Abstract:
The invention pertains to a deburring tool for deburring the interior and/or exterior of work pieces, for example, abutting edges on intersecting bores or on longitudinal and transverse grooves in bores or on transverse bores in a deep-hole bore with different diameters of an engine block, tubular work piece ends, edges on and in flat work piece surfaces or surfaces of a toothed wheel or a sprocket wheel. The deburring tool can be used in machine tools and is pressure-controlled. The cutting forces can be variably adapted to the burr dimensions that change during the machining process and to different materials. Corresponding embodiments of the deburring tool ensure the deburring of different work pieces with a good quality and in a short period of time. The inventive deburring tool is particularly advantageous in that it can be used in intermittent assembly lines with the latest manufacturing technologies.

Description:
BACKGROUND OF THE INVENTION 
   The invention pertains to a deburring tool for deburring the interior and/or exterior of work pieces, for example, abutting edges on intersecting bores or on longitudinal and transverse grooves in bores or on transverse bores in a deep-hole bore with different diameters of an engine block, tubular work piece ends, edges on and in flat work piece surfaces or surfaces of a toothed wheel or a sprocket wheel, as well as to a corresponding method. During its intended use, the deburring tool is moved in a rotatory or translatory fashion, wherein the deburring tool comprises a tool shaft that has a clamping end and an end with in inner support member and at least one blade member with a cutting edge that is movably arranged in an opening. 
   A deburring tool for deburring abutting edges in bores is known from the state of the art, namely DE 43 07 084 C2. This deburring tool is characterized in that the cutting edge is subjected to a radially exerted spring force by the support member that is seated in the central recess and consists of an elastomer material, wherein the blade member that is movably guided in an opening has a support surface, by means of which it is supported on the support member. Once a certain force is exceeded, the cutting edge yields in a springable fashion. It is also possible to accommodate the support member in the recess with a certain prestress. Due to the support on the support member, the blade member is able to carry out movements that should allow an effective deburring, namely also of interior abutting edges. A combined radial and axial guide is provided for the deburring tool. The axial component is intended to simplify the insertion into the bores of the work piece, and the axial movement of the deburring tool is transformed into a radial movement of the blade member due to the design of the corresponding support surface of the opening. In order to make it possible to carry out the required movements, the support member can also be adapted to the respective requirements by choosing the shape, the material and the material quality accordingly. The support member has the shape of a pyramid, a truncated pyramid, a cone, a truncated cone, a prism, a sphere or a cylinder. However, the required movements can also be realized with a combination of a correspondingly shaped support member and a correspondingly shaped recess. The recess is preferably realized in the form of a truncated cone, a prism or a cylinder. Such shapes are also is chosen for the design of the opening. A limitation of the blade member travel in order to prevent a radially outward directed movement thereof is achieved by providing the blade member with a so-called leg for supporting the blade member on the inner surface sections of the recess that are situated laterally of the opening. The decisive disadvantage of the deburring tool disclosed in DE 43 07 084 C2 can be seen in the fact that, when the deburring tool is inserted into the bores, the cutting edge(s) adjoin the bore wall with the spring force exerted by the support member and consequently produce tracks that cannot be measured, but rendered visible with light-optical methods. Such tracks are particularly undesirable, for example, in reamed bores in the engine block. Another disadvantage is that the support member has to be exchanged each time the material of the work piece to be processed changes. Such an exchange of the support member is extremely difficult, in particular, with smaller tool diameters, e.g., on the order of 2 mm. 
   All known deburring tools also have the disadvantage that they cannot adapt to burr dimensions that change during the machining process due to the increasing wear of the burr-producing tools. When using a new tool, i.e., a tool that is at the beginning of its useful life, the burr being produced during the machining of the work piece is still small. However, the size of the burr can increase 10-times by the time the tool reaches the end of its useful life. The dimensions of known deburring tools currently are invariably based on the burr dimensions at the end of the tool life. This causes gradually changing chamfers to be produced on the parts of the work piece to be deburred. Another important aspect is that known deburring tools frequently can only be used for deburring a work piece or parts of a work piece, e.g., for the interior deburring of abutting edges in bores or on transverse bores of a work piece or for the exterior deburring of edges on work piece surfaces. It is disadvantageous that these deburring tools frequently require a high manufacturing expenditure and do not make it possible to achieve the short deburring times required in modern intermittent assembly lines. In addition, there is currently no deburring tool or deburring system available on the market which can be universally utilized for the deburring of work pieces, for example, abutting edges on intersecting bores or on longitudinal and transverse grooves in bores or on transverse bores in a deep-hole bore with different diameters of an engine block, tubular work piece ends, edges on and in flat work piece surfaces and on surfaces of a toothed wheel or a sprocket wheel. 
   Consequently, the invention is based on the objective of developing a deburring tool for the interior and/or exterior deburring of work pieces of the initially described type which adapts the cutting forces to burr dimensions that change during the machining process and to different materials, wherein said deburring tool can be manufactured with a low expenditure, allows a simple handling of smaller tool diameters and ensures a high-quality deburring of work pieces of different geometric shapes and sizes within the short cycle times achieved in modern intermittent assembly lines. 
   BRIEF SUMMARY OR THE INVENTION 
   According to the invention, this objective is attained with a deburring tool with the characteristics of independent claim  1 . The play of the blade member that is movably supported on the surface of the support member is chosen such that the cutting edge(s) do not fall inward at a pressure p=0 bar. This means that the cutting edge(s) are reliably guided in the tubular shaft section and do not adjoin the bore surface with a force F higher than zero Newton. An exact guidance of the cutting edge is achieved in that the blade member comprises a blade center section with a cutting edge, a radial, lateral limitation of the cutting edge travel and a radial limitation of the cutting edge travel on the side of the face, respectively, or a cylindrical limitation of the cutting edge travel. 
   It is advantageous that the cutting edge(s) do not produce any visible tracks in the bore wall when the deburring tool is inserted into the bore. The differently designed surfaces of the support member and the blade member with respect to their shapes and dimensions result in a constant surface differential that, in turn, invariably causes an outward movement of the cutting edge(s) in dependence on the pressure. The surfaces of the support member and the blade member may be realized rectangular, triangular, cylindrical or prismatic, wherein the surfaces may be arranged parallel or non-parallel referred to the longitudinal axis of the tool shaft. In addition, the blade member supported in the opening of the tubular shaft section has such dimensions that only a minimal pressure drop occurs during the deburring process, and that a more intense pressure drop is ensured while the deburring tool is inserted and removed. The medium pressed into the through-bore of the tool shaft under pressure may consist of a liquid or gaseous medium or of a liquid/gas mixture and causes the cutting edge(s) to move outward. In this case, the pressure p on the blade member surface should always be higher than the atmospheric pressure and lower than 500 bar, preferably between 4 and 60 bar. Drilling emulsions, drilling oils or a mixture or other mediums suitable for cooling and/or lubricating purposes may be considered as liquid mediums. The supply is realized via the existing hollow work spindles of machine tools, but also via a separate connection on the support or on the machine tool. Gases such as, for example, welding gases, inert gases, compressed air or carbon monoxide may be considered as gaseous mediums. It would also be conceivable to introduce a liquid/gas mixture such as, for example, air that contains 10-15 percent admixed drilling oil. 
   For example, when deburring abutting edges on a transverse bore in an engine block, a pressure p of 3 bar needs to be programmed on the machine tool control before the deburring tool is inserted into the bore. While the tool is inserted into the bore, the cutting edges that lie outside the tool shaft are moved inward. This opens up partial regions of the opening and the liquid or gaseous medium pressed into the through-bore of the deburring tool is able to escape. As the cutting edge is inserted into the transverse bore, it is moved outward by the pressure created due to the surface differential between the support member and the blade member. A certain force that can be used for the deburring process is now being exerted. A more precisely controlled introduction of the medium into the through-bore of the tool shaft can be achieved for the deburring of smaller bore diameters below 4.5 mm if the tubular shaft section of the deburring tool is connected to the tool shaft by an internal setscrew that extends through the through-bore transverse to the longitudinal axis, wherein the core diameter D 1  of the internal setscrew is smaller than the diameter D 3  of the through-bore and its diameter D is equal to the diameter of the through-bore. The internal setscrew also contains a groove in the region of the through-bore, and its and on the side of the shaft section is realized in a conical fashion with an angle α&lt;10 degrees. It is advantageous that the pressure p can be increased in a programmed fashion as the burr dimensions increase due to the wear of the drill, namely in dependence on the material and the quantity drilled. It would even be conceivable to advance the deburring tool to the base of the burr on the transverse bore to be deburred in an unpressurized fashion. 
   The deburring tool according to the invention can be easily handled, namely even when using small tool diameters. This is achieved, among other things, because no exchange of the functional components is required. In addition, tests have demonstrated that the deburring tool can be utilized for deburring uneven bore openings. In such instances, the radial plane or parts of this plane are, for example, inclined at the point at which the tool emerges. The deburring of abutting edges on larger transverse bores with a diameter larger than 3 mm is currently still problematic because the productivity cannot be increased by increasing the advance/cutting speed and the quality of the deburring result becomes inferior. It can be ascertained that the cutting edges are arranged on the blade members in the tubular shaft section and lie in the openings such that they are distributed over the circumference of the shaft section, wherein the area of contact does not extend over the entire cutting edges. The cutting edges of the deburring tool are also arranged in one plane viewed in the axial direction. The proposed embodiment of the deburring tool is characterized in that at least two openings are arranged closely adjacent to one another in the tubular shaft section in a radially symmetric fashion and offset relative to one another in the axial direction by a distance m. However, the openings in the tubular shaft section may also be arranged asymmetrically. The distance m is always smaller than the advance of the cutting edge. A high-quality deburring result can advantageously be achieved within an extremely short period of time because a larger number of a cutting edges are now in direct contact. The rotational speed of the deburring tool can be increased to &gt;2000 rpm at the same pressure ratios. This means that the deburring tool fulfills the prerequisites for use in intermittent assembly lines that utilize the latest manufacturing technologies. 
   Another embodiment of the deburring tool according to the invention now also makes it possible to simultaneously deburr abutting edges on intersecting bores with different diameters in a deep-hole bore. This means that additional deburring tools are no longer required. For this purpose, the tubular shaft section of the deburring tool which contains the centrally arranged through-bore and carries a deburring unit on its end is extended with another deburring unit that has a smaller diameter such that a step is formed, wherein the end of the deburring unit with the smaller diameter which is situated on the side of the work piece consists of a small closing plate in the form of a screw which is realized integrally with the support member. Depending on the respective requirements, the diameter of the tubular shaft section may contain several steps, wherein a deburring unit of identical constructive design is arranged after each step. In order to deburr the tubular ends of a work piece, devices and tools are known from the state of the art which remove burrs on the end of cylindrical pipes along the inner edge as well as the outer edge. A device for simultaneously deburring the inner edge and the outer edge of a cylindrical pipe is disclosed in DE-OS 26 58 344. 
   The device is realized in the form of a rotationally symmetrical pipe deburring head and consists of an attachment piece with a bore that can be attached to a drive axle of a lathe, as well as a sleeve, in the interior of which two pairs of tools are arranged such that they can be axially displaced relative to one another by means of a pressure medium, for example, compressed oil. If a pipe to be deburred on the outer edge and the inner edge is inserted into the pipe feed opening of the deburring head, both tool pairs can be uniformly pressed against the inner edge and the outer edge of the pipe by increasing the force that axially acts upon the pipe. According to this publication, a simultaneous deburring of both pipe edges should be achieved by rotating the pipe deburring head. The disadvantages of the device disclosed in DE-OS 26 58 344 are that it requires a high manufacturing expenditure and can only be used for simultaneously deburring the inside contour and the outside contour of a cylindrical pipe. These disadvantages are eliminated with the deburring tool according to the invention. For this purpose, the deburring tool needs to be modified in such a way that the tool shaft with the clamping end and the shaft end on the side of the tool are realized integrally with the through-bore, that the shaft end has the shape of a hollow cylinder, that a section of the hollow cylinder which surrounds the tubular end of the work piece to be processed contains in the through-bore several cylindrical blade members with cutting edges that point in the direction of the longitudinal axis, wherein the cylindrical blade members are distributed over the circumference and arranged in the opening, and that the blade members adjoin the conical support members with a certain play, wherein the support members are rigidly connected to and positioned by the small closing plates. The small closing plates seal the ends of the through-bore of the section in a pressure-tight fashion such that the proper function of the deburring tool is ensured. In addition, the inside diameter D 4  of the section is larger than the outside diameter of the tubular end of the work piece. In order to simultaneously deburr the interior and exterior of work piece ends, a complete deburring tool with several cutting edges that are distributed over the circumference and point in the direction of the surrounding section of the hollow cylinder needs to be inserted into the hollow cylinder. The inserted deburring tool and the hollow cylinder are connected to one another in a pressure-tight fashion by means of a screw connection that forms an extension of the through-bore. The diameter D 5  of the deburring tool is smaller than the inside diameter of the tubular work piece end to be deburred. 
   Another embodiment of the deburring tool ensures that edge burrs on and in flat surfaces of a work piece, for example, a sheet metal processed with a perforating tool or a punched sheet metal, can be rapidly removed in a cost-efficient fashion without damaging the surface. This deburring tool is characterized in that the tool shaft is rotatable and provided with a cylindrical connecting piece with a larger diameter on the shaft end on the side of the tool, wherein the connecting piece comprises a centrally arranged support member that has the shape of a spherical cap and at least four circularly arranged, offset through-bores for connecting elements that serve for mounting the shaft section, and wherein the shaft section contains in its end face several circularly arranged openings for accommodating the blade members with the cutting edges. The blade members with the cutting edges may also be arranged in the openings in a spiral-shaped fashion or in a plane that lies parallel to the end face of the shaft section. The connecting piece may also comprise a support member in the form of a truncated cone that is arranged in an axially oblique fashion or a cylindrical support member with oblique grooves machined therein which is arranged in an axially oblique fashion. 
   In addition, it is possible to utilize the deburring tool according to the invention for deburring exterior surfaces of a toothed wheel or a sprocket wheel. In this context, the invention discloses a corresponding method that fulfills the requirements for the deburring of toothed wheels and sprocket wheels in modern intermittent assembly lines. According to this method, the deburring tool is, after having been advanced toward the work piece, guided in a controlled fashion in the radial direction f 1  and in the axial direction f 2  in accordance with the shape of the work piece to be processed and/or linearly referred to the work piece with a certain advance, namely with a pressure &gt;3 bar, wherein the work piece simultaneously rotates in the clockwise and/or counterclockwise direction with a speed &gt;100 rpm. The aforementioned method is also characterized in that the advance per revolution of the work piece lies between 0.01 and 0.3 mm, preferably between 0.05 and 0.2 mm. It is possible to simultaneously utilize several deburring tools for this purpose. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention is described in greater detail below with reference to embodiments that are illustrated in the figures. The figures show: 
       FIG. 1 , a section through a deburring tool according to the invention; 
       FIG. 2 , a section through another embodiment of the deburring tool; 
       FIG. 3 , a section through another variation of the pre-deburring tool; 
       FIG. 4 , a section through a radial, lateral blade member support; 
       FIGS. 5   a - 5   e,  different variations of the support of the blade member on the support member, namely in the form of sections along the line A-A in  FIG. 4 ; 
       FIGS. 6   a  &amp;  6   b,  blade member variations on the face side in the form of sections along the line B-B in  FIG. 4 ; 
       FIG. 7  a top view of  FIG. 6 ; 
       FIGS. 8   a  &amp;  8   b , respective side view of  FIGS. 6   a  &amp;  6   b;    
       FIG. 9 , a longitudinal section through another embodiment of the deburring tool; 
       FIGS. 10   a - 10   g , side views and top view of round blade member receptacles with different variations of the cutting edge and the shoulder; 
       FIG. 11 , a section through another connection between the shaft section and the tool shaft; 
       FIG. 12 , a variation of the internal setscrew shown in  FIG. 11 ; 
       FIG. 13 , a section through the new connection between the shaft section and the tool shaft; 
       FIG. 14 , a longitudinal section through another embodiment of the end of the internal setscrew on the side of the shaft section which is shown in  FIG. 13 ; 
       FIG. 15 , a longitudinal section through the internal setscrew shown in  FIG. 13 ; 
       FIG. 16 , a bore with two different diameters and two transverse bores in a work piece; 
       FIG. 17 , a corresponding deburring tool; 
       FIG. 18 , a special variation of the end of the deburring tool according to  FIG. 17  on the side of the work piece; 
       FIG. 19 , a section through a deburring tool for deburring the outer edge of tubular ends of a work piece; 
       FIG. 20 , a section through a deburring tool for simultaneously deburring the outer edge and the inner edge of tubular ends of a work piece; 
       FIG. 21 , a sectioned side view of a deburring tool for deburring flat surfaces; 
       FIG. 22 , the end face of the shaft section of the deburring tool according to  FIG. 21 ; 
       FIG. 23 , another variation of the end face of the shaft section of the deburring tool according to  FIG. 21 ; 
       FIG. 24 , a section through an advanced deburring tool for deburring the exterior of a toothed wheel; 
       FIG. 25 , a section through an advanced deburring tool for deburring the exterior of a sprocket wheel, and 
       FIGS. 26   a  &amp;  26   b , a top view of a tubular shaft section with three openings and a section view through the tubular shaft section along the line C-C. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
     FIG. 1  shows a longitudinal section through a deburring tool according to the invention. One can ascertain that a rigid bearing in the form of a conical support member  6  is arranged on the shaft end  5  on the side of the tool. The tubular shaft section  11  is connected to the tool shaft  1  by means of a connecting element  13 , for example, a threaded stem and a guide, and holds two rectangular blade members  21  with a radial, lateral limitation  18  of the cutting edge travel, wherein said blade members are movably supported in the opening  10  and loosely adjoin the surface of the support member  6  with a play  8  of at least 0.05 mm. A pre-deburring tool  9  in the form of grooves is arranged on the end face of the tubular shaft section  11 . This pre-deburring tool  9  is used for deburring materials with a high extensibility, e.g., steel. In this case, the grooves are arranged at an angle of 45 degrees and have a depth of 0.5 mm and a width of at least 0.8 mm. The pre-deburring tool  9  may also consist of a hollow screw with slots. If drilling oil is introduced into the through-bore  12  with a pressure p via the medium connection  14  that may be realized in the form of a thread or core hole, a pressure is built up on the blade members  21  which causes the cutting edge(s)  3  realized with a shoulder  23  to move outward. The through-bore  12  is arranged in the tool shaft  1  centrally referred to the longitudinal axis  4  up to the end of the support member  6 . However, the through-bore could also be arranged asymmetrically. Once the pressure p is reduced to zero bar, the cutting edges  3  move toward the surface of the support member  6 . Most machine tools are equipped with a coolant and lubricant supply that is realized via their work spindles and can be programmed with a CNC control. The arrangement of the deburring tool in a work spindle with a medium supply makes it possible to control the pressure p in dependence on path and time. Consequently, the cutting forces of the deburring tool can be variably adjusted as a function of the pressure such that different materials can be easily deburred with the deburring tool according to the invention. It is also possible to compensate increasing burr dimensions caused by the wear of the corresponding tool by increasing the pressure in a time-controlled fashion. In addition, a combination with means for measuring the burrs would be conceivable. A medium connection  14  and an adapter  20  for extending the tool shaft  1  on demand are provided on the end of the tool shaft  1  on the side of the machine. The tubular shaft section  11  has a width across flats  15  in order to rapidly and easily install the deburring tool. 
     FIG. 2  shows another embodiment of the deburring tool in the form of a section, wherein two conical blade members  21  adjoin the cylindrical support member  6  with a play  8  and thusly ensure a radial, lateral limitation  18  of the cutting edge travel is ensured. The tubular shaft section  11  is connected to the tool shaft  1 , for example, by means of dowel pins  16  in this case. A diaphragm  28  in the form of a through-bore is arranged in the end face of the shaft section  11 , wherein this diaphragm not only makes it possible to lower the pressure in the deburring tool, but can also be used for cleaning the bore surface, as well as for blowing off oil and/or chips. A pressure reduction can also be achieved if the through-bore  12  in the tool shaft  1  has a blind-hole bore with a radial outlet. In other respects, this embodiment contains no other modifications in comparison with the deburring tool shown in  FIG. 1 . 
     FIG. 3  shows another embodiment of the pre-deburring tool  9  in the form of a section. One can ascertain that a small closing plate  17  provided with several grooves is arranged on the end face of the tubular shaft section  11 . 
     FIG. 4  shows a section through a radial, lateral blade member support in the unpressurized state, in which the bearing play  8  is equal to zero. The surface of the support member  6  and the surface of the rectangular blade member  21  directly adjoin one another in a loose fashion. One can also ascertain that the tubular shaft section  11  accommodates the blade member  21  with the cutting edge  3  that is movably supported in the opening  10 . In order to ensure the proper function of the deburring tool, it is important that twice the length L 2  of the projection of the blade member  21  relative to the support member  6  is smaller than or equal to the length L 1  of the blade member  21 , that the thickness d of the blade member  21  is smaller than the wall thickness a of the tubular shaft section  11 , and that the thickness d of the blade member  21  is larger than the height c of the cutting edge. If these constructive characteristics for the radial, lateral limitation of the cutting edge support are not observed, the cutting edge(s)  3  tilt away toward the inside such that the deburring tool is unusable. 
     FIG. 5  shows different variations of the support of the blade member  21  on the support member  6  in the form of sections along the line A-A in  FIG. 4 . These variations of the blade member support elucidate the required surface differential between the support member  6  and the blade member  21  in order to ensure the movement of the cutting edge(s) under a pressure p. 
     FIG. 6  shows two blade member variations on the face side in the form of sections along the line B-B in FIG.  4 . The blade member  21  has a cutting edge  3  with a height c and a width b of less than 0.5 mm. This figure also shows the shoulder height  24  that is smaller than or equal to the height c of the cutting edge. The shoulder angle δ is particularly important with respect to smaller transverse bores with diameters of less than 2 mm. It is advantageous to reduce the shoulder angle δ to 5-45 degrees. When deburring larger transverse bores, this shoulder angle may, however, also be larger than 45 degrees. This allows an unobstructed deburring of the transverse bores. 
     FIG. 7  shows a top view of  FIG. 6  with a shoulder  23  and a recess  22  that may be realized differently with respect to the depth C 1 . This makes it possible to reduce the time required for the movement of the cutting edge under pressure and the cutting edge automatically moves into the starting position. The shoulder  23  absorbs the laterally acting blade member forces and frictional force such that fractures of the cutting edge are prevented. 
     FIG. 8  shows a side view of  FIG. 6 . The surfaces F 1 , F 2 , F 3  of the cutting edge  3  define the clearance angle a of zero degrees. This angle is particularly favorable for achieving an effective deburring of transverse bores, wherein the deburring tool operates in the clockwise direction while it is advanced and in the counterclockwise direction while it is retracted. All known deburring tools have a clearance angle a that is larger than zero degrees on the active cutting edges and consequently are only able to deburr in one direction. This means that new burrs as they are frequently produced during the deburring process cannot be removed in the same production step. The deburring tool according to the invention is able to remove a possibly produced new burr (secondary burr) when it is retracted. Another characteristic of the cutting edge  3  is that the surfaces F 1 , F 2 , F 3  are always arranged parallel to the x-axis and the y-axis. The cutting edge  3  is also provided with a radial limitation  19  of the cutting edge travel on the face side. The tilting angle γ of the cutting edge  3  is larger than zero degrees and prevents damages on the work piece surfaces, for example, on the bore wall, during the deburring process. 
     FIG. 9  shows a longitudinal section through another embodiment of the deburring tool. In this case, the tool shaft  1  is connected to the tubular shaft section  11  by means of three setscrews  16  that are offset on the circumference of the shaft section  11  by 60 degrees. The through-bore  12  is arranged in the tool shaft  1  centrally referred to the longitudinal axis  4  up to the middle of the cylindrical support member  6 . Two bores  26  extend directly in the direction of the cutting edges  3  from the end of the through-bore  12  in the support member  6 . The blade center section  7  holds the cutting edge  3 , is realized round or with two laterally arranged surfaces and movably supported in the opening  10  of the shaft section  11 . 
     FIG. 10  shows side views and top views of several round blade member receptacles with different variations of the cutting edge  3  and the shoulder  23 . The variations in a) and b) are illustrated in the form of side views, wherein a) shows a cylindrical limitation  27  of the cutting edge travel with a blade center section  7  and the directly adjacent cutting edge  3 . The blade center section has a flat  25  that serves as a turning safety. This flat is not provided in b). The blade member receptacles in c), d), e), f) and g) are illustrated in the form of top views, wherein c) shows two cutting edges  3  and two milled shoulders  23 , and wherein d) shows two cutting edges and two bored shoulders. The blade member receptacle illustrated in e) is provided with serrated edges and suitable for deburring bores in castings. The cutting edges are able to better compensate the casting tolerances. The blade member receptacle illustrated in f) has two cutting edges and two shoulders, wherein the cutting edges and the shoulders and not realized parallel referred to the axial center. In the blade member receptacles illustrated in e) and f), the shoulder and the cutting edge may alternate because the arrangement is not fixed by means of a flat. This means that a sort of self-fixing effect in accordance with the conditions on the burr is achieved. The round blade member receptacle illustrated in g) is realized with asymmetrically arranged cutting edges and shoulders. 
     FIG. 11  shows a section through a different connection between the tubular shaft section  11  and the tool shaft  1 . This connection is characterized in that at least two internal setscrews  29  extend through the shaft section  11 , through the tool shaft  1  and into the through-bore  12  transverse to the longitudinal axis  4 . The internal setscrews  29  may also end at the through-bore  12 . The position of the internal setscrews  29  defines the cross-sectional size of the through-bore  12 . Consequently, the flow rate of the medium pressed into the through-bore  12 , as well as the pressure p on the blade member surfaces, can be varied in a controlled fashion. 
     FIG. 12  shows an embodiment of the internal setscrew  29  according to  FIG. 11 . The end of the internal setscrew  29  on the side of the through-bore contains at least one transverse bore  30  that ensures a flow in all positions of the internal setscrew  29  and thusly is able to function as a throttle/diaphragm. A bore  28  that acts as a throttle/diaphragm may also be provided in the longitudinal direction of the internal setscrew  29 . This makes it possible to reduce the pressure in the radial direction of the deburring tool. All known cooling and lubricating systems for machine tools are designed for high pressures and do not allow a fine adjustment within the lower pressure ranges around, for example, 3 bar used in the deburring of aluminum or cast-iron castings. This is the reason why the deburring tool has several options for reducing the pressure, wherein said options can be selectively utilized depending on the respective application. The diameter of the end  31  on the side of the shaft section is smaller than the outside diameter of the internal setscrew  29 , and its length is shorter than the wall thickness a of the shaft section  11 . The transition from the end  31  on the side of the shaft section to the outside diameter of the internal setscrew  29  is advantageously realized in a spherical or conical fashion. For example, a hexagon socket  32  for a hex key is arranged in the end on the side of the shaft section in order to simplify the installation and the operation. The hexagon socket  32  may also be replaced with a slot or a cross recess. 
     FIG. 13  shows a section through the new connection between the shaft section and the tool shaft. One can ascertain that the tubular shaft section  11  is connected to the tool shaft  1  by means of an internal setscrew  29  that extends through the through-bore  12  transverse to the longitudinal axis  4 . The internal setscrew  29  contains a groove  33  in the region of the through-bore  12 . 
     FIG. 14  shows a longitudinal section through another embodiment of the end of the internal setscrew on the side of the shaft section. The end  31  of the internal setscrew  29  on the side of the shaft section is realized in a conical fashion, wherein the angle α is &lt;10 degrees. This makes it possible, among other things, to prevent damages on the bore wall and to achieve an improved compensation of the tolerance of the internal setscrew referred to the blade member that is movably supported in the opening. A hexagon socket  32  is provided on the end  31  on the side of the shaft section for installation purposes. 
     FIG. 15  shows a longitudinal section through the internal setscrew according to  FIG. 13 . A reliable deburring of extremely small bore diameters such as, for example, 2.8 mm is possible if the diameter D 3  of the through-bore  12  of the tool shaft  1  is larger than the core diameter D 1  of the internal setscrew  29  and the diameter D 3  of the through-bore  12  and the diameter D of the internal setscrews  29  are identical. If these dimensions are observed, the medium pressed into the through-bore  12 , e.g., compressed air, is able to reach the cutting edges in an unrestricted fashion. 
     FIG. 16  shows a bore with two different diameters d 0 ; d 1  and with two transverse bores d quer  in a work piece. This means that the deburring tool needs to have two different diameters in order to deburr these abutting edges on the transverse bores. 
     FIG. 17  shows a deburring tool that is realized in the form of a stepped tool for deep-hole bores and comprises deburring units A and B for deburring the abutting edges on the intersecting bores with the diameters d 0 /d quer  and d 1 /d quer  in the work piece according to  FIG. 16 . The deburring unit A with the diameter M 3  deburrs the abutting edges on the intersecting bores with the diameters d 0 /d quer , and the deburring unit B with the diameter M 2  deburrs the abutting edges on the intersecting bores with the diameters d 1 /d quer . Both deburring units A; B contain the same base part in the form of a tubular shaft section ( 11 ) with a centrally arranged through-bore ( 12 ). The diameter M of this base part may, if so required, be stepped several times, wherein an analogous deburring unit is arranged after each step. 
     FIG. 18  shows a special variation of the end of the deburring tool on the side of the work piece according to  FIG. 17 . This figure shows a small closing plate  17  in the form of a screw that is realized integrally with the support member  6 . The tool shaft  1  is connected to the tubular shaft section  11  by means of a pin  16 . The proper function of the deburring tool is ensured by the play  8  provided between the support member  6  and the tubular shaft section  11 . This special variation of the end of the deburring tool on the side of the tool ensures a linear pressure supply such that, among other things, the efficiency of the deburring tool is decisively improved. 
     FIG. 19  shows a section through a deburring tool for deburring the outer edge of tubular ends of a work piece. One can ascertain that the tool shaft  1  with the clamping end  2  and the shaft end  5  on the side of the tool which has the shape of a hollow cylinder are realized integrally with the inner through-bore  12 . The section  35  of the hollow cylinder surrounds the tubular end of the (not-shown) work piece to be processed and contains in the through-bore  12  several cylindrical blade members  21  that are distributed over the circumference and arranged in the opening  10 , wherein the blade members contain cutting edges  3  that point in the direction of the longitudinal axis  4 . The ends of the through-bore  12  of the section  35  are sealed in a pressure-tight fashion with small closing plates  17 . The blade members  21  that adjoin the conical support member  6  with a play  8  can be positioned accordingly by rigidly connecting the support member  6  to the small closing plates  17 . It is important for the proper function of the deburring tool that the inside diameter D 4  of the section  35  is larger than the outside diameter of the tubular end of the work piece to be processed. 
     FIG. 20  shows a section through a deburring tool for simultaneously deburring the outer edge and the inner edge of tubular ends of a work piece. For this purpose, the deburring tool shown in  FIG. 19  can be rapidly and easily modified in such a way that a complete deburring tool  36  is inserted into the hollow cylinder  5 . The deburring tool  36  has several cutting edges  3  that are distributed over the circumference and point in the direction of the surrounding section  35  of the hollow cylinder. The hollow cylinder  5  and the deburring tool  36  are connected by means of a screw connection  37  that forms an extension of the through-bore  12 . In order to achieve the simultaneous deburring of the inner edges and outer edges of tubular ends of a work piece, the diameter D 5  of the deburring tool  36  needs to be smaller than the inside diameter of the tubular end of the work piece. 
     FIG. 21  shows a sectioned side view of an embodiment of a deburring tool for deburring edge burrs on and in flat surfaces of a work piece. In this figure, the end  5  of the tool shaft  1  on the side of the tool is rigidly connected to a cylindrical connecting piece  34  of larger diameter, wherein the connecting piece  34  comprises a centrally arranged support member  6  that has the shape of a spherical cap and four circularly arranged through-bores that are offset by 90° and serve for accommodating setscrews  16  for mounting the shaft section  11 , the end face of which contains several openings  10  for accommodating the blade members  21  with the cutting edges  3 . These blade members are arranged in the openings  10  in a plane that lies parallel to the end face of the shaft section  11  such that the cutting edges  3  deburr like a milling cutter and are particularly suitable for the deburring of large flat surfaces. 
     FIG. 22  shows the end face of the shaft section of the deburring tool according to  FIG. 21 . One can ascertain that the end face of the shaft section  11  contains eight circularly arranged openings  10  and four circularly arranged through-bores that are offset by 90° and serve for accommodating the setscrews  16  for mounting the shaft section  11  on the connecting piece  34 . 
     FIG. 23  shows another variation of the end face of the shaft section of the deburring tool according to  FIG. 21 . The end face contains four circularly arranged setscrews  16  that are offset by 90° and four openings  10  for accommodating the blade members with the cutting edges. 
     FIG. 24  shows a section through an advanced deburring tool for deburring the exterior of a toothed wheel. After the toothed wheel has been set into a clockwise rotation with a speed of 120 rpm, the deburring tool  36  is linearly guided in a controlled fashion toward the toothed wheel in the radial direction f 1  with a pressure of 5 bar and advanced by 0.07 mm per revolution of the toothed wheel. When the deburring tool is retracted, the deburring is carried out with the same rotation of the toothed wheel in the counterclockwise direction. This makes it possible to deburr an addendum of 4 mm in less than 50 seconds independently of the toothed wheel diameter. 
     FIG. 25  shows a section through an advanced deburring tool for deburring the exterior of a sprocket wheel. The sprocket wheel rotates in the clockwise direction with a speed of 200 rpm. The deburring tool is guided in a controlled fashion in the radial direction f 1  and in the axial direction f 2  such that it follows the shape of the sprocket wheel with a pressure of 4 bar and advanced by a distance that was determined to be 0.07 mm per revolution of the sprocket wheel in the advance as well as the retraction mode. The depth of the teeth of the sprocket wheel lies at 60 mm. The time required for deburring  36  teeth including the addendum and dedendum circles is approximately 45 seconds. The method according to the invention may also be used for simultaneously deburring the exterior of several sprocket wheels if two deburring tools are arranged offset to one another. This would make it possible to simultaneously deburr several tooth profiles such that the deburring time is additionally reduced. 
     FIG. 26  shows a top view of a tubular shaft section  11  with three openings  10  that are offset by 0.1 mm in the axial direction. In the section C-C through the tubular shaft section  11 , one can ascertain that six openings  10  are actually arranged radially symmetrical in the tubular shaft section  11 , wherein three openings  10  respectively lie closely adjacent to and opposite of one another. The openings  10  accommodate the not-shown blade members with the cutting edges. In such an arrangement of the openings  10 , three cutting edges are in direct contact and three cutting edges are in indirect contact. The axial offset by the distance m makes it possible to increase the total advance per revolution of the deburring tool to 0.6 mm. 
   LIST OF REFERENCE SYMBOLS 
   
       
         1  Tool shaft 
         2  Clamping end 
         3  Cutting edge 
         4  Longitudinal axis 
         5  Shaft end on the side of the tool 
         6  Support member 
         7  Cylindrical blade center section 
         8  Bearing play 
         9  Pre-deburring tool 
         10  Opening 
         11  Tubular shaft section 
         12  Through-bore 
         13  Connecting element (threaded stem and guide) 
         14  Medium connection 
         15  Width across fiats 
         16  Connecting element (setscrew, pin, dowel pin) 
         17  Small closing plate 
         18  Radial, lateral limitation of the cutting edge travel 
         19  Radial limitation of the cutting edge travel on the face side 
         20  Adapter 
         21  Blade member 
         22  Recess 
         23  Shoulder 
         24  Shoulder height 
         25  Flat 
         26  Bore 
         27  Cylindrical limitation of the cutting edge travel 
         28  Diaphragm/throttle 
         29  Internal setscrew 
         30  Transverse bore 
         31  End on the side of the shaft section 
         32  Hexagon socket 
         33  Groove 
         34  Connecting piece 
         35  Section 
         36  Deburring tool as a unit 
         37  Screw connection 
       a Wall thickness of the shaft section  11   
       b Width of the cutting edge 
       c Height of the cutting edge 
       C 1  Countersinking depth 
       d Thickness of the blade member  21   
       f Width of the shoulder  21   
       L 1  Length of the blade member  21   
       L 2  Length of the projection of the cutting edges—relative to the support member 
       F 1  Surface of the cutting edge  3   
       F 2  Surface of the cutting edge  3   
       F 3  Surface of the cutting edge  3   
       A Deburring unit 
       B Deburring unit 
       M General diameter of the shaft section  11   
       M 2  Smaller diameter of the shaft section  11   
       M 3  Larger diameter of the shaft section  11   
       D Diameter of the internal setscrew  29   
       D 1  Core diameter of the internal setscrew  29   
       D 3  Diameter of the through-bore  12   
       D 4  Inside diameter of the section  35   
       D 5  Diameter of the deburring tool  36   
       f 1  Advance in the radial direction 
       f 2  Advance in the axial direction