JP2002018674A - Coolant liquid supply device of machining point automatic sighting type - Google Patents

Abstract

PROBLEM TO BE SOLVED: To automatically adjust a sighting angle of a coolant nozzle following movement of a machine without previously calculating a nozzle angle or preparing an angle command on an NC(numerical control) machining program. SOLUTION: This supply device comprises a coolant injection device 10 having a coolant nozzle 12 having variable sighting angle β when the coolant liquid is injected toward a machining point and a nozzle sighting and driving servo motor for changing the sighting angle β of the coolant nozzle 12 to direct the coolant nozzle to the machining point, and a nozzle sighting angle controlling means for always calculating a present position of the machining point of the work varying following movement of a feed shaft of the machine tool based on a moving amount of the feed shaft of the machine tool and controlling the sighting angle of the nozzle so as to follow positional change of the machining point.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a coolant supply apparatus for supplying a coolant to a cutting tool in a machine tool, and more particularly, to an automatic control of an irradiation angle of a coolant nozzle for ejecting a coolant, thereby constantly processing a workpiece. The present invention relates to a machining point automatic aiming type coolant liquid supply apparatus in which a coolant liquid is supplied to a workpiece.

[0002]

2. Description of the Related Art In the cutting of a work, a coolant liquid plays an important role such as lubrication of a cutting edge, cooling of a work, and removal of chips from a processing point. In particular, unmanned cutting with a machining center is an indispensable technical issue for ensuring the stability and safety of machining.

Conventionally, a coolant liquid is supplied from a coolant nozzle provided on a spindle or a nose end face of a spindle head to an external supply method for supplying a coolant liquid toward a cutting edge, or supplied from inside the spindle through a tool holder or the like. There is an internal supply method.

[0004] In the internal method, it is necessary to machine a coolant supply passage on the main shaft side or take measures against leakage, which increases the cost, and therefore the external supply method is widespread.

In a conventional coolant supply system of an external supply system, in order to apply coolant to a cutting point,
It is necessary to frequently adjust the nozzle angle of the coolant nozzle with the change of the tool length due to the movement of the cutting axis or the tool change. Conventionally, the operator has manually adjusted the nozzle angle while observing the progress of machining. However, with the automation and omission of machining, a nozzle angle command is incorporated in the NC machining program in advance, and NC
The nozzle angle is adjusted by a command from a machining program.

[0006]

However, in actual machining, there are various parameters defining the nozzle angle, such as the amount of spindle feed, the amount of movement of the cutting axis, and the length of the tool to be used. In order to supply the nozzle, an appropriate nozzle angle is calculated in advance based on the movement of the cutting axis during machining, the feed amount of the spindle, and the length of the tool to be used. And it took a lot of time to create a machining program in advance.

Accordingly, an object of the present invention is to solve the above-mentioned problems of the prior art, and to calculate the nozzle angle in advance and use the NC
It is an object of the present invention to provide a machining point automatic aiming type coolant liquid supply apparatus in which an irradiation angle of a coolant nozzle is automatically adjusted according to a machine movement without creating an angle command on a machining program.

[0008]

In order to achieve the above object, the invention according to claim 1 is arranged outside a main shaft of a numerically controlled machine tool, and a coolant liquid is supplied to a processing point of a workpiece by a tool by a nozzle. A coolant nozzle that changes the irradiation angle when spraying the coolant liquid toward the processing point, and directs the coolant nozzle to the processing point by changing the irradiation angle of the coolant nozzle. A coolant injection device having a servo motor for nozzle sighting drive for causing the position of the machining point of the workpiece to change with the movement of the feed axis of the machine tool, based on the movement amount of the feed axis of the machine tool. Calculating, nozzle irradiation angle control means for controlling the irradiation angle of the nozzle so as to follow the current position change of the processing point,
It is characterized by having.

According to the present invention, even when the workpiece is changed to a tool having a different tool length or when the machining point of the workpiece changes due to the movement of a feed axis such as a cutting axis for feeding the workpiece or a feed axis of the main spindle,
The irradiation angle of the coolant nozzle follows the movement of the tool length and the feed axis to automatically aim at the processing point, and the coolant liquid is reliably supplied to the processing point.

According to a second aspect of the present invention, in the first aspect of the invention, the nozzle irradiation angle control means includes: a nozzle angle detection means for detecting an irradiation angle of the coolant nozzle; Calculating means for calculating a target value of an irradiation angle necessary for accurately aiming at a processing point based on a current position of the processing point, and generating an irradiation angle command to be given to the coolant injection device; Nozzle angle control means for controlling the servomotor so that the detected value of the irradiation angle fed back from the angle detection means coincides with the target value of the angle.

According to a third aspect of the present invention, in the second aspect of the present invention, the arithmetic means comprises an arithmetic unit in a numerical control device, and the arithmetic unit includes a feed axis position control system in the direction of the main spindle axis and the feed axis. The present invention is characterized in that the current position of a machining point having the origin at the machining start position is calculated based on the amount of movement and the tool length given in advance.

[0012]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing an embodiment of an automatic machining type coolant supply device according to the present invention; FIG. 1 shows a table type horizontal boring milling machine to which a machining point automatic aiming type coolant liquid supply device according to the present invention is applied. In FIG. 1, reference numeral 1 denotes a column, 2 denotes a spindle head, and 3 denotes a spindle. The work 4 is fixed to a table 5. A tool 6 is attached to the tip of the main shaft 3.
In such a horizontal boring milling machine, as the tool 6,
A milling machine, an end mill, a drill, or the like is used, and a tool designated by a machining program is mounted on the spindle 3 by an automatic tool changer (not shown).

In this horizontal boring and milling machine, there are four axes for controlling the movement of the machine body, and the spindle head 2 can move in the vertical Y axis along the guide surface of the column 1. In the spindle head 2, the quill 8 is integrated with the spindle 3 in the axial direction (W
Axis). The table 4 can move an X axis perpendicular to the axial direction of the main shaft 3 and a Z axis parallel to the axial direction of the main shaft 3.

Reference numeral 10 denotes a work 4
Is a coolant jetting device for jetting a coolant liquid from the nozzle 12 facing the processing point. The coolant ejection device 10 is attached to the spindle head 2. The coolant injection device 10 itself is a known device in which the nozzle 12 is turned on a vertical plane including the axis of the main shaft 3 and the irradiation angle β is variable. By combining means for controlling the irradiation angle β so as to follow the position change, the coolant liquid can be sprayed at a target processing point. In this embodiment, the irradiation angle β is defined as an angle between the nozzle axis and the main axis.

Next, FIG. 2 schematically shows a change in the processing point and a change in the positions of the work 4, the tool 6, and the nozzle 12 in the process of drilling the work 4 using a drill as the tool 6. FIG. In FIG. 2, 14 is a table 5
A Z-axis motor that drives a ball screw 15 that sends
Reference numeral 6 denotes a W-axis motor that drives a ball screw 17 that feeds the quill 8 to feed the main shaft 3. H is a tool length, and W is a spindle feeding length. Here, the tool length H is equal to the spindle 3
Is the length from the end face to the tip of the tool 6, and is data specified in advance in the NC machining program as a tool dimension when the program is created. Table 5
By specifying the thickness D of the work 4, the work 4 is positioned such that the processing end face of the work 4 becomes the origin of the Z axis. In many cases, when the position of the processing end surface of the work 4 fixed to the table 5 is at the origin of the Z-axis, the spindle feed-out length positions the main shaft 3 at a position where the tip of the tool 6 contacts the work 4. This is the length that the spindle 3 has advanced from the nose end face 19 for the purpose of determination. A is the distance between the nose end face 19 and the nozzle turning center 20 of the coolant injection device 10, B is the distance between the axis of the main shaft 3 and the nozzle turning center 20, and these distances A and B are mechanical. Is constant regardless of the motion of the robot and is specified in advance in the NC machining program.

In the case of drilling with the tool 6, after the spindle 3 is extended by W and positioned, the spindle 3 rotates, and the table 5 is fed by the cutting amount Z. As a result, the tool 6 cuts a hole deep in the work 4, and the position of the machining point to which the coolant liquid is to be supplied changes every moment as the work 5 moves. In the case of drilling, the term “processing point” refers to a target point at which the coolant is applied at the entrance of the hole drilled in the work 4, and is not necessarily the cutting point at which the tool actually cuts the workpiece. It does not match. Note that the processing point may coincide with the cutting point depending on the type of processing.

As described above, the processing point to which the coolant liquid is to be supplied changes every moment with the relative movement of the work 4 and the tool. However, if the current position of the processing point is constantly grasped, the nozzle 12 is moved to the processing point. The irradiation angle β when aiming is uniquely determined.

That is, in this embodiment, the tool length H
When the spindle feed-out length W is determined, the origin on the Z-axis and the machining point at the start of machining coincide with each other. Therefore, the actual movement amount of the table 5 from the start of machining, that is, the cutting amount Z
Is obtained, the current position of the processing point can always be obtained.

The processing point at the start of processing is Z0, and the irradiation angle β1 aimed at this processing point is β1 = tan ^-1 {b / (H + W + a)}.

After the start of machining, the current position of the machining point at the cutting amount Z1 is a position shifted by Z1 from the limited position on the Z-axis. Therefore, the irradiation angle β2 of the nozzle aimed at the machining point at this time is: , Β2 = tan ^-1 {b / (H + W + a) -Z1}.

Therefore, the nozzle irradiation angle control means for executing automatic control for causing the aiming angle β to follow the change in the position of the processing point will be described below with reference to FIG.

In FIG. 3, P is a machining program in which machining command information relating to hole machining of the work 4 is described.
Numeral 30 denotes an NC unit, which includes an arithmetic unit 31 and a servo control unit 33. The program analysis unit 32 of the arithmetic unit 31
It sequentially analyzes the processing command information of the read processing program P, calculates the X-axis, Y-axis, Z-axis, and W-axis movement amount and feed speed commands and outputs them to the servo control unit 33. The servo control unit 32 has a servo unit for each axis, and the X-axis, Y-axis, Z-axis, and W-axis motors are controlled by commands distributed to each axis.

In this embodiment, the arithmetic unit 31 of the NC unit 30 includes a nozzle angle calculator 3 for calculating a current position of a processing point and a target value β of a nozzle irradiation angle at the current position.
4 are provided. The nozzle angle calculation unit 34 includes Z
Position feedback from a position detector 35 forming a position control loop of the shaft motor 14 and position feedback from a position detector 36 forming a position control loop of the W-axis motor 16 are introduced via a servo control unit 32, From the position feedback, the nozzle angle calculation unit 34 calculates the actual spindle feed amount W and the cut amount Z. Further, data such as the tool length H is given from the program analysis unit 32, and the nozzle angle calculation unit 34 constantly obtains the current position of the processing point from these data, as described above, and sets the target of the nozzle irradiation angle. Calculate the value β.

On the other hand, the coolant injection device 10 is provided with a servo motor 38 as a drive source at an aiming portion for turning the nozzle 12 to aim at a processing point, and the NC device 30 has a nozzle angle for controlling the servo motor 38. A control unit 42 is additionally provided, and a position control loop is configured by the encoder 40 that detects the rotation angle of the servo motor 38.

The nozzle angle control unit 42 compares the target value β of the nozzle irradiation angle commanded from the nozzle angle calculation unit 34 with the feedback from the encoder 40, and performs control so that the deviation becomes zero. As a result of adjusting the irradiation angle β according to the change in the position of the processing point, the aim of the nozzle 12 is always automatically adjusted to the current position of the processing point. Therefore, the coolant liquid injected from the nozzle 12 surely hits the processing point, and the necessary and sufficient coolant liquid is supplied to the tool 6, so that smooth and safe processing can be performed.

In addition, the tool length, spindle feed amount,
There is no need to calculate the depth of cut etc. in advance and incorporate a command to adjust the nozzle angle into the machining program or adjust the nozzle angle manually as needed while monitoring the progress of machining. Thus, the aim of the coolant nozzle can automatically follow the movement of the machine without manual intervention. Therefore, in complicated machining in which the number of tools used is large and the machining time is long, the creation of a program is facilitated and the machining is also unmanned.

In the above description, the case of drilling a workpiece using a drill as a tool has been described. However, the same applies to the processing using a milling machine or an end mill, in which the current position is determined using the cutting edge as a processing point in the same manner. The angle can follow the movement of the machine. Therefore, even when various tools are successively changed and processed by the automatic tool changer, the aim of the nozzle can be automatically adjusted to the processing point every time the tool is changed.

Also, an example has been described in which, in addition to the tool length, the amounts of movement of the spindle extension axis and the cutting axis are determined by feedback to determine the machining point. However, depending on the machining mode, the tool length and other axes may be determined. It is needless to say that the processing point can be obtained from the movement amount.

[0029]

As is apparent from the above description, according to the present invention, a command for adjusting a nozzle angle in a machining program by previously calculating a tool length, a spindle extension amount, a cutting amount, and the like. It is no longer necessary to adjust the nozzle angle manually while monitoring the progress of machining, and just program the machining procedure, and the coolant nozzle will automatically follow the machine movement without manual intervention Can be done. Therefore, in complicated machining in which the number of tools used is large and the machining time is long, the creation of a program is facilitated and the machining is also unmanned.

[Brief description of the drawings]

FIG. 1 is a side view showing a horizontal boring milling machine to which a machining point automatic aiming type coolant liquid supply device according to the present invention is applied.

FIG. 2 is an explanatory diagram showing a relationship between a change in a processing point in drilling and an irradiation angle of a coolant nozzle.

FIG. 3 is a control block configuration diagram of a machining point automatic aiming type coolant liquid supply device according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Column 2 Spindle head 3 Spindle 4 Work 5 Table 6 Tool 10 Coolant injection device 12 Coolant nozzle 14 Z-axis motor 16 W-axis motor 20 Nozzle rotation center β Nozzle irradiation angle

Claims (3)

[Claims] In a coolant supply apparatus which is arranged outside a main spindle of a numerically controlled machine tool and which supplies coolant to a processing point of a workpiece by a tool by spraying from a nozzle, the coolant is injected toward the processing point. A coolant nozzle having a variable irradiation angle at the time, a coolant injection device having a servomotor for nozzle aiming drive for directing the coolant nozzle to a processing point by changing the irradiation angle of the coolant nozzle, and feed of the machine tool. The current position of the processing point of the workpiece, which changes with the movement of the axis, is constantly calculated based on the amount of movement of the feed axis of the machine tool, and the irradiation angle of the nozzle is controlled so as to follow the change in the position of the processing point. And a nozzle irradiating angle control means. 2. The nozzle irradiation angle control means includes: a nozzle angle detection means for detecting an irradiation angle of the coolant nozzle; and a target value of an irradiation angle required for accurately aiming the coolant nozzle at a processing point of a workpiece. Is calculated based on the current position of the machining point, and generates an irradiation angle command to be given to the coolant injection device. The irradiation angle of the irradiation angle fed back from the angle detection means to the commanded target value of the irradiation angle is calculated. 2. A machining point automatic aiming type coolant liquid supply apparatus according to claim 1, further comprising: nozzle angle control means for controlling the servo motor so that the detected values match. 3. The arithmetic means comprises an arithmetic unit inside a numerical control device, and fetches a movement amount of the feed shaft from a position control system of a feed shaft in a spindle direction, and the movement amount is given in advance. 3. The coolant supply device according to claim 2, wherein a current position of a processing point having a processing start position as an origin is calculated based on a tool length.