JP2021194709A - Processing machine - Google Patents

Abstract

To provide a processing machine that can prevent floating particles from leaking from a processing area and has excellent convenience.SOLUTION: A processing machine 10 comprises: a cover body 21 provided with an opening part 26; and a door part 31 which moves between a first position at which the opening part 26 is brought into an opened state and a second position at which the opening part 26 is brought into a closed state, which compartments and forms a processing area 110 together with the cover body 21 when positioned at the second position. The opening part 26 includes a front opening part 27 arranged in front of the machine in the processing area 110 and an upper opening part 28 extended from the front opening part 27 and arranged above the processing area 110. The processing machine 10 further comprises a capturing part 51 (a movable cover 61) that moves between a third position overlapping with the upper opening part 28 in a top view and a fourth position further away from the upper opening part 28 than the third position, and that can capture oil mist.SELECTED DRAWING: Figure 1

Description

The present invention relates to a processing machine.

For example, in Japanese Patent Application Laid-Open No. 6-37642 (Patent Document 1), an entire cover provided with an opening, an automatic opening / closing cover arranged at the opening, and a plurality of discharge ports provided on two opposite sides of the opening are provided. Also disclosed is a machine tool mist scattering prevention device comprising a suction port and a mist recovery device connected to the suction port via a duct. When the automatic opening / closing cover is opened, an air curtain is formed by providing an air flow from the discharge port to the suction port.

Jitsukaihei 6-376742 Gazette

As disclosed in Patent Document 1 described above, a processing machine including a door portion that can be opened and closed arranged at an opening of a cover body and a mist collector for collecting mist generated in the processing area is known. Has been done.

In such a processing machine, if the door portion is opened when the mist collection by the mist collector is not completed, the mist in the processing area may leak to the external space. On the other hand, it is conceivable to prevent the leakage of mist when the door is opened by arranging the intake port of the duct connected to the mist collector in the upper opening arranged above the processing area. However, in such a configuration, the loading and unloading of the work through the upper opening is hindered, the inside of the processing area becomes dark, and the convenience of the processing machine is impaired.

Therefore, an object of the present invention is to solve the above-mentioned problems, and to provide a processing machine capable of preventing leakage of suspended particles from the processing area and having excellent convenience.

The processing machine according to the present invention operates between the cover body provided with the opening, the first position where the opening is opened, and the second position where the opening is closed, and the second position. It is provided with a cover body and a door portion for partitioning a processing area when positioned in. The opening includes a front opening located in front of the machine in the machining area and an upper opening extending from the front opening and located above the machining area. The processing machine operates between a third position that overlaps the upper opening in top view and a fourth position that is farther from the opening above the third position, and further includes a catching portion capable of capturing suspended particles.

According to the processing machine configured in this way, when the door portion is positioned at the first position, the trapping portion is positioned at the third position to capture the suspended particles rising from the processing area through the upper opening. Capture by the part. This makes it possible to prevent the leakage of suspended particles from the processing area. Further, by positioning the catching portion at the fourth position, the upper opening portion is opened. This makes it possible to improve the convenience of the processing machine.

Also preferably, the capture section includes a movable cover.

According to the processing machine configured in this way, the movable cover positioned at the third position can capture the suspended particles rising from the processing area through the upper opening.

Also preferably, the suspended particles are mist. The movable cover includes a bottom surface that faces the machining area when positioned in the third position. The bottom surface has a shape in which the central portion of the bottom surface projects upward from the peripheral edge portion of the bottom surface.

According to the processing machine configured in this way, by collecting the mist condensed on the bottom surface of the movable cover on the peripheral edge of the bottom surface, it is possible to suppress the occurrence of mist dripping at an unintended location.

Further, preferably, the processing machine has a saucer shape and further includes a saucer portion arranged below the peripheral edge portion of the bottom surface.

According to the processing machine configured in this way, the mist collected on the peripheral edge of the bottom surface can be collected in the dish portion.

Also preferably, the door portion includes an upper door portion that closes the upper opening when positioned at the second position. When the movable cover is positioned at the third position, the movable cover is arranged in place of the upper door portion at the position of the upper door portion when the door portion is positioned at the second position.

According to the processing machine configured in this way, it is possible to suppress the formation of a gap between the movable cover positioned at the third position and the cover body. This makes it possible to more reliably prevent the leakage of suspended particles from the processing area.

Also preferably, the processing machine includes a duct and further comprises a recovery device that collects suspended particles through the intake port of the duct. The capture section includes the intake port of the duct.

According to the processing machine configured in this way, the suspended particles rising from the processing area through the upper opening can be collected in the collection device through the intake port of the duct positioned at the third position.

Further, preferably, the catching portion slides in the front-rear direction of the machine or in the left-right direction of the machine between the third position and the fourth position.

According to the processing machine configured in this way, when the catching portion slides in the front-rear direction of the machine and the left-right direction of the machine, the catching portion can be compactly arranged in the left-right direction of the machine and the front-back direction of the machine, respectively.

Further, preferably, the processing machine further includes an actuator connected to the capture unit and operating the capture unit between the third position and the fourth position, and an actuator control unit that controls the actuator.

According to the processing machine configured in this way, the catching portion can be automatically operated between the third position and the fourth position.

Further, preferably, the actuator control unit controls the actuator so that the capture unit operates from the fourth position to the third position when the door unit operates from the second position to the first position.

According to the processing machine configured in this way, the catching portion operates from the fourth position to the third position in conjunction with the operation of the door portion from the second position to the first position, so that the inside of the machining area It is possible to more reliably prevent the leakage of suspended particles from the door.

Further, preferably, the actuator control unit controls the actuator so that the capture unit operates from the fourth position to the third position when the execution program of the work processing in the processing area is completed.

According to the processing machine configured in this way, the catching portion operates from the fourth position to the third position following the completion of the work processing, so that the leakage of suspended particles from the processing area is more reliably prevented. be able to.

Further, preferably, the actuator control unit controls the actuator so that the capture unit operates from the third position to the fourth position after a predetermined time has elapsed after the capture unit is positioned at the third position.

According to the processing machine configured in this way, the suspended particles can be captured by the capturing unit within a predetermined time.

Further, preferably, the actuator control unit controls the actuator so that the capture unit operates from the third position to the fourth position when a command from the operator is received.

According to the processing machine configured in this way, the operator can freely determine the timing at which the capturing unit operates from the third position to the fourth position.

Further, preferably, the processing machine further includes a detection unit capable of detecting suspended particles in the processing area. The actuator control unit controls the actuator so that the capture unit operates from the third position to the fourth position when it is determined that the amount of suspended particles detected by the detection unit is equal to or less than a predetermined amount.

According to the processing machine configured in this way, the upper opening can be opened after the amount of suspended particles detected by the detection unit becomes a predetermined amount or less.

Further, preferably, the actuator control unit controls the actuator so that the capture unit operates from the third position to the fourth position when the program for loading and unloading the work is executed inside and outside the machining area.

According to the processing machine configured in this way, it is possible to prevent the loading / unloading of the work through the upper opening from being obstructed by the catching portion.

As described above, it is possible to prevent the leakage of suspended particles from the processing area, and it is possible to provide a processing machine having excellent convenience.

It is a perspective view which shows the processing machine in embodiment of this invention. It is a side view which shows the processing machine (door part: 1st position, movable cover: 3rd position). It is a top view which shows the processing machine in FIG. It is a side view which shows the processing machine (door part: 2nd position, movable cover: 4th position). It is a top view which shows the processing machine in FIG. It is a side view which shows the processing machine (door part: 1st position, movable cover: 4th position). It is a top view which shows the processing machine in FIG. It is sectional drawing which shows the 1st modification of a movable cover. It is another cross-sectional view which shows the 1st modification of a movable cover. It is a perspective view which shows the 2nd modification of a movable cover. It is another perspective view which shows the 2nd modification of a movable cover. It is a block diagram which shows the control system for sliding operation of a movable cover. It is a flowchart which shows the 1st specific example of the timing of sliding operation of a movable cover. It is a flowchart which shows the 2nd specific example of the timing of sliding operation of a movable cover. It is a flowchart which shows the 3rd specific example of the timing of sliding operation of a movable cover.

Embodiments of the present invention will be described with reference to the drawings. In the drawings referred to below, the same or corresponding members are assigned the same number.

FIG. 1 is a perspective view showing a processing machine according to an embodiment of the present invention. With reference to FIG. 1, the processing machine 10 in the present embodiment is a lathe that processes a work by bringing a tool into contact with a rotating work. The machining machine 10 is an NC (Numerically Control) machine tool in which various operations for machining a workpiece are automated by numerical control by a computer.

In the present specification, an axis parallel to the left-right direction (width direction) of the processing machine 10 and extending in the horizontal direction is referred to as a "Z axis", and is parallel to the front-back direction (depth direction) of the processing machine 10 and horizontally. The axis that extends is called the "Y axis", and the axis that extends in the vertical direction is called the "X axis". The right direction in FIG. 1 is referred to as "+ Z axis direction", and the left direction is referred to as "-Z axis direction". In FIG. 1, the front direction of the paper surface is referred to as "+ Y-axis direction", and the back direction is referred to as "-Y-axis direction". The upward direction in FIG. 1 is referred to as "+ X-axis direction", and the downward direction is referred to as "-X-axis direction".

The “front of the machine” is a horizontal direction from the machining area of the machining machine 10 toward the side on which the operator stands when accessing the machining area of the machining machine 10. "Back of the machine" is the opposite direction of the front of the machine. The + Y-axis direction corresponds to the front of the machine, and the −Y-axis direction corresponds to the rear of the machine. The "machine left-right direction" is a horizontal direction orthogonal to the machine front-rear direction.

For convenience of explaining the structure of the processing machine 10, the X-axis, Y-axis, and Z-axis are set as described above, but these do not necessarily match the X-axis, Y-axis, and Z-axis defined in the lathe. No.

First, the overall structure of the processing machine 10 will be described. The processing machine 10 has a cover body 21. The cover body 21 forms the processing area 110 and has the appearance of the processing machine 10. The processing area 110 is a space where the work is processed, and is substantially sealed so that foreign matter such as chips or cutting oil associated with the work processing does not leak to the outside of the processing area 110.

The machining area 110 holds a work spindle 17 (see FIG. 2 and the like below) for rotating the work around the rotation center axis 101 parallel to the Z axis, and a plurality of tools, and holds the Z axis. A turret type tool post 12 capable of turning around a turning center axis 102 parallel to the direction is arranged. In the machining area 110, a tailstock for supporting the center of rotation of the work, or an opposed work spindle arranged so as to face the work spindle 17 in the Z-axis direction may be further arranged.

The cover body 21 is provided with an opening 26. The opening 26 opens the processing area 110 to the external space.

The opening 26 has a front opening 27 and an upper opening 28. The front opening 27 is arranged in front of the machine in the machining area 110. The front opening 27 opens the processing area 110 in the + Y-axis direction. When accessing the machining area 110, the operator stands at a position facing the opening surface of the front opening 27. The upper opening 28 is arranged above the processing area 110. The upper opening 28 is continuous with the front opening 27. The upper end portion (end portion in the + X-axis direction) of the front opening portion 27 is connected to the front end portion (end portion in the + Y-axis direction) of the upper opening portion 28. The upper opening 28 opens the processing area 110 toward the + X axis direction.

The cover body 21 has a first side cover 14, a second side cover 16, a ceiling cover 19, and a splash guard 18. The first side cover 14, the second side cover 16, and the ceiling cover 19 have the appearance of the processing machine 10. The splash guard 18 partitions the processing area 110.

The first side cover 14 and the second side cover 16 are provided on both sides of the opening 26 in the Z-axis direction, respectively. The operation panel 15 is provided on the first side cover 14. The operation panel 15 includes various buttons and switches used by the operator when operating the processing machine 10, a display unit showing a processing state of the work in the processing machine 10, and the like. A work spindle 17 and the like are arranged inside the second side cover 16.

The ceiling cover 19 is arranged on the ceiling of the processing machine 10. The opening 26 is defined by the first side cover 14, the second side cover 16, and the ceiling cover 19.

FIG. 2 is a side view showing a processing machine (door portion: first position, movable cover: third position). FIG. 3 is a top view showing the processing machine in FIG. 2. FIG. 4 is a side view showing a processing machine (door portion: second position, movable cover: fourth position). FIG. 5 is a top view showing the processing machine in FIG. FIG. 6 is a side view showing a processing machine (door portion: first position, movable cover: fourth position). FIG. 7 is a top view showing the processing machine in FIG.

With reference to FIGS. 1 to 7, the processing machine 10 further includes a door portion 31. The door portion 31 is provided in the opening portion 26. The door portion 31 can operate between the first position Pa with the opening 26 in the open state and the second position Pb with the opening 26 in the closed state.

The door portion 31 slides between the first position Pa and the second position Pb. The door portion 31 slides in the horizontal direction between the first position Pa and the second position Pb. The door portion 31 slides in the Z-axis direction between the first position Pa and the second position Pb.

The door portion 31 has the appearance of the processing machine 10. The door portion 31 is arranged so as to overlap the second side cover 16 when it is positioned at the first position Pa. When the door portion 31 is positioned at the second position Pb, the door portion 31 together with the splash guard 18 forms a section of the processing area 110.

The door portion 31 has a front door portion 33 and an upper door portion 32. When the door portion 31 is positioned at the second position Pb, the front door portion 33 closes the front opening 27, and the upper door 32 closes the upper opening 28. The front door portion 33 as a whole has a plate shape parallel to the X-axis-Z-axis plane. The front door portion 33 is provided with a transparent window 34 (see FIG. 1). The upper door portion 32 has a plate shape parallel to the Y-axis-Z-axis plane as a whole. The upper end portion (end portion in the + X-axis direction) of the front door portion 33 and the front end portion (end portion in the + Y-axis direction) of the upper door portion 32 are connected to form a corner portion.

The door portion 31 is a manual door that is manually slid. The door portion in the present invention is not limited to this, and may be an automatic door that is slid by an actuator such as a cylinder or a motor.

The door portion in the present invention may be composed of a plurality of door portions that are aligned in the Z-axis direction and close the openings when positioned at the second position. The operation of the door portion in the present invention is not limited to the slide type, and is, for example, a rotary type that is rotatably supported around an axis parallel to the X-axis direction and rotates between the first position and the second position. May be.

The processing machine 10 further has a catching portion 51. The capturing unit 51 can capture the mist (oil mist) generated in the processing area 110. The catching portion 51 operates between a third position Pc that overlaps the upper opening 28 in top view and a fourth position Pd that is farther from the upper opening 28 than the third position Pc.

The catching portion 51 is provided on the ceiling cover 19. The catching portion 51 is provided so as to be able to advance and retreat with respect to the upper opening 28. The capturing unit 51 slides between the third position Pc and the fourth position Pd. The capturing unit 51 slides in the horizontal direction between the third position Pc and the fourth position Pd.

The capturing unit 51 slides in the Y-axis direction (machine front-rear direction) between the third position Pc and the fourth position Pd. The direction in which the catching portion 51 slides is orthogonal to the direction in which the door portion 31 slides. The capturing unit 51 slides in the −Y axis direction (rearward of the machine) when moving from the third position Pc to the fourth position Pd. The capturing unit 51 slides in the + Y axis direction (front of the machine) when moving from the fourth position Pd to the third position Pc.

The capture unit 51 may slide in the Z-axis direction (machine left-right direction) between the third position Pc and the fourth position Pd. In this case, the direction in which the catching portion 51 slides is parallel to the direction in which the door portion 31 slides.

The catching portion 51 has a movable cover 61. The movable cover 61 has a plate shape parallel to the Y-axis-Z-axis plane (horizontal plane) as a whole. The movable cover 61 has a shallow bottom saucer shape in which the peripheral edge portion on the Y-axis −Z axis plane is bent in the −X axis direction (downward) and opens in the −X axis direction. The movable cover 61 has a rectangular shape when viewed from above. Preferably, the area of the movable cover 61 when viewed from above is larger than the area of the opening surface of the upper opening 28 when viewed from above.

The movable cover 61 is supported by various guide mechanisms (not shown) such as a linear guide so as to be slidable in the Y-axis direction (machine front-rear direction). The movable cover 61 is an automatic cover that is slid by an actuator 66 described later. The movable cover 61 may be a manual cover that is manually slid.

As shown in the top view in FIG. 3, the movable cover 61 positioned at the third position Pc covers the entire opening surface of the upper opening 28. The movable cover 61 positioned at the third position Pc may be configured to cover a part of the opening surface of the upper opening 28.

As shown in the top view in FIGS. 5 and 7, the movable cover 61 positioned at the 4th position Pd is retracted from the upper opening 28 with respect to the movable cover 61 positioned at the 3rd position Pc. There is. The movable cover 61 positioned at the fourth position Pd is arranged at a position deviated from the opening surface of the upper opening 28.

The movable cover 61 positioned at the fourth position Pd may be configured to cover a part of the opening surface of the upper opening 28. In this case, the area where the movable cover 61 positioned at the fourth position Pd covers the opening surface of the upper opening 28 is larger than the area where the movable cover 61 positioned at the third position Pc covers the opening surface of the upper opening 28. Also becomes smaller.

According to such a configuration, as shown in FIGS. 2 and 3, when the door portion 31 is positioned at the first position Pa that opens the opening portion 26, the movable cover 61 is designated as the upper opening portion 28. By positioning at the overlapping third position Pc, the oil mist rising from the machining area 110 through the upper opening 28 is captured by the movable cover 61. This makes it possible to prevent oil mist from leaking from the processing area 110.

Further, as shown in FIGS. 6 and 7, when the door portion 31 is positioned at the first position Pa that opens the opening 26, the movable cover 61 is positioned at the fourth position Pd that moves away from the opening 26. By doing so, the upper opening 28 is opened. As a result, when the work is hung by a wire using a crane or the like, it is possible to prevent the wire or the work from interfering with the movable cover 61, or to prevent the inside of the processing area 110 from being darkened by the movable cover 61. As a result, the convenience of the processing machine 10 can be improved.

The processing machine 10 further includes a mist collector 41 (recovery device). The mist collector 41 is a device that collects the oil content of the oil mist and discharges clean air. The method for recovering the oil content of the oil mist in the mist collector 41 is not particularly limited, and may be, for example, a filter method or a centrifugal separation method.

The mist collector 41 has a mist collector main body portion 42, a first duct 46, a second duct 48, and a switching mechanism portion 43.

The mist collector main body 42 is a main body of the mist collector 41 that collects the oil content of the oil mist. The first duct 46 and the second duct 48 are duct bodies that guide the oil mist generated in the processing area 110 to the mist collector main body 42. The first duct 46 and the second duct 48 are connected to the mist collector main body 42 via the switching mechanism 43.

The first duct 46 has an intake port 46p. The intake port 46p is connected to the movable cover 61. The intake port 46p is connected to the movable cover 61. The intake port 46p is open in the space directly below the movable cover 61. The second duct 48 has an intake port 48p. The intake port 48p is connected to the splash guard 18. The intake port 48p is open in the processing area 110.

The switching mechanism portion 43 has an oil mist passage connecting the first duct 46 and the second duct 48, the mist collector main body portion 42, and a valve arranged in the oil mist passage. The switching mechanism unit 43 has an operation mode of sucking oil mist through the first duct 46, an operation mode of sucking oil mist through the second duct 48, and an oil mist through the first duct 46 and the second duct 48 by operating a valve. It is possible to switch between the operation mode of sucking.

As shown in FIGS. 2 and 3, when the door portion 31 is positioned at the first position Pa that opens the opening 26 and the movable cover 61 is positioned at the third position Pc that overlaps the upper opening 28. The mist collector 41 sucks the oil mist through the first duct 46. As a result, the oil mist captured by the movable cover 61 can be collected in the mist collector main body 42. In this case, the mist collector 41 may suck the oil mist through the first duct 46 and the second duct 48.

As shown in FIGS. 4 and 5, when the door portion 31 is positioned at the second position Pb that closes the opening 26, the mist collector 41 sucks the oil mist through the second duct 48. As a result, the oil mist generated by machining the work in the machining area 110 can be collected in the mist collector main body 42.

It should be noted that the movable cover 61 is not provided, and the intake port 46p of the first duct 46 is located at the third position Pc that overlaps the upper opening 28 in the top view and the fourth position that is farther from the upper opening 28 than the third position Pc. It may be configured to operate with Pd. In this case, the catching portion in the present invention has an intake port 46p of the first duct 46. Preferably, the intake port 46p opens toward the −X axis direction (downward).

8 and 9 are cross-sectional views showing a first modification of the movable cover. FIG. 8 shows a cross section corresponding to the position seen in the arrow-viewing direction on the VIII line in FIG. 2, and FIG. 9 shows the position seen in the arrow-viewing direction on the IX-IX line in FIG. The cross section corresponding to is shown.

With reference to FIGS. 8 and 9, the movable cover 61 has a bottom surface 62. As shown in FIG. 8, when the movable cover 61 is positioned at the third position Pc, the bottom surface 62 faces the machining area 110. The bottom surface 62 faces the machining area 110 through the upper opening 28.

The bottom surface 62 has a shape in which the central portion 62j of the bottom surface 62 projects upward from the peripheral edge portion 62k of the bottom surface 62. The peripheral edge portion 62k is located at both ends of the bottom surface 62 in the machine left-right direction (Z-axis direction), and the central portion 62j is located at the middle portion between both ends of the bottom surface 62 in the machine left-right direction. The bottom surface 62 has a shape that extends diagonally upward while curving from both ends of the bottom surface 62 in the left-right direction of the machine toward the intermediate portion.

The bottom surface 62 may have a dome shape in which an inclination occurs at both ends and an intermediate portion in the machine front-rear direction (Y-axis direction) in addition to the machine left-right direction (Z-axis direction).

There is a problem that the oil mist condensed on the bottom surface 62 of the movable cover 61 drips to the operator looking into the processing area 110 through the opening 26. On the other hand, in the movable cover 61 in this modification, the oil mist condensed on the bottom surface 62 of the movable cover 61 can be collected on the peripheral edge portion 62k while being transmitted through the bottom surface 62 by gravity. As a result, it is possible to effectively prevent the oil mist from dripping on the operator.

As shown in FIG. 9, the processing machine 10 further includes a saucer portion 71. The saucer portion 71 is arranged below the peripheral edge portion 62k of the bottom surface 62. The saucer portion 71 has a saucer shape that opens toward the + X axis direction (upward). The opening of the saucer portion 71 faces the peripheral edge portion 62k of the bottom surface 62 in the X-axis direction. The saucer portion 71 has a long shape in which the Y-axis direction is the longitudinal direction.

According to such a configuration, the oil mist collected on the peripheral edge portion 62k of the bottom surface 62 can be collected in the tray portion 71. The saucer portion 71 may be provided with a drain for returning the condensed oil mist to the processing area 110 or the coolant tank (not shown).

10 and 11 are perspective views showing a second modification of the movable cover. In FIG. 10, the door portion 31 is positioned at the second position Pb that closes the opening 26, and the movable cover 61 is positioned at the fourth position Pd away from the upper opening 28. In FIG. 11, the door portion 31 is positioned at the first position Pa that opens the opening 26, and the movable cover 61 is positioned at the third position Pc that overlaps with the upper opening 28.

In this modification, when the movable cover 61 is positioned at the third position Pc, the movable cover 61 is arranged in place of the upper door portion 32 at the position of the upper door portion 32 when the door portion 31 is positioned at the second position Pb. Will be done. The upper door portion 32 slides in the Z-axis direction in the Y-axis −Z-axis plane. The movable cover 61 slides in the Y-axis direction in the same Y-axis-Z-axis plane as the upper door portion 32.

According to such a configuration, the movable cover 61 positioned at the third position Pc is arranged in place of the upper door portion 32 when the door portion 31 is positioned at the second position Pb, and thus is arranged at the third position. It is possible to suppress the formation of a gap between the movable cover 61 positioned on the PC and the cover body 21 forming the upper opening 28. This makes it possible to more reliably prevent oil mist from leaking from the processing area 110.

Subsequently, a control system for sliding the movable cover 61 will be described. FIG. 12 is a block diagram showing a control system for sliding the movable cover.

With reference to FIG. 12, the processing machine 10 further includes an actuator 66 and a control device 81. The actuator 66 operates the capture unit 51 (movable cover 61) between the third position Pc and the fourth position Pd. The actuator 66 is composed of a cylinder capable of stretching and shortening operations along the Y-axis direction. The actuator 66 is not limited to the cylinder, and various actuators (motors and the like) capable of opening and closing the movable cover 61 by receiving an electric signal from the control device 81 (actuator control unit 82 described later) are used. be able to.

The control device 81 controls the processing machine 10. The control device 81 is provided in the processing machine 10 and is a control panel for controlling various operations in the processing machine 10. The control device 81 has an actuator control unit 82 for controlling the actuator 66.

The control device 81 further includes a program storage unit 83, a program execution unit 84, a spindle control unit 86, and a feed control unit 85.

The program storage unit 83 stores an execution program (numerical control program) for machining a work created by an operator of the machining machine 10. The program storage unit 83 is, for example, a flash memory.

The program execution unit 84 executes the execution program stored in the program storage unit 83. More specifically, the program execution unit 84 reads the command of the execution program and outputs a control signal to each of the spindle control unit 86 and the feed control unit 85. The spindle control unit 86 controls the spindle motor 88 according to a control signal from the program execution unit 84. The feed control unit 85 controls the feed motor 87 according to the control signal from the program execution unit 84.

The processing machine 10 further includes a movable cover detection unit 91, a door detection unit 92, a mist detection unit 93, and an input unit 94.

The movable cover detection unit 91 can detect the movable cover 61. The movable cover detection unit 91 includes a sensor capable of detecting the movable cover 61 positioned at the third position Pc and the fourth position Pd. The movable cover detection unit 91 may be a non-contact type sensor such as a proximity sensor, or may be a contact type sensor such as a limit switch. When the movable cover detection unit 91 detects the movable cover 61 positioned at the third position Pc and the fourth position Pd, the movable cover detection unit 91 outputs the position signal of the movable cover 61 corresponding to the third position Pc and the fourth position Pd, respectively. Output to the actuator control unit 82.

The door detection unit 92 can detect the door unit 31. The door detection unit 92 includes a sensor capable of detecting the door unit 31 positioned at the first position Pa and the second position Pb. The door detection unit 92 may be a non-contact type sensor such as a proximity sensor, or may be a contact type sensor such as a limit switch. When the door detection unit 92 detects the door unit 31 positioned at the first position Pa and the second position Pb, the door detection unit 92 actuators the position signals of the door unit 31 corresponding to the first position Pa and the second position Pb, respectively. Output to the control unit 82.

The mist detection unit 93 can detect oil mist in the processing area 110. As shown in FIGS. 1 to 7, the mist detection unit 93 is provided in, for example, the processing area 110. As an example, the mist detection unit 93 has a light emitting element and a light receiving element, and the light from the light emitting element is diffusely reflected by the oil mist, and the amount (concentration) of the oil mist is determined by the amount of the diffusely reflected light reaching the light receiving element. ) Consists of an optical sensor (light scattering method) that evaluates.

The input unit 94 is configured so that the operator can input an instruction regarding the operation of the processing machine 10. The input unit 94 is provided on the operation panel 15 in FIG. 1, for example.

In the following, a specific example of the timing for sliding the movable cover 61 between the third position Pc and the fourth position Pd will be described. FIG. 13 is a flowchart showing a first specific example of the timing of sliding the movable cover.

With reference to FIGS. 12 and 13, specifically, when the actuator control unit 82 operates the door unit 31 from the second position Pb to the first position Pa, the movable cover 61 moves to the fourth position Pd. The actuator 66 is controlled so as to operate from the third position Pc. The actuator control unit 82 controls the actuator 66 so that the movable cover 61 operates from the third position Pc to the fourth position Pd after a predetermined time has elapsed after the movable cover 61 is positioned at the third position Pc. do.

More specifically, as shown in FIGS. 4 and 5, the work is machined in the machining area 110 (S101). In this step, the program execution unit 84 reads the command of the execution program stored in the program storage unit 83, and outputs a control signal to each of the spindle control unit 86 and the feed control unit 85. During the work processing, the door portion 31 is positioned at the second position Pb. The movable cover 61 is positioned at the fourth position Pd. Next, the work processing is completed (S102).

Next, the door portion 31 is slid (opened) from the second position Pb toward the first position Pa (S103). In this step, the operator slides the door portion 31 in the −Z axis direction.

Next, the opening operation of the door portion 31 is detected (S104). In this step, when the door unit 31 moves away from the second position Pb, the door detection unit 92 stops outputting the position signal of the door unit 31 corresponding to the second position Pb to the actuator control unit 82. When the door unit 31 reaches the first position Pa, the door detection unit 92 outputs a position signal of the door unit 31 corresponding to the first position Pa to the actuator control unit 82. The actuator control unit 82 detects the opening operation of the door unit 31 based on the position signal of the door unit 31 input from the door detection unit 92.

Next, as shown in FIGS. 2 and 3, the movable cover 61 is slid (advanced) from the fourth position Pd toward the third position Pc (S105). In this step, the actuator control unit 82 controls the actuator 66 so that the movable cover 61 advances when the opening operation of the door unit 31 is detected in S104. The control of the actuator 66 is performed between the time when the input of the position signal of the door portion 31 corresponding to the second position Pb is stopped and the time when the input of the position signal of the door portion 31 corresponding to the first position Pa is started. It is done at either timing.

Next, the advance movement of the movable cover 61 is detected (S106). In this step, when the movable cover 61 is separated from the fourth position Pd, the movable cover detecting unit 91 stops the output of the position signal of the movable cover 61 corresponding to the fourth position Pd to the actuator control unit 82. When the movable cover 61 reaches the third position Pc, the movable cover detecting unit 91 outputs a position signal of the door unit 31 corresponding to the third position Pc to the actuator control unit 82. The actuator control unit 82 detects the advance movement of the movable cover 61 based on the position signal of the door unit 31 input from the movable cover detection unit 91.

Next, the actuator control unit 82 determines whether or not a predetermined time has elapsed since the movable cover 61 was positioned at the third position Pc (S107). In this step, the actuator control unit 82 determines whether or not a predetermined time has elapsed based on the time after the position signal of the door unit 31 corresponding to the third position Pc is input.

Next, as shown in FIGS. 6 and 7, the movable cover 61 is slid (retracted) from the third position Pc to the fourth position Pd (S108). In this step, the actuator control unit 82 controls the actuator 66 so that the movable cover 61 retracts when it is determined in S107 that a predetermined time has elapsed.

According to such a configuration, by moving the movable cover 61 in conjunction with the opening operation of the door portion 31, it is possible to more reliably prevent the oil mist from leaking from the processing area 110. Further, the oil mist can be captured by the movable cover 61 within a predetermined time after the movable cover 61 is positioned at the third position Pc.

FIG. 14 is a flowchart showing a second specific example of the timing of sliding the movable cover.

With reference to FIGS. 12 and 14, specifically, when the actuator control unit 82 completes the work processing execution program in the machining area 110, the movable cover 61 moves from the fourth position Pd to the third position Pc. The actuator 66 is controlled so as to operate toward. The actuator control unit 82 controls the actuator 66 so that the movable cover 61 operates from the third position Pc to the fourth position Pd when a command from the operator is received.

More specifically, as shown in FIGS. 4 and 5, the work is machined in the machining area 110 (S201). In this step, the program execution unit 84 reads the command of the execution program stored in the program storage unit 83, and outputs a control signal to each of the spindle control unit 86 and the feed control unit 85. During the work processing, the door portion 31 is positioned at the second position Pb. The movable cover 61 is positioned at the fourth position Pd.

Next, the work processing is completed (S202). In this step, the actuator control unit 82 recognizes the completion of the work processing by referring to the execution program executed by the program execution unit 84.

Next, as shown in FIGS. 2 and 3, the movable cover 61 is slid (advanced) from the fourth position Pd toward the third position Pc (S203). In this step, the actuator control unit 82 controls the actuator 66 so that the movable cover 61 advances when the work processing is completed in S202.

Next, the door portion 31 is slid (opened) from the second position Pb toward the first position Pa (S204). In this step, the operator slides the door portion 31 in the −Z axis direction.

Next, the operator inputs the retracting operation of the movable cover 61 to the input unit 94 (S205). In this step, the input unit 94 commands the actuator control unit 82 to retract the movable cover 61 input by the operator.

Next, the movable cover 61 is slid (retracted) from the third position Pc to the fourth position Pd (S206). In this step, the actuator control unit 82 controls the actuator 66 so that the movable cover 61 retracts based on the command from the input unit 94 in the step of S205.

According to such a configuration, since the movable cover 61 is immediately advanced after the work processing is completed, the advanced operation of the movable cover 61 can be easily preceded by the opening operation of the door portion 31. This makes it possible to more reliably prevent oil mist from leaking from the processing area 110. Further, since the command from the operator is used as a trigger for the retracting operation of the movable cover 61, the timing of the retracting operation of the movable cover 61 can be freely determined.

FIG. 15 is a flowchart showing a third specific example of the timing of sliding the movable cover.

With reference to FIGS. 12 and 15, specifically, when the actuator control unit 82 completes the work processing execution program in the machining area 110, the movable cover 61 moves from the fourth position Pd to the third position Pc. The actuator 66 is controlled so as to operate toward. The actuator control unit 82 controls the actuator 66 so that the movable cover 61 operates from the third position Pc to the fourth position Pd when a program for loading and unloading the work is executed inside and outside the machining area 110. ..

The steps S301 to S304 in this specific example correspond to the steps S201 to S204 in the specific example 2 in FIG. 14, respectively. In this specific example, the door portion 31 is an automatic door that is slid by an actuator such as a cylinder or a motor. In S304, the program execution unit 84 opens the door unit 31 according to the execution program stored in the program storage unit 83.

Next, when the command for loading / unloading the work is executed, the movable cover 61 is slid (retracted) from the third position Pc to the fourth position Pd (S305). In this step, the program execution unit 84 operates the loader (not shown) according to the execution program stored in the program storage unit 83. The actuator control unit 82 recognizes a command for loading and unloading the work with reference to the execution program executed by the program execution unit 84. The actuator control unit 82 controls the actuator 66 so that the movable cover 61 retracts when the command for loading / unloading the work is recognized.

According to such a configuration, it is possible to prevent the work from being carried in and out through the upper opening 28 from being obstructed by the movable cover 61.

Summarizing the structure of the processing machine 10 according to the embodiment of the present invention described above, the processing machine 10 according to the present embodiment has the cover body 21 provided with the opening 26 and the opening 26 in an open state. A door portion 31 that operates between the first position Pa and the second position Pb that closes the opening 26 and forms a processing area 110 together with the cover body 21 when positioned at the second position Pb. To prepare for. The opening 26 includes a front opening 27 arranged in front of the machine in the machining area 110, and an upper opening 28 connected to the front opening 27 and located above the machining area 110. The processing machine 10 operates between the third position Pc that overlaps the upper opening 28 and the fourth position Pd that is farther from the upper opening 28 than the third position Pc in the top view, and produces oil mist as suspended particles. A catchable portion 51 (movable cover 61) is further provided.

According to the processing machine 10 configured in this way, it is possible to prevent oil mist from leaking from the processing area 110 and improve the convenience of the processing machine 10.

The machining machine in the present invention is not limited to a lathe, and may be, for example, a vertical machining center or a horizontal machining center, and is a combined machining having a turning function using a fixed tool and a milling function using a rotary tool. It may be a machine.

Further, the machine may be an add processing machine capable of adding work (AM (Additive manufacturing) processing), or AM capable of adding work and removing work (SM (Subtractive manufacturing) processing). / SM hybrid processing machine may be used. In these cases, the suspended particles that can be captured by the capture unit in the present invention may be a fume in which a gas such as high-temperature metal vapor is suspended as solid fine particles.

It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

The present invention applies to machine tools, additive processing machines, AM / SM hybrid processing machines and the like.

10 Machining machine, 12 turret, 14 1st side cover, 15 operation panel, 16 2nd side cover, 17 work spindle, 18 splash guard, 19 ceiling cover, 21 cover body, 26 opening, 27 front opening, 28 Upper opening, 31 door, 32 upper door, 33 front door, 34 transparent window, 41 mist collector, 42 mist collector body, 43 switching mechanism, 46 1st duct, 46p, 48p intake port, 48th 2 duct, 51 capture part, 61 movable cover, 62 bottom surface, 62j center part, 62k peripheral part, 66 actuator, 71 saucer part, 81 control device, 82 actuator control part, 83 program storage part, 84 program execution part, 85 feed Control unit, 86 spindle control unit, 87 motor, 88 spindle motor, 91 movable cover detection unit, 92 door detection unit, 93 mist detection unit, 94 input unit, 101 rotation center axis, 102 rotation center axis, 110 machining area, Pa 1st position, Pb 2nd position, Pc 3rd position, Pd 4th position.

A processing machine according to one aspect of the present invention operates between a cover body provided with an opening, a first position in which the opening is open, and a second position in which the opening is closed. , A door portion that partitions and forms a processing area together with a cover body when positioned at the second position is provided. The opening includes a front opening located in front of the machine in the machining area and an upper opening extending from the front opening and located above the machining area. The processing machine operates between a third position that overlaps the upper opening in the top view and a fourth position that is farther from the opening above the third position, and is used as a catching part capable of catching suspended particles and a catching part. It further comprises an actuator that is connected and operates the capture unit between the third and fourth positions, and an actuator control unit that controls the actuator.
A processing machine according to another aspect of the present invention operates between a cover body provided with an opening, a first position in which the opening is open, and a second position in which the opening is closed. , A door portion that partitions and forms a processing area together with a cover body when positioned at the second position is provided. The opening includes a front opening located in front of the machine in the machining area and an upper opening extending from the front opening and located above the machining area. The processing machine operates between a third position that overlaps the upper opening in top view and a fourth position that is farther from the opening above the third position, and further includes a catching portion capable of capturing suspended particles.

Claims (14)

A cover body with an opening and
It operates between the first position where the opening is opened and the second position where the opening is closed, and when positioned at the second position, a processing area is formed together with the cover body. Equipped with a door to
The opening includes a front opening located in front of the machine in the machining area and an upper opening connected to the front opening and located above the machining area, and further.
A processing machine having a catching portion that operates between a third position that overlaps with the upper opening in a top view and a fourth position that is farther from the upper opening than the third position and can capture suspended particles. The processing machine according to claim 1, wherein the catching portion includes a movable cover. The suspended particles are mist and
The movable cover includes a bottom surface facing the machining area when positioned at the third position.
The processing machine according to claim 2, wherein the bottom surface has a shape in which the central portion of the bottom surface projects upward from the peripheral edge portion of the bottom surface. The processing machine according to claim 3, further comprising a saucer portion having a saucer shape and being arranged below the peripheral edge portion of the bottom surface. The door portion includes an upper door portion that closes the upper opening portion when positioned at the second position.
The movable cover is arranged in place of the upper door portion at the position of the upper door portion when the door portion is positioned at the second position when the movable cover is positioned at the third position. The processing machine according to any one of 2 to 4. Further equipped with a recovery device including a duct and collecting suspended particles through the intake port of the duct.
The processing machine according to any one of claims 1 to 5, wherein the catching portion includes an intake port of the duct. The processing machine according to any one of claims 1 to 6, wherein the catching portion slides between the third position and the fourth position in the front-rear direction of the machine or in the left-right direction of the machine. An actuator connected to the capture unit and operating the capture unit between the third position and the fourth position.
The processing machine according to any one of claims 1 to 7, further comprising an actuator control unit for controlling the actuator. The actuator control unit is such that when the door unit operates from the second position to the first position, the capture unit operates from the fourth position to the third position. The processing machine according to claim 8. The actuator control unit controls the actuator so that the capture unit operates from the fourth position to the third position when the execution program of workpiece processing in the processing area is completed. Item 8. The processing machine according to Item 8 or 9. The actuator control unit controls the actuator so that the capture unit operates from the third position to the fourth position after a predetermined time has elapsed after the capture unit is positioned at the third position. The processing machine according to any one of claims 8 to 10. One of claims 8 to 11, wherein the actuator control unit controls the actuator so that the capture unit operates from the third position to the fourth position when a command is received from the operator. The processing machine according to item 1. Further equipped with a detection unit capable of detecting suspended particles in the processing area,
The actuator control unit controls the actuator so that the capture unit operates from the third position to the fourth position when it is determined that the amount of suspended particles detected by the detection unit is equal to or less than a predetermined amount. The processing machine according to any one of claims 8 to 12, which is controlled. The actuator control unit controls the actuator so that the capture unit operates from the third position to the fourth position when a program for loading and unloading a work is executed inside and outside the machining area. , The processing machine according to any one of claims 8 to 13.

Images