JP6961848B1 - Machine Tools - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a machine tool capable of efficiently performing a cleaning operation using a coolant. A machine tool is provided with a first coolant discharge unit 31 to which coolant is supplied from a pump 37 and discharges the coolant toward a machining area 110, and a position separated from the first coolant discharge unit 31 to supply the coolant. A second coolant discharge section 51 for discharging toward the processing area 110 and a coolant receiving port 42 for receiving the coolant discharged from the first coolant discharging section 31 are provided, and the second coolant discharging section 51 is connected to the coolant receiving port 42. It is provided with a coolant guide unit 41 that guides the received coolant toward the second coolant discharge unit 51. [Selection diagram] Fig. 2

Description

The present invention relates to a machine tool.

For example, Japanese Patent Application Laid-Open No. 2007-30142 (Patent Document 1) discloses a machine tool provided with a shower coolant device. The shower coolant device includes a coolant supply source such as a coolant pump, a coolant pipe to which coolant is supplied from the coolant liquid supply source, and a plurality of coolant nozzles attached to the coolant pipe and opened in a processing region.

JP-A-2007-30142

As disclosed in Patent Document 1 described above, a machine tool provided with a coolant discharge unit (coolant nozzle) is known. In such a machine tool, a cleaning operation of removing chips from a work or a work holder for holding the work is performed by using the coolant discharged from the coolant discharge portion.

However, the position of the coolant discharge portion provided in the machine tool is predetermined. Therefore, the coolant discharged from the coolant discharge portion cannot be supplied to a desired location, and foreign matter such as chips may remain on the work or the work holder. In particular, when the work is automatically replaced with respect to the work holder using a robot arm or the like, there is a high possibility that foreign matter such as chips remains because the work is not manually attached and detached. In this case, there arises a problem that foreign matter such as chips is caught between the work and the work holder, which hinders accurate positioning of the work.

Therefore, an object of the present invention is to solve the above-mentioned problems, and to provide a machine tool capable of efficiently performing a cleaning operation using a coolant.

A machine tool according to one aspect of the present invention is provided with a first coolant discharge section in which coolant is supplied from a pump and the coolant is discharged toward a space, and a position separated from the first coolant discharge section to discharge the coolant. A second coolant discharge section that discharges toward the space and a coolant receiver that receives the coolant discharged from the first coolant discharge section are provided, the second coolant discharge section is connected, and the coolant received by the coolant receiver is the second coolant. A coolant guide portion for guiding toward the discharge portion, a work holder for holding the work by connecting the second coolant discharge portion, and a cover body for partitioning the space are provided. The work holder is provided with a first coolant flow path that guides the coolant received by the coolant receiving port toward the second coolant discharging portion. The coolant guide includes a work holder.
A machine tool according to another aspect of the present invention is provided with a first coolant discharge section in which coolant is supplied from a pump and the coolant is discharged toward a space, and a position separated from the first coolant discharge section to discharge the coolant. A second coolant discharge section that discharges toward the space and a coolant receiver that receives the coolant discharged from the first coolant discharge section are provided, the second coolant discharge section is connected, and the coolant received by the coolant receiver is the second coolant. It is provided with a coolant guide unit that guides the discharge unit.

According to the machine tool configured in this way, the coolant discharged from the first coolant discharge part toward the space is once received at the coolant receiving port, and the coolant is guided toward the second coolant discharge part by the coolant guide part. Then, it is discharged from the second coolant discharge part toward the space. As a result, the coolant can be supplied to a desired location in the space by appropriately determining the position of the second coolant discharge portion. Therefore, the cleaning operation using the coolant can be efficiently performed.

Further, preferably, the coolant guide portion includes a tank portion provided with a coolant receiving port and capable of storing the coolant.

According to the machine tool configured in this way, the coolant discharged from the first coolant discharge portion is temporarily stored in the tank portion. Therefore, the coolant can be discharged from the second coolant discharge unit even at the timing when the coolant is not discharged from the first coolant discharge unit.

Further, preferably, the coolant guide portion includes a mesh body provided in the coolant receiving port.

According to the machine tool configured in this way, it is possible to prevent foreign matter such as chips from being mixed into the coolant guided toward the second coolant discharge portion.

Also preferably, the machine tool further comprises a cover that partitions the space. The first coolant discharge portion is provided on the ceiling portion of the cover body.

According to the machine tool configured in this way, the coolant discharged from the first coolant discharge portion falls downward from the ceiling portion of the cover body, so that the coolant can be efficiently received by the coolant receiver. ..

Further, preferably, the machine tool has a spindle coolant mechanism portion for discharging coolant toward the machining area, and includes a tool spindle for rotating the tool. The first coolant discharge unit includes a spindle coolant mechanism unit.

According to the machine tool configured in this way, since the high-pressure coolant is discharged from the spindle coolant mechanism portion, the coolant can be efficiently received by the coolant receiving port.

Also preferably, the machine tool includes a plurality of second coolant discharge units. The coolant guide unit guides the coolant received by the coolant receiving port toward each of the plurality of second coolant discharge units.

According to the machine tool configured in this way, the coolant can be supplied to a desired plurality of locations in the space by appropriately determining the positions of the plurality of second coolant discharge portions.

Further, preferably, the machine tool is provided with a work holder for holding the work to which the second coolant discharge portion is connected. The work holder is provided with a first coolant flow path that guides the coolant received by the coolant receiving port toward the second coolant discharging portion. The coolant guide includes a work holder.

According to the machine tool configured in this way, foreign matter such as chips can be more reliably removed from the work held by the work holder or the work holder.

Further, preferably, a locate member for positioning the work is connected to the work holder by contacting the work. The locate member is provided with a second coolant flow path that communicates with the first coolant flow path and opens into the space. The second coolant discharge unit includes a locate member.

According to the machine tool configured in this way, it is possible to prevent foreign matter such as chips from adhering between the work and the locate member. Thereby, the positioning of the work in the work holder can be performed with higher accuracy.

As described above, according to the present invention, it is possible to provide a machine tool capable of efficiently performing a cleaning operation using a coolant.

It is a perspective view which shows the machine tool in Embodiment 1 of this invention. It is a perspective view which shows the inside of the processing area of the machine tool in FIG. It is sectional drawing which shows the inside of the processing area of the machine tool in FIG. It is a perspective view which shows the main part of the coolant guide part in FIG. 2 and the 2nd coolant discharge part. It is a perspective view which shows the state which the work is held by the work holder in FIG. It is a perspective view which shows the 1st coolant discharge part and the coolant guide part in the machine tool of Embodiment 2 of this invention. 6 is a cross-sectional view showing a first coolant discharging portion and a coolant guiding portion as viewed in the direction of arrow on the line VII-VII in FIG. 6 is a cross-sectional view showing a modified example of the coolant guide portion in FIGS. 6 and 7. It is a perspective view which shows the coolant guide part and the 2nd coolant discharge part in the machine tool of Embodiment 3 of this invention.

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 given the same number.

(Embodiment 1)
FIG. 1 is a perspective view showing a machine tool according to the first embodiment of the present invention. With reference to FIG. 1, the machine tool 10 in the present embodiment is a machining center for machining a work by bringing a rotating tool into contact with the work, and more specifically, the rotation center axis 101 of the tool is horizontal. A horizontal machining center that extends in the direction. The machine tool 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 FIG. 1 and the drawings described below, "X-axis", "Y-axis" and "Z-axis" which are orthogonal to each other are appropriately shown. The "X-axis" is an axis parallel to the horizontal direction and orthogonal to the rotation center axis 101 of the tool, the "Y-axis" is an axis parallel to the vertical direction, and the "Z-axis" is the horizontal direction. It is an axis parallel to and parallel to the rotation center axis 101 of the tool.

The machine tool 10 has a cover body 21. The cover body 21 forms the processing area 110 and the setup station 120, and has the appearance of the machine tool 10.

The processing area 110 is a space in which the work is processed, and is sealed so that foreign matter such as chips or cutting oil accompanying the work processing does not leak to the outside of the processing area 110. The setup station 120 is provided adjacent to the machining area 110 in the Z-axis direction. The setup station 120 is a space where the work is attached. The machine tool 10 further includes an automatic pallet changer (APC: Automatic Pallet Changer) for changing the pallet 18 (see FIG. 3 below) on which the workpiece is mounted between the machining area 110 and the setup station 120. ..

The cover body 21 has a front cover 23, a front door 25, and a ceiling cover 22. The front cover 23, the front door 25, and the ceiling cover 22 form a processing area 110.

The front cover 23 is provided with a cover opening 26. The cover opening 26 opens the processing area 110 to the external space. The front door 25 is provided in the cover opening 26. The front door 25 can slide between an open position in which the cover opening 26 is in the open state and a closed position in which the cover opening 26 is in the closed state (the position of the front door 25 shown in FIG. 1). Is. The ceiling cover 22 constitutes the ceiling portion of the cover body 21. The ceiling cover 22 is arranged above the processing area 110.

The cover body 21 further includes a setup station cover 27 and a setup station door 28. The setup station cover 27 and the setup station door 28 form a section for the setup station 120.

The setup station cover 27 is provided with a cover opening 29. The cover opening 29 opens the setup station 120 to the external space. The setup station door 28 is provided in the cover opening 29. The setup station door 28 rotates between the open position in which the cover opening 29 is in the open state and the closed position in which the cover opening 29 is in the closed state (the position of the setup station door 28 shown in FIG. 1). It can be moved.

The machine tool 10 further includes a tool spindle 12 and a table 15 (see FIG. 3 below). The tool spindle 12 and the table 15 are provided in the machining area 110.

The tool spindle 12 is provided so as to be movable in the X-axis direction and the Y-axis direction. The tool spindle 12 is rotatably provided around a rotation center shaft 101 parallel to the Z axis by a motor drive. The tool spindle 12 holds a tool for machining a work in the machine tool 10. As the tool spindle 12 rotates, the tool held by the tool spindle 12 rotates about the rotation center axis 101.

The table 15 is a device for holding the work. The table 15 holds the work at a position facing the tool spindle 12 in the Z-axis direction. The table 15 is provided so as to be movable in the Z-axis direction. The table 15 is provided so as to be rotatable around a rotation center axis 106 (see FIG. 3 described later) extending in the Y-axis direction.

The machine tool in the present invention is not limited to a horizontal machining center, for example, a lathe, a vertical machining center, a multi-tasking machine having a turning function and a milling function, or an additional machining (AM (Additive manufacturing) machining) of a workpiece. It is also applicable to AM / SM hybrid processing machines capable of removing workpieces (SM (Subtractive manufacturing) processing).

FIG. 2 is a perspective view showing the inside of the machining area of the machine tool in FIG. FIG. 3 is a cross-sectional view showing the inside of the machining area of the machine tool in FIG. With reference to FIGS. 2 and 3, the machine tool 10 has a pump 37 and a first coolant discharge section 31.

The pump 37 is provided in a coolant tank (not shown) installed outside the processing area 110. The pump 37 supplies the coolant stored in the coolant tank toward the first coolant discharge unit 31. The first coolant discharge unit 31 discharges the coolant supplied from the pump 37 toward the processing area 110.

The first coolant discharge portion 31 is provided in the processing area 110. The first coolant discharge portion 31 is provided on the ceiling portion (ceiling cover 22) of the cover body 21. The first coolant discharge unit 31 constitutes a shower coolant that drops the coolant from above the processing area 110.

More specifically, the machine tool 10 has a coolant pipe 36 and a plurality of first coolant discharge portions 31.

The coolant pipe 36 is made of a pipe material through which coolant can flow. The coolant pipe 36 is provided in the processing area 110. The coolant pipe 36 is attached to the ceiling cover 22. The coolant pipe 36 extends in the Z-axis direction. Two coolant pipes 36 are attached to the ceiling cover 22 at positions separated from each other in the X-axis direction.

The first coolant discharge unit 31 is made of a resin nozzle body. The first coolant discharge unit 31 is connected to the coolant pipe 36. The plurality of first coolant discharge portions 31 are arranged in the Z-axis direction with a gap from each other. The plurality of first coolant discharge portions 31 are arranged in the moving direction of the table 15 at intervals from each other.

The first coolant discharge portion 31 has a nozzle tip portion 33, a plurality of hose portions 34, and a connector portion 35.

The connector portion 35 is provided with a screw, and the connector portion 35 is connected to the coolant pipe 36 via the screw portion. The hose portion 34 is rotatably connected to the connector portion 35. The plurality of hose portions 34 are connected from the connector portion 35 toward the nozzle tip portion 33. The plurality of hose portions 34 are connected so as to be rotatable with each other. The nozzle tip 33 is rotatably connected to the hose 34. The nozzle tip 33 has a tapered tubular shape. The nozzle tip 33 is provided with a discharge port 32 for discharging the coolant.

The position of the discharge port 32 (of the coolant) by rotating the connection portion of the connector portion 35 and the hose portion 34, the connection portion between the plurality of hose portions 34, or the connection portion between the hose portion 34 and the nozzle tip portion 33. The discharge position) and the direction in which the discharge port 32 opens (coolant discharge direction) can be adjusted.

The structure and arrangement of the first coolant discharge unit 31 described above is an example, and is not particularly limited in the present invention. For example, the first coolant discharge unit may be composed of a metal nozzle body, or may be configured such that a coolant discharge port is provided directly on the coolant pipe 36. The plurality of first coolant discharge portions may be arranged so as to be spaced apart from each other in the Y-axis direction or the X-axis direction.

The machine tool 10 further includes a second coolant discharge unit 51 and a coolant guide unit 41.

The second coolant discharge portion 51 is provided in the processing area 110. The second coolant discharge unit 51 is provided at a position away from the first coolant discharge unit 31. The second coolant discharge unit 51 is provided below the first coolant discharge unit 31. The second coolant discharge unit 51 discharges the coolant toward the processing area 110. The second coolant discharge unit 51 discharges the coolant at a position lower than that of the first coolant discharge unit 31.

The coolant guide portion 41 is provided in the processing area 110. The coolant guide portion 41 is provided with a coolant receiving port 42. The coolant receiving port 42 receives the coolant discharged from the first coolant discharging unit 31. The coolant receiving port 42 includes an opening that opens in a space (processing area 110) where coolant is discharged from the first coolant discharging portion 31. The coolant receiving port 42 is provided below the first coolant discharging portion 31. The coolant receiving port 42 is provided above the second coolant discharging portion 51.

A second coolant discharge unit 51 is connected to the coolant guide unit 41. The coolant guide unit 41 guides the coolant received by the coolant receiving port 42 toward the second coolant discharge unit 51. The coolant guided by the coolant guide portion 41 flows from the coolant receiving port 42 toward the second coolant discharge portion 51 by gravity.

FIG. 4 is a perspective view showing a main part of the coolant guide part in FIG. 2 and a second coolant discharge part. FIG. 5 is a perspective view showing a state in which the work is held by the work holder in FIG.

With reference to FIGS. 2 to 5, the coolant guide 41 has a work holder 61. The work holder 61 is a device for holding the work. The work holder 61 is provided on the table 15. The work holder 61 is fixed to a pallet 18 mounted on the table 15.

The work holder 61 is made of a metal block body. The work holder 61 has a base portion 62 and a work holding portion 63. The base portion 62 has a plate shape that is arranged in parallel in the horizontal direction. The base portion 62 is fastened to the pallet 18 using bolts or the like.

The work holding portion 63 has a plate shape that rises upward from the base portion 62. The work holding portion 63 is provided with a clamp mechanism portion 71 for holding the work detachably, a locate member 76 for positioning the work, and the like.

The work holding portion 63 has a top surface 63a and a side surface 63b. The top surface 63a is formed of a plane parallel to the X-axis-Z-axis plane and faces upward. The top surface 63a faces the ceiling portion (ceiling cover 22) of the cover body 21 in the vertical direction. The side surface 63b is formed of a plane parallel to the Y axis and faces the horizontal direction. The direction in which the side surface 63b faces changes with the turning operation of the table 15 about the turning center axis 106. The clamp mechanism portion 71 and the locate member 76 are provided on the side surface 63b.

The work holder 61 is provided with a first coolant flow path 66. The work holding portion 63 is provided with a hole through which coolant can flow, and the first coolant flow path 66 is composed of the hole. The first coolant flow path 66 is configured by connecting a plurality of holes extending linearly.

The first coolant flow path 66 forms a flow path through which the coolant received by the coolant receiving port 42 flows toward the second coolant discharging portion 51. The first coolant flow path 66 is open to the top surface 63a and the side surface 63b. The first coolant flow path 66 is open at a plurality of locations on the side surface 63b.

The coolant guide portion 41 further includes a tank portion 43. The tank portion 43 includes a housing capable of storing coolant. The tank portion 43 is open so as to face upward. The coolant receiving port 42 is composed of an opening formed by the tank portion 43. The tank portion 43 is fixed to the work holder 61 (work holding portion 63). The tank portion 43 is placed on the top surface 63a. The space in the tank portion 43 for storing the coolant communicates with the first coolant flow path 66 that opens to the top surface 63a.

The tank portion 43 is provided above the work holder 61 and below the first coolant discharge portion 31. The tank portion 43 is provided above the second coolant discharge portion 51.

The machine tool 10 has a plurality of second coolant discharge portions 51. A plurality of second coolant discharge portions 51 are connected to the work holder 61. The plurality of second coolant discharge portions 51 are provided at positions separated from each other. The coolant guide unit 41 guides the coolant received by the coolant receiving port 42 toward each of the plurality of second coolant discharge units 51.

The second coolant discharge portion 51 has a connector portion 54 and a pipe 53. The connector portion 54 is provided with a screw portion, and the connector portion 54 is connected to the work holder 61 (work holding portion 63) via the screw portion. The connector portion 54 is connected to the side surface 63b. The connector portion 54 communicates with the first coolant flow path 66 that opens on the side surface 63b.

The pipe 53 is connected to the connector portion 54. The pipe 53 is made of a metal pipe such as a copper pipe, for example. A discharge port 52 for discharging coolant is provided at the tip of the pipe 53. By bending the pipe 53, the position of the discharge port 52 (the discharge position of the coolant) and the direction in which the discharge port 52 opens (the discharge direction of the coolant) can be adjusted.

The discharge port 52 is opened between the plurality of second coolant discharge portions 51 so as to face different directions from each other. The discharge port 52 may be opened in the same direction between at least two second coolant discharge portions 51 among the plurality of second coolant discharge portions 51. The discharge port 52 may be opened toward the work W, the clamp mechanism portion 71, or the locate member 76.

Normally, the first coolant discharge unit 31 used as the in-machine coolant is provided at a position away from the work holder 61, so that the coolant from the first coolant discharge unit 31 is clamped to the work W in the work holder 61. It is difficult to efficiently clean the details such as the mechanical portion 71 or the locate member 76 by supplying them.

On the other hand, in the present embodiment, the coolant discharged from the first coolant discharge unit 31 toward the processing area 110 is once received by the coolant receiving port 42. Then, the coolant is guided toward each of the plurality of second coolant discharge portions 51 through the first coolant flow path 66 in the coolant guide portion 41 (work holder 61), and the work W is guided from each of the second coolant discharge portions 51. , Discharge toward the clamp mechanism 71 or the locate member 76. As a result, the coolant can be supplied to a desired portion of the work holder 61, so that the cleaning operation using the coolant can be efficiently performed.

Further, the coolant guide portion 41 has a tank portion 43 provided with a coolant receiving port 42. With such a configuration, the coolant discharged from the first coolant discharge unit 31 toward the processing area 110 is temporarily stored in the tank unit 43. As a result, even when the coolant is not discharged from the first coolant discharge unit 31, the coolant can be discharged from the second coolant discharge unit 51, so that the cleaning operation using the coolant can be performed more efficiently. ..

Further, the first coolant discharge portion 31 is provided on the ceiling portion of the cover body 21. With such a configuration, the coolant discharged from the first coolant discharging portion 31 and falling in the processing area 110 can be efficiently received by the coolant receiving port 42.

The first coolant flow path that guides the coolant received at the coolant receiving port 42 toward the second coolant discharging portion 51 is not limited to the hole provided in the work holding portion 63, but is arranged around the work holding portion 63. It may be composed of a pipe member to be searched.

Summarizing the structure of the machine tool 10 according to the first embodiment of the present invention described above, in the machine machine 10 according to the present embodiment, coolant is supplied from the pump 37 and the coolant is directed to the processing area 110 as a space. From the first coolant discharge unit 31 and the second coolant discharge unit 51, which is provided at a position away from the first coolant discharge unit 31 and discharges the coolant toward the processing area 110, and the first coolant discharge unit 31. A coolant receiving port 42 for receiving the discharged coolant is provided, a second coolant discharging part 51 is connected, and a coolant guiding part 41 for guiding the coolant received by the coolant receiving part 42 toward the second coolant discharging part 51 is provided.

According to the machine tool 10 according to the first embodiment of the present invention configured as described above, the cleaning operation using the coolant is efficiently performed by supplying the coolant to the desired portion of the work holder 61. Can be done.

In the present embodiment, the case where the first coolant discharge unit 31 is an in-machine coolant that discharges the coolant toward the processing area 110 has been described, but the present invention is not limited to this. The first coolant discharge unit in the present invention may be, for example, one that discharges coolant into the setup station 120.

(Embodiment 2)
FIG. 6 is a perspective view showing a first coolant discharging portion and a coolant guiding portion in the machine tool according to the second embodiment of the present invention. FIG. 7 is a cross-sectional view showing a first coolant discharging portion and a coolant guiding portion as viewed in the direction of arrow on the VII-VII line in FIG. The machine tool in the present embodiment basically has the same structure as the machine tool 10 in the first embodiment. Hereinafter, the description of the overlapping structure will not be repeated.

With reference to FIGS. 6 and 7, in the present embodiment, the coolant receiving port 42 is provided in the work holder 61 (work holding portion 63).

The coolant receiving port 42 is opened so as to face the horizontal direction. The coolant receiving port 42 is open to the side surface 63b. The coolant receiving port 42 is provided so that the opening area of the coolant receiving port 42 increases as the distance from the side surface 63b increases. The coolant receiving port 42 communicates with the first coolant flow path 66. The first coolant flow path 66 is provided in the work holding portion 63, and includes a hole extending from the coolant receiving port 42 toward the second coolant discharging portion 51.

The tool spindle 12 has a spindle coolant mechanism 81. The spindle coolant mechanism 81 discharges the coolant through the tool spindle 12 toward the machining area 110. The first coolant discharge unit 31 is composed of a spindle coolant mechanism 81.

The spindle coolant mechanism 81 discharges coolant in the axial direction of the rotation center shaft 101 from the cutting edge of the tool T held by the tool spindle 12. The tool spindle 12 is provided with a coolant flow path 82 in the spindle. The coolant flow path 82 in the spindle extends on the axis of the rotation center axis 101. The tool T held by the tool spindle 12 is provided with an in-tool coolant flow path 86. The in-tool coolant flow path 86 extends on the axis of the rotation center shaft 101 and communicates with the in-spindle coolant flow path 82. The coolant flows through the coolant flow path 82 in the spindle and the coolant flow path 86 in the tool in order, and is discharged to the machining area 110. The opening surface formed by the coolant receiving port 42 preferably extends in a direction intersecting the direction in which the coolant is discharged from the tool T.

By moving the tool spindle 12 in the X-axis direction and the Y-axis direction and moving the table 15 in the Z-axis direction, the tool T held by the tool spindle 12 is arranged to face the opening formed by the coolant receiving port 42. The first coolant discharge unit 31 (main shaft coolant mechanism 81) discharges coolant from the cutting edge of the tool T. The coolant discharged from the tool T is introduced into the first coolant flow path 66 through the coolant receiving port 42.

According to such a configuration, the coolant discharged at high pressure from the cutting edge of the tool T can be efficiently received by the coolant receiving port 42 provided in the work holding portion 63.

FIG. 8 is a cross-sectional view showing a modified example of the coolant guide portion in FIGS. 6 and 7. With reference to FIG. 8, in this modification, the coolant guide portion 41 has a cover portion 46. The cover portion 46 is open so as to face the horizontal direction. The coolant receiving port 42 is composed of an opening formed by the cover portion 46. The cover portion 46 is fixed to the work holding portion 63 (work holder 61). The cover portion 46 is placed on the top surface 63a. The space in the cover portion 46 to which the coolant is supplied communicates with the first coolant flow path 66 that opens to the top surface 63a.

The coolant guide 41 further includes a mesh body 48. The mesh body 48 is provided in the coolant receiving port 42. The mesh body 48 is provided so as to cover the opening formed by the cover portion 46. The mesh body 48 is made of a mesh-like sheet in which fine holes are lined up.

According to such a configuration, the coolant discharged at high pressure from the cutting edge of the tool T can be efficiently received by the coolant receiving port 42 provided in the cover portion 46. At this time, the mesh body 48 provided in the coolant receiving port 42 can remove foreign substances such as chips from the coolant guided toward the second coolant discharging portion 51 through the coolant receiving port 42.

According to the machine tool according to the second embodiment of the present invention configured in this way, the effect described in the first embodiment can be similarly exhibited.

The mesh body in the present invention may be provided at the coolant receiving port 42 formed by the tank portion 43 in FIG. 2, or may be provided at the coolant receiving port 42 formed by the work holder 61 in FIGS. 6 and 7. good.

(Embodiment 3)
FIG. 9 is a perspective view showing a coolant guide portion and a second coolant discharge portion in the machine tool according to the third embodiment of the present invention. The machine tool in the present embodiment basically has the same structure as the machine tool 10 in the first embodiment. Hereinafter, the description of the overlapping structure will not be repeated.

With reference to FIG. 9, a locate member 76 is connected to the work holder 61 (work holding portion 63). The locate member 76 positions the work W by abutting on the work W. The locate member 76 is made of a metal pin.

The locate member 76 has a contact surface 76c. The contact surface 76c corresponds to an end surface of the locate member 76 arranged at one end in the axial direction thereof. The contact surface 76c comes into contact with the work W. The locate member 76 is provided with a second coolant flow path 91. The locate member 76 is provided with a through hole extending in the axial direction thereof, and the second coolant flow path 91 is composed of the hole.

The second coolant flow path 91 is open to the processing area 110. The second coolant flow path 91 is open to the contact surface 76c. The opening of the second coolant flow path 91 on the contact surface 76c constitutes a discharge port 92 for discharging the coolant. The second coolant flow path 91 communicates with the first coolant flow path 66 that opens on the side surface 63b. The second coolant discharge portion 51 is composed of a locate member 76.

According to such a configuration, the coolant is discharged to the processing area 110 through the second coolant flow path 91 provided in the locate member 76, so that the coolant can be accurately located at the contact point between the work W and the locate member 76. Can be supplied. As a result, foreign matter such as chips can be prevented from interposing between the work W and the locate member 76, and the work W can be positioned with higher accuracy in the work holder 61.

The outer peripheral surface of the locate member 76 may be configured to correspond to the contact surface that comes into contact with the work W. In this case, the second coolant flow path 91 may be opened on the outer peripheral surface of the locate member 76.

According to the machine tool according to the third embodiment of the present invention configured in this way, the effect described in the first embodiment can be similarly exhibited.

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 it is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

The present invention applies to machine tools such as machining centers or lathes.

10 Machine tools, 12 Tool spindles, 15 Tables, 18 pallets, 21 Covers, 22 Ceiling covers, 23 Front covers, 25 Front doors, 26, 29 Cover openings, 27 Setup station covers, 28 Setup station doors, 31 1st Coolant discharge part, 32, 52, 92 discharge port, 33 nozzle tip part, 34 hose part, 35, 54 connector part, 36 coolant piping, 37 pump, 41 coolant guide part, 42 coolant receiving port, 43 tank part, 46 cover part , 48 mesh body, 51 second coolant discharge part, 53 pipe, 61 work holder, 62 base part, 63 work holder, 63a top surface, 63b side surface, 66 first coolant flow path, 71 clamp mechanism part, 76 locate Member, 76c contact surface, 81 spindle coolant mechanism, 82 spindle coolant flow path, 86 tool in-tool coolant flow path, 91 second coolant flow path, 101 rotation center axis, 106 swivel center axis, 110 machining area, 120 setup station ..

Claims (7)

The first coolant discharge part, where coolant is supplied from the pump and the coolant is discharged toward the space,
A second coolant discharge unit provided at a position away from the first coolant discharge unit and discharging the coolant toward the space, and a second coolant discharge unit.
A coolant receiving port for receiving the coolant discharged from the first coolant discharging part is provided, the second coolant discharging part is connected, and the coolant received by the coolant receiving part is guided toward the second coolant discharging part. and parts,
A work holder for holding the work to which the second coolant discharge portion is connected, and
A cover body for partitioning the space is provided.
The work holder is provided with a first coolant flow path that guides the coolant received by the coolant receiving port toward the second coolant discharging portion.
The coolant guide is a machine tool including the work holder. The machine tool according to claim 1, wherein the coolant guide portion includes a tank portion provided with the coolant receiving port and capable of storing coolant. The machine tool according to claim 1 or 2, wherein the coolant guide portion includes a mesh body provided in the coolant receiving port. Before Symbol first coolant discharge part is provided in a ceiling portion of the cover body, the machine tool according to any one of claims 1 to 3. It has a spindle coolant mechanism that discharges coolant into the machining area, and has a tool spindle for rotating the tool.
The machine tool according to any one of claims 1 to 3, wherein the first coolant discharge unit includes the spindle coolant mechanism. It is provided with a plurality of the second coolant discharge units.
The machine tool according to any one of claims 1 to 5, wherein the coolant guide unit guides the coolant received by the coolant receiving port toward each of the plurality of second coolant discharge units. A locate member for positioning the work is connected to the work holder by contacting the work.
The locate member is provided with a second coolant flow path that communicates with the first coolant flow path and opens into the space.
The machine tool according to any one of claims 1 to 6, wherein the second coolant discharge unit includes the locate member.

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