JP2020196064A - Coolant supply device and machine tool system - Google Patents

Abstract

To provide a coolant supply device in which hunching is less likely to occur in supply means.SOLUTION: A coolant supply device 1 comprises: a coolant tank 10; a pump 11 which force-feeds coolant in the coolant tank to the machine tool 3 side; liquid level detection means 12 which detects a liquid level of coolant; supply means 13 which supplies coolant to the coolant tank; and discharge means 14 which discharges coolant in the coolant tank exceeding a return level, the coolant supply device 1 supplies the coolant by the supply means for the coolant tank and the discharges the coolant by the discharge means, in accordance with delivery of the coolant for a machine tool by the pump. The supply means continues the supply of coolant over a prescribed duration time from detection of a liquid level of the coolant by the liquid level detection means and the discharge means discharges a quantity of coolant per unit time which is equivalent to increases in the coolant tank per unit time by supply of the supply means.SELECTED DRAWING: Figure 1

Description

The present invention relates to a coolant supply device and a machine tool system.

In machine tools, there is known a coolant supply device that supplies high-pressure coolant to a machining area where a workpiece is machined by a tool (see, for example, Patent Document 1).

Generally, in the coolant supply device, a liquid level detecting means for detecting the liquid level of the coolant in the coolant tank is installed, and the coolant is supplied and supplied into the coolant tank based on the information of the liquid level detecting means. It is conceivable to control the outage and maintain the amount of coolant in the coolant tank.

Japanese Unexamined Patent Publication No. 6-304842

However, it is considered that the frequent operation and stop of the supply means such as the pump that supplies the coolant to the coolant tank may adversely affect the supply means.

The present invention includes a coolant supply device capable of maintaining the amount of coolant in the coolant tank without operating and stopping the operation of the supply means for supplying the coolant to the coolant tank more frequently than necessary, and the coolant supply device. The purpose is to provide a machine tool system.

The coolant supply device according to the present invention includes a coolant tank in which coolant is stored, a pump that pumps the coolant in the coolant tank to the machine tool side, and a liquid level detecting means for detecting the liquid level of the coolant in the coolant tank. , A supply means for supplying coolant to the coolant tank and a discharge means for discharging the coolant in the coolant tank exceeding the return level are provided, and when the coolant is delivered to the machine tool by the pump, the supply means to the coolant tank is used. In the coolant supply device that supplies and discharges the coolant by the discharge means, the supply means continues to supply the coolant for a predetermined duration from the detection of the liquid level of the coolant by the liquid level detection means, and the discharge means , The amount of coolant per unit time, which increases in the coolant tank due to the supply of the supply means, is discharged per unit time.

Further, in the coolant supply device according to the present invention, the supply means is determined after the liquid level detecting means detects that the liquid level of the coolant stored in the coolant tank has dropped to a control level lower than the return level. It is preferable to start supplying the coolant after the waiting time has elapsed.

Further, in the coolant supply device according to the present invention, the supply means has elapsed a predetermined duration after the liquid level detecting means detects that the liquid level of the coolant stored in the coolant tank has risen to the control level. It is preferable to stop the supply of coolant later.

Further, the machine tool system according to the present invention includes a machine machine that processes a workpiece with a tool and a coolant supply device that supplies coolant to a machining area where the workpiece is machined, and the coolant supply device stores coolant. The coolant tank to be used, the pump that pumps the coolant in the coolant tank to the processing area, the liquid level detection means that detects the liquid level of the coolant in the coolant tank, and the supply means that supplies the coolant to the coolant tank. And a discharge means for discharging the coolant in the coolant tank exceeding the return level, and the coolant is supplied to the coolant tank by the supply means and discharged by the discharge means as the coolant is sent to the processing area by the pump. In the supply device, the supply means continues to supply the coolant for a predetermined duration from the detection of the liquid level of the coolant by the liquid level detection means, and the discharge means increases in the coolant tank by the supply of the supply means. Discharge the amount of coolant per hour.

In the coolant supply device according to the present invention, the coolant is supplied for a predetermined duration after the liquid level of the coolant tank rises to the control level, so that the supply means is activated and stopped more frequently than necessary. The amount of coolant in the coolant tank can be maintained without doing so. Further, in the coolant supply device according to the present invention, the discharge means discharges the amount of coolant per unit time, which increases in the coolant tank due to the supply of the supply means, so that the liquid level in the coolant tank is raised. It is prevented from rising more than necessary, the overflow of coolant from the coolant tank is suppressed, and in particular, the coolant discharged by the discharge means is returned to the supply side of the coolant supplied by the supply means, so that the coolant on the supply side It is possible to avoid a shortage of coolant. The supply side of the coolant supplied by the supply means can be a coolant tank arranged in the machine tool of the machine tool system according to the present invention.

It is a functional block diagram of the coolant supply device which concerns on embodiment. It is a flowchart which shows the coolant level control process by NC apparatus at the time of execution of the machining process of the workpiece by the machine tool shown in FIG. It is a figure (the 1) for demonstrating the coolant level control process shown in FIG. It is a figure (the 2) for demonstrating the coolant level control process shown in FIG. It is a figure (the 3) for demonstrating the coolant level control process shown in FIG. It is a figure (the 4) for demonstrating the coolant level control process shown in FIG. FIG. 5 is a diagram (No. 5) for explaining the coolant level control process shown in FIG.

As shown in FIG. 1, the coolant supply device 1 according to the present invention is mounted in conjunction with the machine tool 3, and the machine tool system 100 according to the present invention is configured by the coolant supply device 1 and the machine tool 3. There is.

The machine tool 3 includes a spindle for holding the work 101, a tool post on which the tool 102 is mounted, a second coolant tank 30 for storing coolant, a second pump 31 for pumping coolant in the second coolant tank 30, and a numerical control device. (Numerical Control, hereinafter NC device) 2 and the like are provided.

In the present embodiment, the NC device 2 serves as a control device that controls the overall operation of the machine tool system 100 including the coolant supply device 1 and the machine tool 3, a computing device such as a CPU, a storage device such as SRAM, and a DRAM. It is also composed of an interface circuit or the like capable of communicating with each of the constituent elements of the coolant supply device 1 and the machine tool 3.

The coolant supply device 1 includes a first coolant tank 10 in which coolant is stored, a first pump 11 that pumps the coolant in the first coolant tank 10 to the machine tool side, and a liquid level of the coolant in the first coolant tank 10. A liquid level detecting means 12 for detecting the level, a supply means 13 including a pump for supplying coolant to the first coolant tank 10, and a coolant tank exceeding a preset return level, which is a predetermined liquid level. It is provided with a discharge means 14 for discharging the coolant inside.

The first pump 11 and the supply means 13 are controlled by the NC device 2, and the supply means 13 supplies the coolant to the first coolant tank 10 via the supply pipe 17, and the first pump 11 supplies the coolant in the first coolant tank 10. The coolant is discharged from the supply unit 16 at high pressure via the connecting pipe 15.

The first pump 11 and the supply means 13 are the first when the first pump 11 discharges the coolant from the first coolant tank 10 and the supply means 13 simultaneously supplies the coolant to the first coolant tank 10. The coolant in the coolant tank 10 is preset so as to increase by a predetermined amount per unit time.

The discharge means 14 has a return pipe 36 serving as a drain pipe, and the inlet of the coolant formed in the first coolant tank 10 so as to allow the coolant to flow into the return pipe 36 is the coolant stored in the first coolant tank 10. Is arranged so that the coolant in the first coolant tank 10 flows into the return pipe 36 when the return level R is exceeded.

The return pipe 36 uses the same amount of coolant as the amount of coolant per unit time that increases in the coolant tank 10 due to the simultaneous discharge of the coolant by the first pump 11 and the supply of the coolant by the supply means 13. It is formed to discharge per hour.

The liquid level detecting means 12 has a high level sensor 121, a low level sensor 122, and a control level sensor 123, and detects the liquid level of the coolant stored in the first coolant tank 10. Each of the high level sensor 121, the low level sensor 122, and the control level sensor 123 can be a general liquid level sensor capable of detecting the height of the liquid level, and is, for example, a float type level sensor.

The high level sensor 121 detects that the liquid level has risen abnormally so that the coolant overflows from the coolant tank and overflows. The low level sensor 122 detects that the liquid level has dropped abnormally so that the first pump 11 cannot suck the coolant. The control level sensor 123 outputs an ascending signal when the liquid level has reached a predetermined control level C.

The control level C is set at a position lower than the return level between the liquid level detected by the high level sensor 121 and the low level sensor 122. The output of the rising signal from the control level sensor 123 stops when the liquid level drops below the control level C. The detection signals of the high level sensor 121 and the low level sensor 122 and the ascending signal are transmitted to the NC device 2.

In the machine tool 3, the operation of the spindle and the tool post is controlled by the NC device 2, and the machining process of the work 101 by the tool 102 is executed. When the work 101 is machined by the tool 102, coolant is supplied to the machining area 103 where the work 101 is machined by the tool 102. The coolant supplied to the processing region 103 falls together with the cutting chips and is collected in the second coolant tank 30.

As for the supply of the coolant to the processing region 103, the coolant in the second coolant tank 30 is supplied from the supply unit 33 by the second pump 31 via the connecting pipe 32 under the control of the NC device 2, and the coolant supply device 1 Therefore, the coolant in the first coolant tank 10 can be supplied from the supply unit 16 by the first pump 11 via the connecting pipe 15. The supply pressure of the coolant supplied to the processing region 103 can be switched by making the supply pressure of the coolant from the coolant device 1 by the first pump 11 higher than the supply pressure of the coolant by the second pump 31.

When the coolant is supplied to the processing region 103 by the coolant device 1, referring to the flowchart shown in FIG. 2 and FIGS. 3 to 8, the NC device 2 supplies the coolant by the coolant device 1, for example, the supply of high-pressure coolant. When it is determined that the start instruction has been obtained (S101-YES), the liquid level of the first coolant tank 10 is detected based on the high level warning signal, the low level warning signal, etc., and in the case of an abnormality (S102-YES). , An alarm signal is output (S103), and the process is terminated.

When the NC device 2 determines that the liquid level is normal (S102-NO), the first pump 11 is started (S104), and as shown in FIG. 3, the NC device 2 is transferred to the machining region 103 via the supply unit 16. Start supplying coolant. When the first pump 11 operates and the coolant is supplied to the processing region 103, the amount of coolant in the first coolant tank 10 decreases, and the liquid level gradually decreases.

Next, the NC device 2 determines whether or not the liquid level of the first coolant tank 10 has dropped to the control level C based on the rising signal (S105).

As shown in FIG. 4, the NC device 2 has a liquid level lower than the control level C, and the liquid level of the first coolant tank 10 has been lowered to the control level C based on the rising signal from the control level sensor 123. (S105-YES), the time counting of a predetermined standby time is started (S106). The standby time is a time for waiting from the liquid level of the first coolant tank 10 to the control level C until the start of supply of the coolant by the supply means 13, for example, 30 seconds.

Next, the NC device 2 determines whether or not a predetermined waiting time has elapsed after the liquid level of the first coolant tank 10 drops to the control level C (S107). As shown in FIG. 5, the liquid level of the first coolant tank 10 is further lowered from the control level C until the standby time elapses.

When the NC device 2 determines that a predetermined standby time has elapsed after the liquid level has dropped to the control level C (S107-YES), the NC device 2 moves from the second coolant tank 30 to the first coolant tank 10 by the supply means 13. Coolant supply is started (S110). When the supply of the coolant by the supply means 13 is started, the liquid level of the first coolant tank 10 gradually rises. On the other hand, the liquid level of the second coolant tank 30 gradually decreases by the difference between the amount of coolant discharged to the first coolant tank 10 and the amount of coolant recovered from the processing region 103.

Next, the NC device 2 determines whether or not the liquid level of the first coolant tank 10 has risen to the control level C based on the rising signal (S109).

As shown in FIG. 6, the NC device 2 starts timing of a predetermined duration when it is determined that the liquid level of the first coolant tank 10 has risen to the control level C (S109-YES). (S110). The duration is a time for continuing the supply of the coolant by the supply means 13 after the liquid level of the first coolant tank 10 rises to the control level C, for example, 30 seconds.

As shown in FIG. 7, after the liquid level of the first coolant tank 10 has risen to the control level C, the liquid level of the first coolant tank 10 is returned by continuing the supply of the coolant by the supply means 13. Ascend to level R. When the liquid level of the first coolant tank 10 rises to the return level R, the coolant supplied from the second coolant tank 30 begins to return to the second coolant tank 30 via the discharge means 14.

Since the coolant supplied from the second coolant tank 30 returns to the second coolant tank 30 via the discharge means 14, the liquid level of the first coolant tank 10 is generally maintained at the return level R. On the other hand, the liquid level of the second coolant tank 30 is maintained at a substantially constant level depending on the amount of the coolant returned via the return pipe 36 and the coolant recovered from the processing region 103.

Next, the NC device 2 determines whether or not a predetermined duration has elapsed since the liquid level of the first coolant tank 10 rose to the control level C (S111).

When the NC device 2 determines that a predetermined duration has elapsed since the liquid level level has risen to the control level C (S111-YES), the NC device 2 stops the supply of coolant by the supply means 13 (S112). When the supply of coolant by the supply means 13 is stopped, the first pump 11 operates and the liquid level of the first coolant tank 10 gradually decreases. Therefore, the NC device 2 then sends a high level alarm signal and a low level alarm signal. The liquid level of the first coolant tank 10 is detected based on a level alarm signal or the like (S113). In the case of an abnormality (S113-YES), the NC device 2 outputs an alarm signal (S103) and ends the process.

The NC device 2 repeats the processes of S105 to S114 until it is determined that the liquid level is normal (S113-NO) and the end of the processing of the work 101 is determined (S114-YES). When it is determined (S114-YES) that the coolant supply (supply of high-pressure coolant) by the coolant device 1 is completed, the NC device 2 ends the process.

In the coolant supply device 1, the coolant is supplied for a predetermined duration after the liquid level of the coolant stored in the first coolant tank 10 rises to the control level C, so that the coolant supply means 13 supplies the coolant. The amount of coolant in the coolant tank can be maintained without operating and stopping the operation more frequently than necessary. Further, since the start of operation of the supply means 13 is waited until a predetermined standby time elapses after the liquid level drops to the control level C, the frequency of operation and stop of operation of the supply means 13 can be further suppressed.

Further, in the coolant supply device 1, the discharge means 14 transfers the same amount of coolant to the second coolant tank 30 per unit time as the amount of coolant increases in the coolant tank due to the supply of the coolant by the supply means 13. Since the coolant is returned, the liquid level in the first coolant tank is generally maintained at the return level R while the coolant is being supplied by the supply means 13, and it is prevented from rising more than necessary, and the coolant overflows from the first coolant tank. Is suppressed. The liquid level of the second coolant tank 30 is maintained substantially constant by the coolant refluxed from the first coolant tank 10 via the discharge means 14. In the coolant supply device 1, the liquid level of the second coolant tank 30 arranged in the machine tool 3 is maintained substantially constant, so that the liquid level of the second coolant tank 30 rises and falls abnormally. It is low, and overflow of coolant on the second coolant tank 30 side and insufficient amount of coolant are avoided.

In the coolant supply device 1, the first coolant tank 10 and the second coolant tank 30 are connected via a single supply pipe 17, but in the coolant supply device according to the embodiment, the first coolant supply device has a plurality of supply pipes. The 1st coolant tank and the 2nd coolant tank may be connected. Further, in the coolant supply device 1, a single discharge means 14 and a return pipe 36 are arranged in the first coolant tank 10, but in the coolant supply device according to the embodiment, a plurality of discharge means and a return pipe are arranged. May be good.

1 Coolant supply device 2 NC device 3 Machine tool 10 1st coolant tank (coolant tank)
11 1st pump (pump)
12 Liquid level detection means 13 Supply means 100 Machine tool system

Claims (4)

For the coolant tank in which the coolant is stored, the pump for pumping the coolant in the coolant tank to the machine tool side, the liquid level detecting means for detecting the liquid level of the coolant in the coolant tank, and the coolant tank. It is equipped with a supply means for supplying coolant and a discharge means for discharging the coolant in the coolant tank that exceeds the return level.
In a coolant supply device that supplies coolant to the coolant tank by the supply means and discharges the coolant by the discharge means as the coolant is delivered to the machine tool by the pump.
The supply means continues to supply the coolant for a predetermined duration from the detection of the liquid level of the coolant by the liquid level detection means.
The discharge means discharges the amount of coolant per unit time, which is increased in the coolant tank by the supply of the supply means.
A coolant supply device characterized by that. The supply means receives after a predetermined waiting time has elapsed after the liquid level detecting means detects that the liquid level of the coolant stored in the coolant tank has dropped to a control level lower than the return level. The coolant supply device according to claim 1, wherein the supply of coolant is started. The supply means stops the supply of the coolant after a predetermined duration has elapsed after the liquid level detecting means detects that the liquid level of the coolant stored in the coolant tank has risen to the control level. The coolant supply device according to claim 2. It has a machine tool that processes a work with a tool and a coolant supply device that supplies coolant to the processing area where the work is processed.
The coolant supply device is
For the coolant tank in which the coolant is stored, the pump for pumping the coolant in the coolant tank to the processing region, the liquid level detecting means for detecting the liquid level of the coolant in the coolant tank, and the coolant tank. It is equipped with a supply means for supplying coolant and a discharge means for discharging the coolant in the coolant tank that exceeds the return level.
In the coolant supply device that supplies the coolant to the coolant tank by the supply means and discharges the coolant by the discharge means as the coolant is delivered to the processing area by the pump.
The supply means continues to supply the coolant for a predetermined duration from the detection of the liquid level of the coolant by the liquid level detection means.
The discharge means discharges the amount of coolant per unit time, which is increased in the coolant tank by the supply of the supply means.
A machine tool system characterized by that.

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