JPH08118198A - Working fluid feeder - Google Patents

Abstract

PURPOSE: To prevent the leakage of a residual working fluid during tool changing action by sucking to recover a working fluid remaining in a spindle and a tool holder at the time of stopping the jet of the machining fluid. CONSTITUTION: The working fluid feeder 10 of a machine tool is provided with a control valve 20 provided at the intermediate part of a fluid circuit 17 for making a working fluid flow through to a working fluid jet part from working fluid supply sources 14, 18, so as to control the jet on-off of the working fluid, and a suction means 28 for sucking the residual working fluid in a line 36 between the control valve 20 and the working fluid jet part.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a machining fluid supply device for machine tools such as machining centers.

[0002]

2. Description of the Related Art In the field of machine tools, machine tools such as machining centers equipped with an automatic tool changer are widely used. In such a machine tool, a tool holder mounting hole formed in a tapered shape is provided at the tip of the spindle, and the tool holder is detachably attached to the spindle by fitting the tool holder mounting hole and the shank of the tool holder. It is installed. The tool is mounted in the tool holder and is replaced together with the tool holder.

By the way, such a machine tool is provided with a machining liquid supply pipe line extending from the rear part of the main shaft toward the tip end in the direction of the main shaft and the tool holder, and the machining liquid is supplied through the machining liquid supply pipe line to a cutting part or a jetting part. There is a machine tool equipped with a so-called through-spindle type machining fluid supply device that ejects the liquid toward the target. In a machine tool equipped with a through-spindle machining fluid supply device, when exchanging tools with an automatic tool changer, when the tool holder is removed from the tip of the spindle, the machining fluid supply line between the spindle and tool holder Is divided. For this reason, the machining fluid remaining in the machining fluid supply conduit leaks out from the divided portion.

Since the working fluid is circulated and used between the working part and the working fluid tank, the working fluid contains minute chips generated by cutting. If the machining fluid leaks out from the divided portion of the machining fluid supply pipe and the chips adhere to the joint surface between the spindle and the tool holder, the mounting accuracy of the tool holder at the time of tool replacement is lowered. To prevent this,
For example, in the coolant supply device described in Japanese Patent Publication No. 60-14660, after the supply of coolant as a working fluid is stopped at the time of tool change, a clean fluid is supplied to the coolant supply passage to attach chips to the joint surface. To prevent that.

[0005]

However, in addition to the coolant supply device, this device requires a device such as a pump and a tank for supplying the cleaning liquid, which not only increases the cost of the device, but also cleans it separately from the coolant. It is inconvenient for the user because the liquid must be prepared.
Also, when the machining fluid is ejected from the machining fluid nozzle toward the machining section, or when it is ejected from the tool tip through the pipe line directly connected to the tool holder by the so-called through tool method, the machining fluid is stopped. After that, when the worker approaches the processing portion to perform the work, there is a problem that the residual processing liquid leaks and drips from the processing liquid jetting portion and deteriorates the workability.

The present invention has as a technical object to solve the problems of the prior art. When the supply of the machining fluid is stopped, the machining fluid remaining in the machining fluid pipeline such as the spindle and the tool holder is removed. An object of the present invention is to provide a machining fluid supply device that prevents the residual machining fluid from leaking out during suction, collection and the like, during a tool change operation.

[0007]

SUMMARY OF THE INVENTION The above-mentioned object is to change the tool of a machine tool when the ejection of the machining fluid is stopped.
This is achieved by a working fluid supply device configured to instantly suck and collect the working fluid remaining in the working fluid conduit. That is, according to the present invention, in a machining fluid supply device for a machine tool, a control is provided in the middle of a fluid circuit that circulates the machining fluid from a machining fluid supply source to the machining fluid jetting portion, and controls the on / off of jetting of the machining fluid. A valve and suction means for sucking the residual machining fluid in the pipe between the control valve and the machining fluid ejecting portion when the control valve is turned off and the ejection of the machining fluid is stopped. A featured working fluid supply device is provided.

Further, the present invention is a through-spindle type machining liquid supply apparatus for supplying a machining liquid from a machining liquid supply source to the rear part of a main spindle of a machine tool and circulating the liquid inside the main spindle to eject the machining liquid from the front part of the main spindle. , A control valve provided in the middle of the fluid circuit from the machining fluid supply source to the rear part of the spindle for controlling on / off of the jetting of the machining fluid, and when the control valve is turned off and the jetting of the machining fluid is stopped. A machining fluid supply device is also characterized in that it is provided between the rear portion of the spindle and a control valve, and is provided with a suction means for sucking residual machining fluid in a pipe line inside the spindle. Preferably, the suction means is provided in a branch pipeline branched from the fluid circuit, and utilizes a negative pressure generated by jetting the machining fluid flowing through the branch pipeline in a high-speed jet form. It is a fluid discharge device.

[0009]

When the control valve stops the ejection of the machining fluid, the suction means sucks the machining fluid remaining in the pipe. This allows
Leakage of residual machining fluid from the machining fluid after the machining fluid is stopped is prevented.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described below with reference to FIGS. The spindle device 12 of a machine tool such as a machining center equipped with an automatic tool changer (not shown)
It has a housing 32 with a generally cylindrical hollow. In the hollow part of the housing 32, a main shaft 34 arranged in the longitudinal direction is rotatably supported via bearings. A tool holder mounting hole formed in a tapered shape is provided at the tip of the main shaft 34, and a tool holder 38 is removably mounted in the tool holder mounting hole. A predetermined cutting tool is attached to the tip of the tool holder 38,
While rotating the main shaft 34, a cutting tool is pressed against a work (not shown) to perform a predetermined cutting process.

In order to eject the machining liquid toward the machining portion at the tip of the cutting tool, a machining pipe line 36 is provided as a machining liquid supply pipe line that penetrates the spindle 34 and the tool holder 38. The rear end of the main shaft conduit 36 is connected to the machining fluid supply device 10 via a rotary joint (not shown) or the like. The machining fluid supplied from the machining fluid supply device 10 is
It flows from the rear end of the main spindle channel 36 toward the tip, and is jetted from the tool tip toward the machining portion.

The machining fluid supply device 10 includes a machining fluid tank 14 as a machining fluid supply source and a pump 18.
The suction port of the pump 18 is connected to the machining fluid tank 1 through the pipe 15.
4 is connected. The discharge port of the pump 18 is the line 16
Via a solenoid type directional control valve 2 as a control valve
Connected to 0. The directional control valve 20 is a two-position three-port directional control valve having one port on the inlet side and two ports on the outlet side, and its solenoid is connected to a control device (not shown) of the machine tool. There is. Direction switching valve 2
One of the two ports on the outlet side of 0 is connected to the rear part of the main shaft conduit 36 provided in the main shaft 34 via the conduit 17. The other port of the direction switching valve 20 is connected to the nozzle-side port 2 of the ejector 28 as a suction unit via the pipe line 22.
It is connected to 8d. The structure of the ejector 28 will be described later in detail. A branch line 24 is provided in the line 17,
The branch conduit 24 is connected to the suction side port 28e of the ejector 28. A solenoid type shutoff valve 26 is provided between the pipe line 17 and the ejector 28 in the branch pipe line 24. The solenoid of the shutoff valve 26 is also connected to a machine tool controller (not shown). The outlet-side port 28c of the ejector 28 is connected to the working liquid tank 14 via a return pipe 30. Note that FIG. 1 is shown with the solenoids of the direction switching valve 20 and the shutoff valve 26 demagnetized.

The ejector 28 is a generally known fluid ejecting device, which ejects a fluid at a high speed from a nozzle, generates a negative pressure by the entrainment action of the jet, and sucks and ejects another fluid by this negative pressure. It is a device that does. Referring to FIG. 2, the ejector 28 includes a hollow main body 28a. The main body 28a has a nozzle-side port 28d formed at one end in the longitudinal direction, and an outlet port 28c formed at the other end. As described above, the conduit 22 is connected to the nozzle side port 28d, and the return line 3 is connected to the outlet side port 28c.
0 is connected. Nozzle side port 28d is nozzle 28b
Is in communication with. The nozzle 28b is a port 28 on the nozzle side.
The working fluid supplied to d at a predetermined pressure is
It is formed so as to be ejected in the form of a high-speed jet toward 8c. The suction side port 28e is provided on the side surface of the main body 28a closer to the outlet side port 28d than the tip of the nozzle 28b.
Are formed. The suction pipe 28e has a branch pipe 2
4 is connected.

Next, the operation of the working fluid supply apparatus according to this embodiment will be described. First, while the machine tool is performing the cutting process, the solenoids of the direction switching valve 20 and the shutoff valve 26 are in the excited state, and the working fluid in the working fluid tank 14 is pumped by the pump 18 via the conduit 15. After being pressurized to a predetermined pressure, it is supplied to the main shaft pipeline 36 via the pipeline 16, the direction switching valve 20, and the pipeline 17. The high-pressure machining liquid supplied to the spindle channel 36 penetrates the spindle 34 and the tool holder 38 and is ejected toward the machining section.

When the predetermined machining process is completed, the spindle 3
The rotation of No. 4 is stopped, and then the machine tool starts a tool changing operation. At this time, the solenoid of the directional control valve 20 is demagnetized by the control device of the machine tool. As a result, the discharge port of the pump 18 includes the pipe line 16, the direction switching valve 20, and
Nozzle-side port 28 of ejector 28 via conduit 22
communicate with d. Negative pressure is generated behind the jet by the high-speed fluid ejected from the nozzle 28b, and the pressure of the suction side port 28e becomes lower than the atmospheric pressure. At about the same time, or before and after a predetermined short time, the solenoid of the shutoff valve 26 is demagnetized, and the suction side port 28e of the ejector 28 is demagnetized.
But communicates with the main shaft conduit 36 via the shutoff valve 26 and the conduit 24. As a result, the machining fluid remaining in the machining fluid supply holes of the main spindle duct 36 and the tool holder 38 is ejected by the ejector 2
8 is sucked into the ejector 28 from the nozzle side port 28d.
It is collected in the working fluid tank 14 through the return pipe 30 together with the working fluid supplied to the.

After this state is continued for a predetermined time to remove the machining fluid remaining in the machining fluid supply holes of the main spindle conduit 36 and the tool holder 38, the pump 18 is stopped by the control device of the machine tool. On the other hand, the machining fluid leaks when the tool holder 38 is removed from the spindle 34. Therefore, after the machining fluid remaining in the machining fluid supply pipe of the tool and the tool holder 38 is removed, the tool holder 38 is removed. Even if is removed from the main shaft 34, the residual machining fluid does not leak out. Further, since the amount of machining fluid remaining in the tool and the tool holder 38 is small, when the solenoid of the shutoff valve 26 is demagnetized and the main shaft conduit 36 communicates with the suction side port 28e of the ejector 28, the residual machining of the tool holder 38 remains. The liquid is removed instantly and does not interfere with the automatic tool change operation of the machine tool.

In the embodiment described above, the ejector utilizing the pressure drop due to the jet flow is used as the suction means,
It is also possible to use other suction means. In short, the suction means uses the negative pressure to cause the tool holder 38 and the main shaft conduit 36 to move.
Any means can be used as long as it can suck the working liquid remaining therein. For example, branch line 24 may be connected to a vacuum tank or other vacuum source available in the factory. In this case, the conduit 2 connected between the direction switching valve 20 and the ejector 28
2 is directly connected to the tank 14 from the direction switching valve 20. In addition, the directional control valve 20 as a control valve
Can be constituted by a solenoid type shutoff valve similar to the shutoff valve 26, and a relief valve can be appropriately provided instead and the conduit 22 can be omitted.

In the present embodiment, the so-called through spindle type working fluid supply device has been described, but a nozzle type working fluid supply device in which the working fluid is ejected from the working fluid nozzle toward the processing portion is also called the tool through system. The same configuration can be adopted also in the machining fluid supply device.

[0019]

The machining fluid supply device of the present invention has a machining fluid supply conduit that penetrates the spindle and the tool holder after the machining fluid supply is stopped when the tool is replaced and before the tool holder is removed from the spindle tip. Since the residual machining fluid is sucked and collected from the machine, it is possible to prevent the residual machining fluid from leaking when the tool holder is removed from the spindle. Further, the machining fluid supply device of the present invention uses a pump that supplies the machining fluid to the main spindle device to eject the machining fluid in a high-speed jet form to generate a negative pressure and suck the residual machining fluid. It does not require a power unit and has a simple structure to prevent leakage of residual machining fluid.

[Brief description of drawings]

FIG. 1 is a schematic view of an embodiment of a working fluid supply device of the present invention.

FIG. 2 is a principle diagram of the ejector of FIG.

[Explanation of symbols]

 10 ... Machining liquid supply circuit 12 ... Spindle device 14 ... Machining liquid tank 18 ... Pump 20 ... Direction switching valve 26 ... Shutoff valve 28 ... Ejector 34 ... Spindle 36 ... Spindle conduit 38 ... Tool holder

Claims (3)

[Claims] 1. A machining fluid supply device for a machine tool, which is provided in the middle of a fluid circuit for circulating the machining fluid from a machining fluid supply source to a machining fluid jetting part, and which controls a turning on / off of the jetting of the machining fluid. And a suction means for sucking the residual machining fluid in the conduit between the control valve and the machining fluid ejection part when the control valve is turned off and the ejection of the machining fluid is stopped. Characteristic machining fluid supply device. 2. A through-spindle type machining liquid supply device for supplying a machining liquid from a machining liquid supply source to a rear portion of a main spindle of a machine tool to circulate in the main spindle and eject the machining liquid from a front portion of the main spindle. A control valve that is provided in the middle of the fluid circuit from the supply source to the rear part of the spindle and controls the on / off of the jetting of the machining fluid; and when the jetting of the machining fluid is stopped by turning off the control valve, the spindle rear part And a control valve, which is provided with suction means for sucking residual machining fluid in a pipe line inside the main shaft. 3. The suction means is provided in a branch pipe branching from the fluid circuit, and a negative pressure generated by jetting the machining fluid flowing through the branch pipe in a high-speed jet stream is provided. The machining fluid supply device according to claim 1 or 2, which is a fluid discharge device that is used.