KR101496578B1 - Coolant auto control system and method for supplying coolant thereof - Google Patents

Abstract

The present invention relates to a cutting oil automatic control system to automatically control cutting oil in accordance to the type of workpiece and amount of cutting, and a cutting oil supplying method thereof. For example, disclosed is the cutting oil supplying method comprising: an information input step of inputting the type of workpiece to be processed, a diameter, a rotational speed, a cutting depth, and the amount of movement of a tool; a classifying step of classifying the workpiece in accordance to the type of materials of the workpiece; a weight applying step of applying a weight to the amount of cutting of the workpiece classified in the classifying step; a cutting amount comparison step of comparing the amount of cutting applied with the weight in the weight applying step with the amount of cutting prior to the weight being applied; an inverter output step of controlling the quantity of output voltage of an inverter in accordance to the results of the comparison of the amount of cutting; and a cutting oil supply step of supplying the cutting oil by controlling the number of rotations of a motor in accordance to the quantity of the output voltage of the inverter.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a coolant automatic control system,

The present invention relates to a coolant automatic control system and a coolant supply method thereof.

Generally, the machine tool is provided with a system for supplying cutting oil. The cutting oil is sprayed onto the workpiece and the cutting tool to cool the heat generated when the cutting tool is machining the workpiece and to prevent breakage of the equipment. In addition, the used cutting oil is collected in the storage tank together with the chips generated in the workpiece, and then circulated through the circulating device in a properly filtered state to be supplied again to the cutting tool and the workpiece. On the other hand, such a cutting oil supplies a uniform cutting oil inputted according to a cutting tool of a machine tool, so that it can not be precisely controlled depending on the byproduct of the workpiece.

Korean Patent Laid-Open No. 10-2012-0104764 (September 24, 2012)

The present invention provides a cutting fluid automatic control system that can automatically adjust cutting oil according to the type of workpiece and a cutting amount, and a method of supplying the cutting oil.

A method of supplying cutting fluid to an automatic control system for a cutting fluid according to the present invention includes an information input step of inputting a kind of a workpiece to be machined, a diameter, a rotation speed, a cutting depth, A classification step of classifying the workpiece according to the type of the workpiece; A weighting step of weighting the amount of cut of the workpieces classified in the classification step; A cutting amount comparing step of comparing the weighted cutting amount with a weight value before weighting is applied in the weighting step; An inverter output step of adjusting an output voltage amount of the inverter according to a result of the cutting amount comparing step; And a coolant supply step of supplying coolant by controlling the number of revolutions of the motor according to the amount of the output voltage of the inverter.

Further, in the information input step, the amount of cut of the workpiece can be calculated.

Where D is the diameter of the workpiece, n is the rotational speed of the workpiece, T is the workpiece diameter, T is the workpiece diameter, And F may be the feed amount of the tool.

In addition, in the weighting step, different weights can be given according to the types of workpieces.

In addition, if the weighted amount of cutting is larger than the weighted amount of cutting, the amount of output voltage of the inverter may be set as the first reference value.

In addition, if the weighted amount of cutting is equal to the amount of cutting before weighting is applied in the step of comparing the amount of cutting, the amount of output voltage of the inverter can be set as the second reference value.

If the weighted cutting amount is smaller than the weighted amount, the output voltage amount of the inverter may be set as the third reference value.

In addition, in the coolant supply step, the larger the output voltage of the inverter, the greater the number of revolutions of the motor, and the larger the number of revolutions of the motor, the greater the amount of coolant supplied.

In addition, the automatic control system for a cutting fluid according to the present invention includes an input unit for receiving the type, diameter, rotation speed, cutting depth, and tool feed amount of a work to be processed; A cutting amount calculation unit for calculating a cutting amount of the workpiece; And a control unit that classifies the workpiece according to the type of the workpiece, assigns a weight to the amount of cutting of the workpiece, and adjusts an amount of output voltage of the inverter by comparing the weighted amount of cutting with the amount of cutting before weighting, And a control unit for controlling the coolant supplied to the coolant supply unit.

The automatic cutting system of the present invention and the method of supplying the cutting oil according to the embodiment of the present invention minimize the consumption of the cutting oil by automatically receiving the information of the workpiece and calculating the cutting amount in real time and automatically controlling the cutting oil according to the cutting amount Thereby minimizing environmental pollution and reducing the cost accordingly.

1 is a block diagram illustrating an automatic control system for a coolant according to an embodiment of the present invention.
2 is a flowchart illustrating a method of supplying coolant in an automatic coolant control system according to an embodiment of the present invention.
FIG. 3 is a flowchart specifically showing the coolant supply method shown in FIG.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

1 is a block diagram illustrating an automatic control system for a coolant according to an embodiment of the present invention.

1, a cutting fluid automatic control system 100 according to an embodiment of the present invention includes an input unit 110, a storage unit 120, a cutting amount calculation unit 130, a control unit 140, and an inverter 150 . Here, the automatic cutting oil control system 100 is a system that adjusts the cutting oil required for machining the workpiece according to the type of workpiece or the amount of cutting and supplies the cutting oil to the machine tool 10.

The input unit 110 receives information on the workpiece to be machined by the machine tool 10. [ The input unit 110 receives information such as the type of the workpiece, the diameter, the rotation speed, the cutting depth, and the feed amount of the tool.

The storage unit 120 stores information on the workpiece input to the input unit 110. That is, the storage unit 120 stores information such as the type of the workpiece, the diameter, the rotation speed, the cutting depth, and the feed amount of the tool. In the storage unit 120, the amount of cut of the workpiece calculated by the cut amount calculation unit 130 is stored.

The cutting amount calculation unit 130 calculates a cutting amount of the work using the information of the work stored in the storage unit 120. [ The cutting amount calculation unit 130 can calculate the cutting amount L of the workpiece by the following equation (1).

[Equation 1]

L (cm 2 / min) =? X D x n x T x F / 1000

Where D is the diameter of the workpiece, n is the rotation speed of the workpiece, T is the depth of cut of the workpiece, and F is the feed rate of the tool.

The controller 140 controls the inverter 150 according to the amount of cut of the workpiece calculated by the cutting amount calculator 130 to adjust the amount of the cutting oil supplied to the machine tool 10. Specifically, the control unit 140 adjusts the output of the inverter 150 according to the result of the comparison, compares the amount of the weighted cutting with the amount of the previous amount of cutting, supplies the weighted amount to the machine tool 10 Can be controlled.

The inverter 150 controls the rotation speed of the motor 20 that supplies the cutting oil by converting and outputting the frequency under the control of the controller 140. That is, the rotation speed of the motor 20 varies according to the output of the inverter 150, and the amount of the cutting oil supplied varies according to the rotation speed of the motor 20.

As described above, the automatic cutting oil supply system 100 according to the embodiment of the present invention receives the information of the workpiece, calculates the cutting amount according to the information, and automatically adjusts and supplies the cutting oil according to the cutting amount. Thereby minimizing environmental contamination. Further, in the present invention, a large amount of cutting oil is supplied to a machining operation requiring a large amount of cutting oil, thereby minimizing problems such as heat generation and chip loading that occur during machining.

Hereinafter, a method of supplying coolant to the automatic coolant control system will be described.

2 is a flowchart illustrating a method of supplying coolant in an automatic coolant control system according to an embodiment of the present invention. FIG. 3 is a flowchart specifically showing the coolant supply method shown in FIG.

Referring to FIG. 2, a method of supplying a coolant to an automatic coolant control system according to an embodiment of the present invention includes an information input step S10, a classification step S20, a weighting step S30, a cut amount comparison step S40, An inverter output step (S50) and a coolant determination step (S60). 2 and 3, a detailed description will be given below.

In the information input step (S10), the information of the work to be machined is inputted to the input unit (110). In the information input step (S10), a calculation parameter for calculating a cutting amount is input to the input unit (110). For example, in the information input step S10, information such as the type of work, diameter, rotation speed, depth of cut, tool feed amount, and the like may be input to the input unit 110. Further, in the information input step (S10), the cutting amount L of the workpiece may be calculated in advance and stored in the storage unit according to the information of the workpiece.

The sorting step S20 is a step of sorting the workpieces according to the information of the workpieces inputted in the information input step S10. In the classification step S20, the workpiece can be classified according to the type of material. In FIG. 3, workpieces are classified into three types according to the material, but they can be more or less classified. In the sorting step S20, the workpiece may be classified into the first material, the second material, and the third material according to the type of material. For example, the first material may be aluminum, the second material may be steel, and the third material may be classified as casting. In step S21, the controller 140 determines whether the workpiece is a first workpiece (S21). If the workpiece is not the first workpiece, the controller 140 determines whether the workpiece is a second workpiece (S22) (S23). Accordingly, in the sorting step S20, the first material, the second material, or the third material may be classified according to the type of workpiece.

The weighting step S30 is a step of assigning different weights according to the types of the materials classified in the classification step S20. In the weighting step S30, the first weight W1 is applied to the first material W2, the second weight W2 is applied to the second material W2, And the third weight W3 is given to the cutting amount (S33). Here, the cutting amount L of each material is previously calculated in the information input step S10 and stored in the storage unit 120. [ For example, the first weight W1 may be 1.1 to 1.2, the second weight W2 may be 1, and the third weight W3 may be 0.5 to 0.9. In the weighting step S30, the weighted amount of cuts L0 is stored in the storage unit 120 (S34).

The step S40 is a step of comparing the weighted amount L0 with the existing amount L of cutting. In step S40, the control unit 140 compares the weighted amount L0 with the existing amount L to determine whether the weighted amount L0 is greater than the existing amount L. If the weighted amount L0 is smaller than the existing amount L, (S42). If the weighted amount L0 is not equal to the existing amount L, it is determined whether the weighted amount L0 is less than the existing amount L (S43). In the weighting step S40, since the first weight W1 is set to be larger than 1, the weight of the first material to which the weight is imparted is larger than the existing amount of cut. Since the second weight W2 is set to 1, the amount of the second material to be weighted is equal to the amount of the conventional cut, and the third weight W3 is set to be smaller than 1. Therefore, Is smaller than the existing cut amount.

The inverter output step S50 is a step of adjusting the output voltage amount of the inverter 150 according to the result of the cutting amount comparing step S40. In step S50, the control unit 140 sets the amount of output voltage of the inverter 150 as a first reference value when the weighted amount of cut L0 is greater than the existing amount of cut L (S51). Here, the first reference value may be a maximum value of the amount of the output voltage of the inverter 150. In the inverter output step S50, the control unit 140 sets the output voltage amount of the inverter 150 as a second reference value when the weighted amount of cut L0 is equal to the existing cut amount L S52). Here, the second reference value may be set to 4/5 of the maximum value. In the inverter output step S50, if the weighted amount L0 is less than the existing amount L, the control unit 140 sets the output voltage amount of the inverter 150 as the third reference value S53). Here, the third reference value may be set to 3/5 of the maximum value.

The coolant supply step S60 is a step of determining the output (the number of revolutions) of the motor 20 according to the output of the inverter 150 and supplying the coolant to the machine tool 10. In the coolant supply step S60, the output value of the motor 20 is changed according to the amount of the output voltage of the inverter 150, and the supply amount of the coolant is determined according to the output of the motor 20. For example, when the output voltage level of the inverter 150 is set to the maximum value in the inverter output step S50, the output of the motor 20 is also set to the maximum, and the amount of the cutting oil supplied to the machine tool 10 is set to the maximum value . If the output voltage level of the inverter 150 is set to 4/5 of the maximum value in the inverter output step S50, the output of the motor 20 is also set to 4/5 of the maximum value, The amount of coolant supplied is 4/5 of the maximum value. When the output voltage level of the inverter 150 is set to 3/5 of the maximum value in the inverter output step S50, the output of the motor 20 is also set to 3/5 of the maximum value, The amount of cutting oil supplied becomes 3/5 of the maximum value.

As described above, the present invention minimizes the consumption of cutting oil by minimizing the amount of cutting oil supplied according to the type of workpiece and the amount of cutting, thereby minimizing environmental pollution and reducing costs.

It is to be understood that the present invention is not limited to the above-described embodiment, and that various modifications and changes may be made without departing from the scope of the present invention as defined in the appended claims. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

10: Machine tool 20: Motor
100: automatic coolant control system 110: input
120: Storage part 130: Cutting amount calculation part
140: control unit 150: inverter

Claims (9)

An information input step of inputting a kind of a work to be machined, a diameter, a rotation speed, a cutting depth, and a feed amount of the tool;
A classification step of classifying the workpiece according to the type of the workpiece;
A weighting step of weighting the amount of cut of the workpieces classified in the classification step;
A cutting amount comparing step of comparing the weighted cutting amount with a weight value before weighting is applied in the weighting step;
An inverter output step of adjusting an output voltage amount of the inverter according to a result of the cutting amount comparing step; And
And a coolant supply step of supplying coolant by regulating the number of revolutions of the motor in accordance with the amount of the output voltage of the inverter,
In the weighting step, a first weight is applied to the cutting amount of the first work, a second weight is applied to the cutting amount of the second work, a third weight is applied to the cutting amount of the third work, Weight,
The first weight is set to 1.1 to 1.2, the second weight is set to 1, and the third weight is set to 0.5 to 0.9,
If the weighted amount of cutting is larger than the amount of cutting before weighting is applied, the amount of output voltage of the inverter is set as a first reference value. If the amount of cut is equal to a second reference value, and,
Wherein the first reference value is a maximum value of the inverter output voltage amount, the second reference value is set to 4/5 of the maximum value, and the third reference value is set to 3/5 of the maximum value. A method of supplying the coolant. The method according to claim 1,
And the cutting amount of the workpiece is calculated in the information input step. The method according to claim 1,
The amount of cut of the workpiece is determined by the following equation,
L (cm2 / min) =? XDxnxTxF / 1000
here,
D is the diameter of the workpiece, n is the rotational speed of the workpiece, T is the cutting depth of the workpiece, and F is the feed rate of the tool. delete delete delete delete The method according to claim 1,
Wherein the rotation speed of the motor increases as the output voltage of the inverter increases, and the amount of the cutting oil supplied increases as the rotation speed of the motor increases. delete

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