump 49, in order to be led to a filter 50. The latter consists of a kind of filter. closed and inexpensive paper. The output of this filter 50 is connected, through a valve A, to a high pressure pump 51 which raises the pressure of the oil, for example up to 10 kg / cm2.

  The output of this high pressure pump 51 is connected, by an assembly comprising a directional control valve 52 and flow control valves 53a and 53b, to said inlet and outlet channels 36 and 37 of the device. The oil line between said high pressure pump 51 and said directional control valve 52 is further equipped with a safety valve (or relief valve in the event of overpressure) 55, as well as a pressure gauge 56.



   Once it has been used as a hydraulic pressure agent, lubricant, or coolant, the oil flows back into reservoir 47 through separator 48 and is again sent to filter 50 through the low-pressure pump 49. As a result, all abrasive grains and other residual waste likely to be in the oil are removed therefrom by the closed filter. The filtered oil is then sucked in and its pressure is again raised to the appropriate value by the high pressure pump 51.



   As the filter 50 is placed between the low pressure pump 49 and the high pressure pump 51, the differential pressure between the inlet and the outlet of this filter is sufficiently low that it is possible to use an inexpensive filter. of the paper filter type.



  The life of the filter is therefore extended and in addition, it is not necessary to resort to a filter housing of great strength, resistant to high pressures.



   In the situation shown in FIG. 6, the directional control valve 52 conducts pressurized oil to the inlet channel 36 through the flow control valve 53a. The oil which, in a way, overflows from the hydraulic action device, reaches the part to be ground where it acts, as previously indicated, as lubricant and coolant; then, this oil returns to the reservoir see 47. The oil which comes out of the outlet channel 37 also returns, via the valve 53b and the valve 52, to the reservoir 47 (the return line between the valve 52 and the reservoir 47, however, has not been drawn in Fig. 6).



   In the embodiments described, the device for holding the workpiece to be ground is of the type with two rollers and a shoe, but it is clear that one could also use, to hold the part to be ground in place by its periphery. and to move the latter in rotation, another drive arrangement, for example the already known arrangement which comprises three rollers.



   Using the particular device described above, in which a pressurized axial bearing rotor is rotatably and slidably mounted in a support member, the workpiece is subjected to an axial holding force provided by said rotor, so that the construction of the device is simple and that its cost is low in comparison with the devices using the conventional hydrostatic bearing method.

  It is on the other hand possible, with the device described, to rectify or grind parts having only a small end surface, and, moreover, the arrangement providing the fluid pressure used for advancing and retreating. the pressurized axial bearing rotor does not need to be a very high pressure arrangement, since the pressure required may be only of the order of 10 kg / cm2; thus, the lubricating or cooling liquid for grinding can be used as the hydraulic fluid, the lubricant (or the cooling agent) and the hydraulic fluid can therefore constitute a single common fluid.



   It should also be noted, with regard to direct gauging by the automatic buffer gauge method, that the oil passage recesses in the surface of the rotor coming into contact with the part to be ground make it possible to prevent, when direct gauging is carried out, the gauging operation is hampered by the pressurized fluid.



   As long as the hydrostatic pressure applied to the pressurized back-up rotor has an appropriate value, it is possible to grind (grind) parts not only according to the method in which the end surfaces of the part to be ground are used as a reference , but also according to the method with which the periphery of the part to be ground is used as a reference.



  Thus, precise interior grinding can be performed even if both end surfaces of the part have a poor finish condition; it is also possible to perform a strong grinding (encountering great resistance, with a great depth of cut), or to grind longer pieces to be ground, by widening the two rollers and strengthening the friction action against the piece to be rectified to drive it in rotation.



   Furthermore, in the device described, given that well-specified values are given to the ratios of the areas of constriction of the ducts through which the fluid can reach and leave the cylindrical chamber in which the portion of the rotor intended to receive the pressure is located. of fluid, it is possible to quickly move the rotor backwards; and, since a stepped portion is formed in the support plate for the arrangement under pressure, the loading and unloading of workpieces can be performed in a safe manner, which is also an appreciable advantage.

 

Claims (1)

CLAIM Device for holding a part to be ground on a machine according to the centerless method, characterized in that it comprises means for supporting said part on its peripheral surface, means for driving this part, a front plate arranged to provide support sliding at one end of this part and having an opening to allow passage of a grinding wheel, a support element having a bore and a cylindrical chamber coaxial with this bore, a tip surface located at the other end of said part being parallel to the bearing surface of the front plate, and a pressurized axial bearing rotor arranged in said bore of the support element so as to be able to move in rotation with said part and to be able to slide axially in said bore, this rotor being provided, on the side opposite to that which it directs towards said part, of a part which fits into said cylindrical chamber and which is intended to receive a fluid pressure for the transmission of which conduits open into said chamber, of the clearances existing between the sliding cooperation surfaces of the rotor and of the cylindrical chamber being dimensioned with respect to said conduits such that said rotor is moved axially with a suitable fluid medium. SUB-CLAIMS 1. Device according to claim, characterized in that said rotor comprises a coaxial through bore and has recesses in its surface intended to come into contact with the part to be ground, a buffer gauge coaxial with said part when the latter is in contact. machining position being provided so as to be able to move axially through said bore in the rotor to control the size of the ground bore in said part. 2. Device according to claim or sub-claim 1, characterized in that it further comprises a hydraulic control arrangement comprising a reservoir collecting the liquid used to press said rotor, a filter for said liquid collected after use, a pump. at low pressure sucking this liquid out of the reservoir to bring it into said filter, a set of valves comprising flow control valves and a directional control valve for returning said liquid under pressure to said rotor, and a high pressure pump pressure arranged to pass said filtered liquid from said filter to said set of valves.