JP5432079B2 - Tool runout detection method - Google Patents

Description

  The present invention relates to a tool runout detection method.

  2. Description of the Related Art Conventionally, there are machine tools that perform workpiece cutting using a tool mounted on a rotary shaft. In this type of machine tool, vibration may occur on the rotating shaft during workpiece machining.

  As a technique for suppressing vibration of a rotating shaft that occurs during machining of a workpiece, a vibration suppressing device that calculates an optimum rotational speed capable of suppressing chatter vibration and rotates the rotating shaft at this optimum rotational speed is known ( Patent Document 1).

JP 2009-101495 A

  Among the machine tools described above, there are models having a plurality of rotating shafts. In such a machine tool, a tool may be exchanged on the other rotary shaft while the workpiece is being cut on one rotary shaft. Tool replacement work is frequently performed. On the other hand, since high machining accuracy is required for machine tools, tool mounting accuracy is periodically measured (hereinafter referred to as tool runout detection). Tool shake detection is an operation to detect how much the tip of the tool is shaken, and the amplitude (amount of shake) at the tip of the rotated tool is detected by a non-contact sensor.

  In the work of detecting the tool runout, while the work of detecting the runout of the tool is performed on one rotary shaft, the work of exchanging the tool may be performed on the other rotary shaft. In this case, the vibration generated in the tool replacement operation may affect the measurement result of the tool shake detection. The vibration suppressing device described in Patent Document 1 suppresses chatter vibration that occurs during rotation of a rotating shaft in cutting, and suppresses the influence of vibration that occurs during tool replacement work. Is not considered.

  In a machine tool having a plurality of rotating shafts, the present invention provides a tool replacing operation when tool runout is detected on the other rotating shaft while the tool replacing operation is performed on the other rotating shaft. It is an object of the present invention to provide a tool runout detection method that is less susceptible to the influence of vibrations generated in the above.

  (1) A tool runout detection method in a machine tool including at least two rotating shafts (for example, a processing spindle 36 described later) to which a tool can be detachably attached, and the tool replacement operation on one rotating shaft And a vibration waveform detecting step for detecting a vibration waveform generated by the replacement work, a frequency specifying step for specifying a frequency with the largest vibration based on the detected vibration waveform, and a frequency higher than the specified frequency A scan time setting step for setting a frequency range period as a scan time for performing the vibration detection of the tool, the tool replacement operation on one of the rotating shafts, and another one of the rotating shafts A tool run-out detecting method for detecting run-out of the tool according to the set scan time while rotating the tool.

  According to the invention of (1), the vibration waveform generated when the tool replacement operation is performed is detected, the frequency with the largest vibration is specified, and the period of the frequency region higher than the specified frequency is set in the tool. Set as scan time when shake detection is performed. According to this, it is possible to set a scan time that is not easily affected by vibrations that occur when the tool T is exchanged on one rotary shaft. Therefore, when the vibration of the tool mounted on the other rotating shaft is detected during the set scan time while the tool is being replaced on one rotating shaft, Can be less affected by

  (2) The tool runout detection method according to (1), wherein in the scan time setting step, the scan time when the runout detection of the tool is performed at a frequency cycle that is at least three times the specified frequency. Tool runout detection method set as

  According to the invention of (2), the period of at least three times the specified frequency is set as the scan time when the tool runout detection is performed. According to this, the influence of the vibration which generate | occur | produces in the replacement | exchange operation | work of a tool can be made harder to receive.

  According to the present invention, in a machine tool provided with a plurality of rotating shafts, when tool runout detection is performed on the other rotating shaft while the tool is being exchanged on one rotating shaft, It is possible to provide a tool runout detection method that is less affected by vibrations generated in the exchange work.

1 is a partially cutaway perspective view of a machine tool according to an embodiment. It is a front view of a machine tool. It is a side view of a machine tool. It is a side view of a tool magazine. It is a perspective view of a tool pot. It is a front view of a tool magazine. It is a perspective view of a tool delivery mechanism. (A) is a side view of a tool delivery mechanism. (B) is a side view which shows the state which lowered | hung the hand of the tool delivery mechanism from the state shown to (A). (A) is a top view which shows typically the notch vicinity of a tool magazine. (B) is a front view of (A). (C) is a side view of (A). (A) is a top view which shows typically the notch vicinity of a tool magazine. (B) is a front view of (A). (C) is a side view of (A). (A) is a top view which shows typically the notch vicinity of a tool magazine. (B) is a front view of (A). (C) is a side view of (A). It is a block diagram which shows the structure of the tool run-out detection system in embodiment. It is a graph which shows the vibration waveform detected by the position detection sensor during exchange of a tool. It is the graph which extracted the frequency component from the detected vibration waveform. It is a flowchart which shows the process sequence in the case of performing a tool run-out detection in a controller.

  Hereinafter, an embodiment of a tool runout detection method according to the present invention will be described in detail with reference to the accompanying drawings. Here, a case where the tool runout detection method according to the present invention is applied to a machine tool including two machining spindles 36 will be described.

  FIG. 1 is a partially cutaway perspective view of a machine tool 10 according to the present embodiment. FIG. 2 is a front view of the machine tool 10 shown in FIG. FIG. 3 is a side view of the machine tool 10 shown in FIG. Hereinafter, in order to specify the direction of the machine tool 10, the left-right direction in FIG. 2 is defined as the X direction (X1, X2 direction), and the height direction is defined as the Y direction (Y1, Y2 direction). Further, a depth direction orthogonal to the X direction and the Y direction is defined as a Z direction (Z1, Z2 direction) (see FIG. 3). The X direction and the Y direction are predetermined one directions in the horizontal plane and are orthogonal to each other.

  The machine tool 10 is a device that performs drilling, boring, honing and the like on the workpiece W. The workpiece W is, for example, a box-shaped housing such as an engine cylinder head or a mission case. The machine tool 10 includes a first machine tool 10a on the left side (arrow X1 side), a second machine tool 10b on the right side (arrow X2 side), and the first machine tool 10a and the second machine tool 10b. A controller 12 that integrally and cooperatively controls the machine tool 10b and a tool magazine 11 that holds a plurality of detachable tools T are provided.

  The first machine tool 10a and the second machine tool 10b are adjacently provided in parallel. The first machine tool 10a and the second machine tool 10b share a surface plate 13, a workpiece moving device (not shown), and a frame 15, which will be described later. In the present embodiment, the first machine tool 10a and the second machine tool 10b have the same structure. Hereinafter, the first machine tool 10a will be described as a representative.

The first machine tool 10a is arranged on the upper part of the surface plate 13 fixed to the floor. The surface plate 13 is narrow in the X direction and low in the Y direction. A work moving device (not shown) and a frame 15 are provided on the upper surface of the surface plate 13.
As shown in FIG. 1, the frame 15 supports the tool magazine 11. The tool magazine 11 includes main magazines 80 a and 80 b and a sub magazine 100. The main magazine 80a corresponds to the first machine tool 10a. The main magazine 80b corresponds to the second machine tool 10b. The sub magazine 100 is disposed above the main magazines 80a and 80b on the Z2 side. The sub magazine 100 holds a plurality of tools T shared by the main magazines 80a and 80b.

  The frame 15 includes four support columns 15a extending upward from four corners of the surface plate 13, and a plate 15b supported by the upper portions of the support columns 15a. The sub magazine 100 is supported by legs 105 provided on the upper part of the plate 15b. The frame 15 is supported by four support columns 15 a provided on the surface plate 13. A shutter 107 is provided between the two support columns 15a in the Z direction (only the back side is shown in FIG. 1). The shutter 107 is a shielding member for preventing cutting waste and cutting oil from scattering left and right outside the apparatus when the workpiece W is processed. The shutter 107 is opened during maintenance of the machining spindle 36 that performs machining on the workpiece W with the tool T.

  As shown in FIGS. 2 and 3, the first machine tool 10 a includes a Z rail 16, a column 18, a Y rail 20, and a support body 22. The Z rails 16 are a pair of rails provided on the upper surface of the surface plate 13 and extending in the Z direction. The column 18 is a housing that is guided by the Z rail 16 and slides in the Z direction. The Y rails 20 are a pair of rails extending in the Y direction on the front surface of the column 18. The support 22 is a housing that is guided by the Y rail 20 and slides in the Y direction.

  The position of the column 18 on the Z rail 16 in the Z direction is detected by a Z position sensor 16a. Further, the position of the support 22 in the Y direction on the Y rail 20 is detected by the Y position sensor 20a. The Z direction position and Y direction position detected by each sensor are transmitted to the controller 12.

  The column 18 is driven by a Z motor 24 provided on the surface plate 13. Specifically, the column 18 reciprocates in the Z direction via the ball screw mechanism 26 by the rotation of the Z motor 24 (see FIG. 3). Note that a rotary encoder (not shown) may be attached to the Z motor 24 and the rotation angle of the ball screw of the ball screw mechanism 26 may be detected by the rotary encoder. In this case, the detected rotation angle of the ball screw is transmitted to the controller 12 as the position of the column 18 in the Z direction.

  The support 22 is driven by a Y motor 28 (see FIG. 1) disposed inside the surface plate 13. Specifically, the support 22 reciprocates in the Y direction via the ball screw mechanism 30 by the rotation of the Y motor 28 (see FIG. 2). Note that a rotary encoder (not shown) may be attached to the Y motor 28, and the rotation angle of the ball screw of the ball screw mechanism 30 may be detected by this rotary encoder. In this case, the detected rotation angle of the ball screw is transmitted to the controller 12 as the position of the support 22 in the Y direction. The column 18 and the Y rail 20 have a shape extending in the Y direction. For this reason, the column 18 and the Y rail 20 can move the support body 22 for a relatively long distance.

  The support 22 includes a turning arm 32 and a processing spindle 36. The machining main shaft 36 is provided at the end of the turning arm 32 in the centrifugal direction. The processing spindle 36 is supported so as to be rotatable with respect to the turning arm 32. Further, the support 22 includes an arm motor (not shown) that turns the turning arm 32 and a spindle motor 38 (see FIG. 4) that rotates the machining spindle 36.

The main magazine 80a is provided on the upper surface of the plate 15b and on the left side (X1 side) in the drawing. A plurality of tools T attached to the machining spindle 36 are detachably held in the main magazine 80a. The main magazine 80b is provided on the upper surface of the plate 15b on the right side (X2 side) in the drawing. A plurality of tools T attached to the machining spindle 36 are detachably held in the main magazine 80b. Hereinafter, the main magazine 80a will be described as a representative.
FIG. 4 is a side view of the tool magazine 11. FIG. 5 is a perspective view of the tool pot 126. FIG. 6 is a front view of the tool magazine 11.

  As shown in FIGS. 1 and 6, the main magazine 80 a includes a rotation shaft 82, a magazine motor 83, and a holding arm 84. The rotation shaft 82 is an axis extending in the arrow Z direction. The magazine motor 83 is a drive device that drives the rotary shaft 82. The holding arm 84 is a member provided radially in a range of about 270 degrees when viewed from the front (see FIG. 2) around the rotation shaft 82. A substantially C-shaped grip 85 that holds the tool T is provided at the tip of each holding arm 84. The grip 85 is made of an elastic body. The grip 85 has a C-shaped opening (not shown). When the tool T is pushed in from the opening, the opening is elastically expanded and the tool T can be inserted. When a tool is inserted into the opening, the opening is closed elastically. Thereby, the tool is held by the grip 85. The held tool T can be pulled out from the C-shaped opening. The grip 85 can be directly gripped through a bowl-shaped groove formed in the tool T.

  When exchanging the tool T of the machining spindle 36, the main magazine 80a is rotated so that a predetermined holding arm 84 is directed downward from the end of the plate 15b. Specifically, the empty holding arm 84 that does not hold the tool T is directed downward. And after adjusting the Z direction position of the column 18, the support body 22 is raised. As a result, the tool T is held by the holding arm 84 as shown in FIG. Further, the unclamp lever 52 is operated in contact with the unclamp block 53 suspended from the upper part of the column 18. As a result, the tool T is unclamped with respect to the tool head 50. Therefore, the tool T is extracted from the tool head 50 by retracting the column 18 in the direction of the arrow Z2.

Next, the main magazine 80a is rotated so that the holding arm 84 holding the tool T scheduled to be used is directed downward. Then, the column 18 is advanced in the arrow Z1 direction. As a result, the target tool T is inserted into the tool head 50. When the support 22 is further lowered, the unclamp lever 52 is separated from the unclamp block 53, and the tool T is clamped. Thereafter, the main magazine 80a is rotated so that all the holding arms 84 are arranged above the plate 15b as shown in FIG.
Thus, there is no mechanism interposed between the main magazine 80a and the machining spindle 36 for transferring the tool T on the way. The holding arm 84 directly grips the tool T. For this reason, the attaching / detaching operation of the tool T can be performed directly by the column 18, the support 22 and the turning arm 32.

  As shown in FIGS. 1 to 3, the sub-magazine 100 is supported on the Z2 side of the main magazines 80a and 80b by legs 105 provided on the upper surface of the plate 15b. The sub magazine 100 holds the tool T above the holding arms 84 of the main magazines 80a and 80b. As shown in FIG. 2, the sub magazine 100 is provided so as to straddle the main magazines 80a and 80b. The sub magazine 100 is a rectangular (elliptical) rotating magazine. The sub magazine 100 can simultaneously correspond to the main magazines 80a and 80b. The sub magazine 100 can determine a desired tool T by rotating in the horizontal plane (XZ plane).

  The sub magazine 100 includes a base frame 110, a chain 112, and a rail (tool moving rail) 114. The base frame 110 is a substantially rectangular frame fixed to the leg portion 105. The chain 112 is a power transmission member that is wound around the outer surface of the base frame 110. The rail 114 is a track fixed so as to go around the outer surface of the base frame 110 in parallel with the chain 112 below the chain 112 (Y2 direction).

The chain 112 is circulated and driven in a substantially rectangular shape. The chain 112 engages with the drive gear 122 at one of the substantially rectangular four corners. The chain 112 is engaged with the driven gear 124 at the other three corners of the substantially rectangular four corners. The drive gear 122 is driven by the rotational force of the motor 120. The driven gear 124 is a gear that idles without driving the chain 112. The chain 112 moves endlessly along the outer surface of the base frame 110 as the drive gear 122 rotates.
A plurality of holding arms 118 are attached to the chain 112 along the extending direction thereof. The holding arm 118 is formed in a substantially Y shape. The holding arm 118 indirectly holds the tool T attached to the tool pot 126 by engaging with the tool pot 126.

  The holding arm 118 has a rod-like portion on one end side fixed to the chain 112. Further, the holding arm 118 has a fork 116 on the other end side opened downward (Y2 direction) (see FIGS. 1 and 5). The fork 116 is a bifurcated member having no elastic mechanism or movable part. The holding arm 118 holds the tool pot 126 by sandwiching the tool pot 126 (tool T) inserted into the fork 116 with the rail 114. The tool pot 126 and the tool T in the holding arm 118 can be exchanged, for example, by providing a movable part (not shown) on the rail 114 on the back side (Z2 side) of the system, and an operator can perform it manually through this movable part.

  Thus, in the sub magazine 100, the drive gear 122 is driven by the rotational force of the motor 120 serving as a drive source, and the chain 112 moves endlessly. As a result, the tool pot 126 (tool T) moves along the rail 114 via the holding arm 118.

  Further, as shown in FIG. 1, a position detection sensor 180 is disposed in the vicinity of the machining spindle 36. The position detection sensor 180 has a function of detecting a vibration of the tool T that occurs when the tool T is rotated, and a function of detecting a vibration waveform that is generated when the tool T is exchanged. The position detection sensor 180 in the present embodiment is a non-contact sensor and is electrically connected to the controller 12 shown in FIG. The output of the position detection sensor 180 is transmitted to the controller 12. In FIG. 1, the position detection sensor 180 is arranged on the machining spindle 36 of the second machine tool 10b. However, the position detection sensor 180 is not limited to this, and the position detection sensor 180 is arranged on the machining spindle 36 of the first machine tool 10a. May be. The position detection sensor 180 is disposed in the vicinity of the machining spindle 36 only when the deflection of the tool T is detected. The position detection sensor 180 is configured to retract to a predetermined position when the workpiece W is processed.

  Although not shown, the tool magazine 11 detects that the desired tool T is indexed at a position corresponding to a notch 134a (described later), in addition to a sensor for detecting the presence or absence of the tool T. A sensor, a sensor for detecting reception of a desired tool T from the main magazine 80a side, and the like are arranged. Further, the tool magazine 11 has a sensor for detecting that a desired tool T is disposed at a delivery position with the machining spindle 36 by the main magazine 80a, and the tool T is mounted when the tool T is mounted on the machining spindle 36. A sensor for detecting the separation from the holding arm 84 is disposed.

  As shown in FIG. 5, the tool pot 126 is a substantially cylindrical container. When the tool pot 126 is held by the fork 116, flat and vertical portions 126 a are formed on the upper, lower, left and right surfaces along the axial direction. A mounting hole 128 into which the tool T is attached and detached is provided on the end surface (front surface) of the tool pot 126. In addition, a pair of left and right groove portions 130 and 132 extending in the Y direction perpendicular to the axial direction are provided on the planar portions 126a on the left and right side surfaces of the tool pot 126, respectively.

  Therefore, as shown in FIGS. 4 and 5, the tool pot 126 has an upper surface and left and right sides when the fork 116 of the holding arm 118 is inserted along the extending direction (Y2 direction) of the pair of grooves 130, 130. The side is held. In addition, the lower surface of the tool pot 126 is in contact with the rail 114, whereby the entire tool pot 126 (tool T) is held. When the chain 112 is moved endlessly by the motor 120, the tool pot 126 (tool T) engaged between the forks 116 moves together with the chain 112 while the flat surface portion 126a on the lower surface side is in sliding contact with the rail 114.

  As shown in FIGS. 2 and 6, a pair of notches 134 a and 134 b is formed on the rail 114 with which the tool pot 126 is slidably contacted at the Z1 side positions corresponding to the main magazines 80 a and 80 b, respectively.

  In FIG. 6, the notches 134a and 134b coincide with the rotation shafts 82 of the main magazines 80a and 80b in the X direction. That is, the rotation center C2 of the main magazines 80a and 80b and the center position C4 in the width direction (X direction) of the notches 134a and 134b coincide with each other in the Y direction. Thus, since the notches 134a and 134b and the rotating shaft 82 are both in the same vertical plane (YZ plane in FIG. 14), the holding arms 84 of the main magazines 80a and 80b are at the top in the Y direction. When arranged at the position, it corresponds to the notches 134a and 134b. In this state, the holding arm 118 of the sub magazine 100 is disposed at a position corresponding to the notches 134a and 134b, so that the holding arm 118 and the holding arm 84 are opposed to each other in the Y direction with the notches 134a and 134b interposed therebetween. Can be placed.

  As described above, in the tool magazine 11, the openings of the grip 85 and the fork 116 can be set to face each other in the vertical direction (Y direction) in the front view shown in FIG.

  As shown in FIG. 6, the tool magazine 11 includes a tool delivery mechanism (tool changer) 140. The tool delivery mechanism 140 is an apparatus having an operation center C3 that coincides with the center position C4 of the notches 134a and 134b in the Y direction. In FIG. 6, for simplification of the drawing, the center position C4 of the notches 134a and 134b is shown in a slightly lowered position. However, the center position C4 has a height position in the Y direction at the same position as the rail 114. is there. According to this, the tool delivery mechanism 140 is driven in a state where the openings of the grip 85 and the fork 116 face each other, so that the tool T can be easily delivered between the main magazines 80a and 80b and the sub magazine 100. It can be performed stably.

  Next, the tool delivery mechanism 140 will be described. FIG. 7 is a perspective view of the tool delivery mechanism 140 shown in FIG. FIG. 8A is a side view of the tool delivery mechanism 140 shown in FIG. FIG. 8B is a side view showing a state where the hand 146 of the tool delivery mechanism 140 is lowered from the state shown in FIG. FIGS. 7, 8A and 8B show the tool delivery mechanism 140 corresponding to one main magazine 80b and the notch 134b. Since the mechanisms corresponding to the other main magazine 80a and the notch 134a are basically the same except that they are substantially symmetrical, detailed description thereof is omitted.

  As shown in FIGS. 7 and 9 (described later), the tool delivery mechanism 140 includes a substantially U-shaped engagement member 144 and a substantially flat C-shaped hand 146. The engaging member 144 has a pair of claw portions 142 and 142 that extend upward in the drawing (Y1 direction) and can be engaged with the pair of groove portions 132 of the tool pot 126. The hand 146 is a member disposed between the claw portions 142 and 142 of the engaging member 144. The engaging member 144 and the hand 146 are supported by the frame 148 in a side view.

  The engaging member 144 contacts the pair of guide rods 154. The pair of guide rods 154 is connected to the rod 152 of the cylinder mechanism 150 that moves forward and backward in the Z direction. Therefore, the engaging member 144 is advanced and retracted in the Z direction by the pair of guide rods 154 connected to the cylinder mechanism 150.

  As shown in FIG. 7, the hand 146 is a member formed in a substantially C shape in a side view. The hand 146 includes an upper plate 156 and a lower plate 158. The upper plate 156 is a member parallel to the horizontal plane (XZ plane). The lower plate 158 is a member provided in parallel to the Y2 side of the upper plate 156. Further, the lower plate 158 protrudes in the Z1 direction from the upper plate 156. The distance between the upper plate 156 and the lower plate 158 is set to a distance suitable for holding the tool pot 126 (inserted from the X direction) moved by the holding arm 118 (see FIG. 8A). .

  A slider 160 is attached to the back surface of the upper plate 156 and the lower plate 158. The slider 160 is engaged with the rail 159 of the frame 148. As a result, the slider 160 can move up and down along the rail 159 extending in the Y direction.

  A shaft 162 extending in the X1 direction is provided on a side surface (X1 side in FIG. 7) of the hand 146. Further, as shown in FIG. 8A, a bent link 164 is engaged with the hand 146. The link 164 is pivotally supported by a hinge pin 166 in which a through hole formed in a substantially central bent portion protrudes from the frame 148. The link 164 has a shaft 162 inserted through a long hole 168 formed on one end side. Further, a pin 170 extending in the X1 direction is provided on the other end side of the link 164. The pin 170 is connected to the cylinder mechanism 172. The cylinder mechanism 172 drives the rod 174 to be able to advance and retract in the Z direction. A lever member 175 is provided at the tip of the rod 174. The through hole (not shown) of the lever member 175 is engaged with the pin 170. A stopper 176 is provided on the back surface (Z2 side) of the bent portion of the link 164. The frame 148 is provided with a stopper bolt 178 corresponding to the stopper 176.

  Therefore, when the cylinder mechanism 172 is driven and the lever member 175 is advanced and retracted in the Z2 direction, the link 164 swings around the hinge pin 166 as a fulcrum. Thereby, the shaft 162 moves up and down in the Y direction while moving inside the long hole 168. That is, the hand 146 moves in the Y direction via the slider 160. Specifically, as shown in FIG. 8A, when the rod 174 is advanced in the Z1 direction, the link 164 swings upward. As a result, the hand 146 moves up in the Y1 direction.

  On the other hand, when the rod 174 is retracted in the Z2 direction from the state shown in FIG. 8A, the link 164 swings downward (in the direction of the arrow θ) as shown in FIG. 8B. As a result, the hand 146 descends in the Y2 direction. The vertical position (Y direction position) of the shaft 162 due to the swing of the link 164 is detected by sensors (proximity sensors) 179a and 179b installed at the upper limit position and the lower limit position. The upper limit position of the hand 146 is also regulated by the contact between the stopper 176 and the stopper bolt 178, and the lower limit position of the hand 146 is also regulated by the retracted position of the rod 174.

  Such a tool delivery mechanism 140 is set so that the upper surface side (sliding contact member 158a) of the lower plate 158 of the hand 146 is substantially flush with the rail 114 when the hand 146 is at the upper limit position in the Y1 direction. ing. As a result, the frame 148 is fixed so as to be suspended from the lower surface (Y2 side) of the base frame 110 (see FIGS. 3, 4, 6 and 8A). For this reason, when the tool T is not delivered normally, the hand 146 is set to the upper limit position in the Y1 direction as shown in FIG. Thereby, the tool pot 126 (tool T) can smoothly pass between the upper plate 156 and the lower plate 158. That is, the lower plate 158 (sliding contact member 158a) complements the notches 134a and 134b and functions as a part of the rail 114.

  Next, in the machine tool 10 configured as described above, the operation of transferring the tool T between the main magazine 80a constituting the tool magazine 11 and the sub magazine 100 will be described with reference to FIGS. To do. In addition, since the delivery operation | movement of the tool T between the other main magazine 80b and the submagazine 100 is also substantially the same, description is abbreviate | omitted below.

  9 to 11 are explanatory views showing states of the operation for transferring the tool T between the main magazine 80a and the sub-magazine 100. FIG. This delivery operation is controlled by the controller 12. FIG. 9A is a plan view schematically showing the vicinity of the notch 134 a of the tool magazine 11. FIG. 9B is a front view of FIG. FIG. 9C is a side view of FIG. The same applies to (A) to (C) shown in FIGS.

  In FIG. 9 to FIG. 11, each component is schematically shown in comparison with FIG. For example, the cylinder mechanism 172 constituting the tool delivery mechanism 140 is horizontally placed in FIG. 8A (the axial direction is the arrow Z direction), whereas in FIG. 9C, the cylinder mechanism 172 is vertically placed (the axial direction is the arrow Y). Direction) to clarify its function.

  Further, in FIG. 9A and the like, symbols A to D are attached to the tool pots 126 held in the sub magazine 100 for convenience. In the following description, the tool pots 126A to 126D will be appropriately referred to. In FIG. 9C and the like, a region indicated by a hatched line is a region (processing section) where the workpiece W is processed by the processing spindle 36.

  Next, an operation of transferring a desired tool T from the sub magazine 100 to the holding arm 84 of the main magazine 80a from which unnecessary tools T have been removed in advance will be described.

  First, as shown in FIGS. 9A to 9C, the controller 12 drives the sub-magazine 100 to index the tool pot 126C on which a desired tool T is mounted, and makes it correspond to the notch 134a. That is, the tool pot 126 </ b> C equipped with a desired tool T is placed in the hand 146 of the tool delivery mechanism 140.

  Next, as shown in FIGS. 10A to 10C, the controller 12 drives the cylinder mechanism 172 to lower the hand 146. As a result, the groove portion 130 of the tool pot 126C (and the desired tool T attached thereto) whose upper and lower surfaces are held by the hand 146 is guided by the fork 116. Furthermore, the groove part 132 is guided by the claw part 142 and is smoothly lowered in the direction of the arrow Y2.

  When the lowering of the tool pot 126C and the tool T is completed, the tool pot 126C is completely detached from the holding arm 118 and engaged through the groove 132 as shown in FIGS. It is held by the joint member 144. On the other hand, the desired tool T attached to the tool pot 126C is held by the grip 85 of the holding arm 84 constituting the main magazine 80a.

  Thereafter, the controller 12 drives the cylinder mechanism 150 to retract the engagement member 144 in the Z2 direction, and retracts the tool pot 126C (not shown). As a result, the tool T held by the holding arm 84 is detached from the tool pot 126C, and only the tool pot 126C is retracted in the direction of the arrow Z2. As a result, delivery of the desired tool T to the main magazine 80a is completed.

  The subsequent operation is almost the same as the above-described operation, and the empty tool pot 126C from which the tool T has been detached is returned to the sub magazine 100 and, if necessary, other tools T of the main magazine 80a. Replace it.

  The machine tool 10 of the present embodiment includes the above-described tool T replacement work, work of machining the workpiece W with the tool T mounted on the work spindle 36, and the later-described work in the first machine tool 10a and the second machine tool 10b. The work of detecting the deflection of the tool T to be performed can be performed independently of each other.

  Among these, in the replacement work of the tool T, as described above, the sub magazine 100 is driven by the motor 120, the main magazines 80a and 80b are driven by the magazine motor 83, and the support 22 is driven by the Y motor 28. Is done. In addition, the tool delivery mechanism 140 is driven by the cylinder mechanism 150. Thus, in the tool T replacement work, vibration is generated when the motor or cylinder mechanism is started or stopped. Further, since the sub magazine 100, the main magazines 80a and 80b, the tool delivery mechanism 140, and the like are composed of a plurality of members that are heavy objects, vibration occurs when the motor is started or stopped by a motor or cylinder mechanism. Will occur. Further, since the tool T is also a heavy object, an inertial force is generated when the tool T moves in the horizontal direction or the vertical direction or stops moving. For this reason, vibration is generated by contact or collision between the tool T and another member. Thus, in the replacement work of the tool T, not only vibration is generated with the start and stop of the motor and cylinder mechanism, but also vibration is generated with the start and stop of the sub-magazine 100 and the like. Vibration is also generated by the movement or stop of T.

  Next, a method for detecting the deflection of the tool T will be described. FIG. 12 is a block diagram showing a configuration of a tool runout detection system 200 in the present embodiment. FIG. 13 is a graph showing a vibration waveform detected by the position detection sensor 180 during the replacement of the tool T. FIG. 14 is a graph in which frequency components are extracted from the detected vibration waveform. FIG. 15 is a flowchart illustrating a processing procedure when the controller 12 detects the deflection of the tool T.

  The tool runout detection system 200 of the present embodiment rotates the tool T mounted on one of the two machining spindles 36 and detects the runout amount of the tool T at a predetermined scan time (measured runout value). Detection function). As shown in FIG. 12, the tool run-out detection system 200 includes a controller 12 and a position detection sensor 180.

  The controller 12 is composed of a microcomputer having a CPU, RAM, ROM, etc. (not shown). The controller 12 drives the motor 120 and the tool delivery mechanism 140 according to the tool change program. As a result, the tool T necessary for machining the workpiece W is determined in the sub magazine 100, and the tool T is transferred from the sub magazine 100 to the main magazine 80a (80b) as described above.

  Further, the controller 12 has a function of detecting the deflection of the tool T on the other machining spindle 36 while the tool T is being replaced on the one machining spindle 36 in accordance with the tool deflection detection program.

  First, the vibration waveform detection process, the frequency identification process, and the scan time setting process by the controller 12 will be described.

  The controller 12 detects the vibration waveform generated when the tool T is exchanged by the position detection sensor 180 in the vibration waveform detection step. FIG. 13 shows an example of the detected vibration waveform. In FIG. 13, the horizontal axis indicates the time [sec] of the replacement work, and the vertical axis indicates the distance (sensor distance) [mm] from the position detection sensor 180 to the tool T. The distance (interval) from the position detection sensor 180 to the tool T is 0.58 mm. In the example of FIG. 13, when the tool T is exchanged, a maximum vibration of 0.078 mm (A in the figure) is generated.

  Subsequently, in the frequency specifying step, the controller 12 performs frequency analysis on the detected vibration waveform, extracts each frequency component, and specifies the frequency with the largest vibration. For example, frequency components as shown in FIG. 14 can be extracted by frequency analysis of the vibration waveform shown in FIG. In FIG. 14, the horizontal axis indicates the frequency [Hz], and the vertical axis indicates the amplitude [mm]. The amplitude is based on a distance of 0.58 mm from the position detection sensor 180 to the tool T. As shown in FIG. 14, when the frequency included in the vibration waveform is extracted, it can be seen that the vibration near the frequency of 10 Hz is the largest. For this reason, the controller 12 specifies the frequency with the largest vibration as 10 Hz.

  For example, when the vibration detection of the tool T is performed on the other machining spindle 36 while the tool T is being exchanged on one machining spindle 36, for example, the scan time (time required for one vibration detection) Is 0.1 sec (10 Hz), there is a high possibility that the vibration measurement value of the vibration detection includes vibration generated by the replacement work.

  Therefore, in the scan time setting step, the controller 12 sets a period in a frequency range higher than the previously specified frequency as the scan time when performing the vibration detection of the tool T. In the present embodiment, a frequency period that is three times the specified frequency is set as the scan time. That is, since 10 Hz × 3 = 30 Hz (0.03 sec), the scan time is set to 0.03 sec. As shown in FIG. 14, the amplitude in the frequency band of 30 Hz is significantly smaller than that in the frequency band of 10 Hz. For this reason, it is considered that by setting the scan time to 0.03 sec, it is less likely to be affected by vibrations that occur when the tool T is exchanged.

  Thereafter, the controller 12 detects the deflection of the tool T using the position detection sensor 180 in the tool deflection detection step. That is, the controller 12 detects the deflection of the tool T mounted on the other machining spindle 36 while the exchange operation of the tool T is performed on one machining spindle 36 with a scan time of 0.03 sec.

  Next, a processing procedure for detecting the deflection of the tool T in the controller 12 will be described with reference to FIG. The processing of this flowchart is executed by the controller 12 in accordance with a shake detection execution program stored in a storage device (not shown).

  First, in step ST <b> 101, the controller 12 detects a vibration waveform generated when the tool T is replaced by the position detection sensor 180.

  In step ST102, the controller 12 performs frequency analysis on the vibration waveform detected in step ST101, extracts each frequency component, and specifies the frequency with the largest vibration.

  In step ST103, the controller 12 scans the period of the frequency range higher than the frequency specified in step ST102 (in this embodiment, a frequency that is three times the specified frequency) when performing the vibration detection of the tool T. Set as time.

  In step ST104, the controller 12 performs the replacement operation of the tool T on one machining spindle 36, and detects the deflection of the tool T mounted on the other machining spindle 36 based on the scan time set in step ST103. . At this time, the controller 12 stores the detected measured deflection value of the tool T in a storage device (not shown). The controller 12 ends the processing of this flowchart after the detection of the deflection of the tool T in step ST104 is completed.

  Next, Table 1 and Table 2 show examples in which runout detection of the tool T mounted on the other machining spindle 36 is performed while exchanging the tool T on one machining spindle 36. Will be described with reference to FIG. In this embodiment, the scan time is set to four stages of 0.1 sec to 0.03 sec, and the rotation speed of the machining spindle 36 is set to three stages of 2200 rpm to 4400 rpm. In addition, while exchanging the tool T on one of the machining spindles 36, the runout of the tool T mounted on the other machining spindle 36 is continuously detected 20 times, and each runout is measured. The value [mm] was recorded. Note that the amount of deflection of the tool T measured in advance by another method was 0.039 mm (39 μm).

  Table 1 shows the measurement results with the maximum shake measurement value in 20 times of shake detection, and Table 2 shows the measurement results with the minimum shake measurement value in 20 times of shake detection.

  As shown in Tables 1 and 2, the measurement results were minimized when the rotation speed of the machining spindle 36 was 3300 rpm and the scan time was set to 0.03 sec. Therefore, it has been clarified that, when the shake detection is performed under the above-described conditions, it is difficult to be affected by the vibration generated when the tool T is replaced on the other machining spindle 36. For this reason, when shake detection is performed under the conditions shown in the present embodiment, accurate shake measurement values can be obtained.

  In Table 2, when the rotational speed of the machining spindle 36 is set to 4400 rpm, the measurement result is less than 0.039. These numerical values are excluded from the consideration of the measurement results because the shake amount (0.039 mm) of the main body is underestimated.

  Further, the rotational speed of the machining spindle 36 in the conventional shake detection is 2200 rpm. However, as is apparent from the measurement results in Tables 1 and 2, it is desirable to set the rotation side of the machining spindle 36 at a higher speed than in the prior art. In this example, the speed was set to 3300 rpm, which is 1.5 times that of the conventional example (2200 rpm). Thus, by setting the rotation side of the machining spindle 36 at a higher speed than the conventional one, it is possible to make it less susceptible to vibration without underestimating the deflection amount of the tool T.

  According to the tool run-out detection system 200 of the present embodiment described above, the following effects are obtained.

  In the tool run-out detection system 200 according to the present embodiment, the controller 12 detects a vibration waveform generated when the tool T is exchanged, and specifies a frequency having the largest vibration, and is higher than the specified frequency. A function of setting a frequency range period as a scan time for detecting the deflection of the tool T is provided. According to this, it is possible to set a scan time that is not easily affected by vibrations that occur when the tool T is exchanged with one machining spindle 36. Therefore, when the vibration of the tool T mounted on the other machining spindle 36 is detected while the exchange work of the tool T is performed on one machining spindle 36, the vibration generated by the exchange work of the tool T is performed. Can be less affected by

  Further, in the tool run-out detection system 200 of the present embodiment, the controller 12 has a function of setting a frequency period at least three times the specified frequency as a scan time. According to this, the influence of the vibration which generate | occur | produces in the exchange operation of the tool T can be made harder to receive.

  Further, in the tool runout detection system 200 of the present embodiment, when the rotation side of the machining spindle 36 is set to a higher speed than the conventional one, the runout amount of the tool T can be prevented from being underestimated.

  Although the embodiment of the tool runout detection method according to the present invention has been described above, the present invention is not limited to the above-described embodiment, and can be implemented in various forms.

  For example, in the present embodiment, a vibration waveform that is generated when the tool T is exchanged is detected by the position detection sensor 180 that is used when the vibration is detected. However, the present invention is not limited to this, and a vibration waveform generated when the tool T is exchanged may be detected by a dedicated vibration sensor.

  Further, in the present embodiment, the case has been described in which the deflection of the tool T is detected on the other machining spindle 36 while the tool T is being replaced on the one machining spindle 36. However, the present invention is not limited to this, and the present invention can also be applied to the case where the deflection of the tool T is detected on the other machining spindle 36 while the machining W is being performed on the one machining spindle 36. In this case, it is possible to make it less susceptible to vibrations generated by cutting the workpiece W.

10: Machine tool 11: Tool magazine 12: Controller 36: Processing spindle 80a, 80b: Main magazine 100: Sub magazine 140: Tool delivery mechanism 180: Position detection sensor 200: Tool run-out detection system

Claims (2)

A tool runout detection method in a machine tool having at least two rotating shafts to which a tool can be detachably attached,
A vibration waveform detection step of performing the tool replacement operation on one rotating shaft and detecting a vibration waveform generated by the replacement operation;
Based on the detected vibration waveform, a frequency specifying step for specifying a frequency with the largest vibration,
A scan time setting step of setting a period of a frequency region higher than the identified frequency as a scan time when performing the tool runout detection;
A tool runout detecting step of performing the tool replacement operation on one of the rotating shafts and detecting the runout of the tool according to the set scan time while rotating the other one of the rotating shafts,
Tool runout detection method including In the scan time setting step,
The tool runout detection method according to claim 1, wherein a period of a frequency at least three times the identified frequency is set as a scan time when performing the runout detection of the tool.

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