KR102168108B1 - Nozzle for metal working fluid - Google Patents

Abstract

The present invention provides a nozzle for supplying cutting oil to a cutting surface, comprising: a first supply pipe having a predetermined diameter and length; An air supply unit disposed outside the first supply pipe and having an air supply hole for supplying air to the inside of the first supply pipe; A second supply pipe having a predetermined length, an outer circumference of which is spaced apart from an inner circumferential surface of the first supply pipe, and disposed inside the first supply pipe; A first air guide part protruding at a predetermined height toward the inner circumference of the first supply pipe along the periphery of one end of the second supply pipe; And a second air guide unit configured to provide a first unit air supply port in a ring shape, the outer circumference connected to one end of the first supply pipe, the inner circumference disposed inside the second supply pipe, and facing the inside of the first supply pipe. It includes, and provides a cutting oil supply nozzle through which the cutting oil introduced to one end of the second supply pipe is supplied to the cutting surface through the other end of the second supply pipe.
In the present invention, cutting oil is supplied in the form of a mist, but intensive supply can be made to a portion where cutting is performed, and the flow rate of the supplied cutting oil can be increased by the Coanda effect, and the cooled air can be cut together It is possible to cool the cutting area by supplying it to the processing area, and by forming an air curtain around the supplied cutting oil, the cutting oil can be concentrated and supplied to the cutting surface.

Description

Coolant supply nozzle {Nozzle for metal working fluid}

The present invention relates to a coolant supply nozzle, and more particularly, to a coolant supply nozzle capable of intensive coolant supply to a cutting surface by using the Coanda effect during a cutting operation using a machine tool.

A machine tool is a machine that processes a metal or non-metal material (hereinafter referred to as the base material) by cutting or the like using a suitable tool by various cutting or non-cutting processing methods.

During the cutting operation, frictional heat is generated, and this frictional heat causes a decrease in durability of the cutting machine tool. In addition, if the chips generated by the cutting process are left as they are, precise base material processing cannot be performed.

Therefore, cutting machine tools use cutting oil to quickly remove generated heat to obtain a high-quality work piece and to smoothly remove chips.

Here, a large amount of cutting oil is supplied for efficient cutting processing, but this causes a cost increase, and there is a problem of deteriorating the working environment and harming the health of the worker.

To prevent this, in order to minimize the supply of cutting oil, minimum quantity lubricant (MQL) processing has been put into practice. This is a technology for spraying cutting oil for cooling and lubricating a tool or a workpiece in the form of a mist has been developed.

Spraying the cutting oil in the form of mist is good for cost reduction and environment, but there is a problem that the temperature of the cutting surface rises.

A technology for cooling and supplying cutting oil to prevent temperature rise of the cutting surface during cutting has been disclosed.

However, the technology of supplying less or finely supplying the cutting oil or the technology of cooling and supplying the cutting oil has a problem in that the degree of wear of the cutting tool is large and the degree of cutting is reduced.

As a prior art for the present invention, Korean Patent Publication No. 2004-77521 may be exemplified.

An object of the present invention is to provide a cutting oil supply nozzle that supplies cutting oil in a mist form, but provides intensive supply to a portion where cutting is performed.

In addition, an object of the present invention is to provide a coolant supply nozzle capable of supplying by increasing the flow rate of the coolant supplied by the Coanda effect.

Another object of the present invention is to provide a cutting oil supply nozzle capable of cooling a cutting portion by supplying cooled air together with a cutting oil to a cutting portion.

In addition, an object of the present invention is to provide a coolant supply nozzle capable of concentrating and supplying the coolant to a cutting surface by forming an air curtain around the supplied coolant.

In order to achieve the above object, the present invention provides a nozzle for supplying cutting oil to a cutting surface, comprising: a first supply pipe having a predetermined diameter and length; An air supply unit disposed outside the first supply pipe and having an air supply hole for supplying air to the inside of the first supply pipe; A second supply pipe having a predetermined length, an outer circumference of which is spaced apart from an inner circumferential surface of the first supply pipe and disposed inside the first supply pipe; A first air guide part protruding at a predetermined height toward the inner circumference of the first supply pipe along the periphery of one end of the second supply pipe; And a second air guide unit configured to provide a first unit air supply port in a ring shape, the outer circumference connected to one end of the first supply pipe, the inner circumference disposed inside the second supply pipe, and facing the inside of the first supply pipe. It includes, and provides a cutting oil supply nozzle through which the cutting oil introduced to one end of the second supply pipe is supplied to the cutting surface through the other end of the second supply pipe.

In a ring shape, an outer periphery is connected to the other end of the first supply pipe, and an inner periphery is disposed between the first supply pipe and the second supply pipe, and provides a second unit air supply port toward the central axis of the first supply pipe. 3 may further include an air induction unit.

The cutting oil may be in a mist state.

A central axis of the first supply pipe and the second supply pipe may coincide.

The second supply pipe may increase in diameter from one end to the other end.

The outer periphery of the first air induction part may have a curved shape having a predetermined curvature.

The second air induction part may extend inside the second supply pipe.

The second air induction part may have a curved cross section protruding toward the rear of the first supply pipe.

The third air induction part may be disposed to be inclined from the other end of the first supply pipe toward the front of the other end of the second supply pipe.

The air may contain carbon dioxide.

The air may be cooled and supplied.

In the present invention as described above, the cooled cutting oil is supplied in the form of a mist, but intensive supply may be made to a portion where cutting is performed.

In addition, the present invention can be supplied by increasing the flow rate of the cutting oil supplied by the Coanda effect.

In addition, the present invention can cool the cutting portion by supplying the cooled air together with the cutting oil to the cutting portion.

In addition, according to the present invention, an air curtain is formed around the supplied cutting oil, so that the cutting oil can be concentrated and supplied to the cutting surface.

1 is a perspective view showing the configuration of a cutting oil supply nozzle according to an embodiment of the present invention.
2 is a cross-sectional view taken along line AA of FIG. 1.
3 is a view showing the supply of cutting oil by the cutting oil supply nozzle according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a configuration of a cutting oil supply nozzle according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along line A-A of FIG. 1.

1 and 2, a cutting oil supply nozzle 100 according to an embodiment of the present invention includes a first supply pipe 110, an air supply unit 120, a second supply pipe 130, and a first air guide unit 140A. ), a second air induction part 140B and a third air induction part 140C.

The first supply pipe 110 is a pipe having a predetermined diameter and length, and provides a flow space in which the cutting oil flows.

In addition, a second supply pipe 130 to be described later is disposed on the flow space in the first supply pipe 110.

The air supply unit 120 has a hexahedral shape having a predetermined size and is disposed on one side of the first supply pipe 110.

In this embodiment, a pair of the air supply units 120 are arranged to face each other in a direction orthogonal to the central axis of the first supply pipe 110, but the number of arrangements may be increased or decreased according to the needs of the user.

An air supply hole 122 communicating with the inner space of the first supply pipe 110 is formed on the air supply unit 120. The air supply hole 122 supplies predetermined air supplied from the outside to the coolant flow space of the first supply pipe 110.

The central axis of the air supply hole 122 is orthogonal to the central axis of the first supply pipe 110.

Air supplied through the air supply hole 122 includes carbon dioxide (CO ₂ ). In addition, air supplied through the air supply hole 122 may be cooled to a temperature below a certain temperature (for example, below 0°C) and supplied.

The cooled air may be supplied to the cutting surface together with the cutting oil, and then cool the cutting surface where heat is generated during cutting.

The second supply pipe 130 is disposed inside the first supply pipe 110. Here, the central axis of the second supply pipe 130 is disposed to coincide with the central axis of the first supply pipe 110.

The length of the second supply pipe 130 corresponds to the length of the first supply pipe 110. And, the diameter of the second supply pipe 130 increases from one end to the other end.

Since the outer periphery of the second supply pipe 130 is spaced apart from the inner periphery of the first supply pipe 110, the space between the outer periphery of the second supply pipe 130 and the inner periphery of the first supply pipe 110 is an air supply hole 122 The air supplied through the air flows to form an air chamber (C).

In addition, after the air supplied through the air supply hole 122 is bisected at the outer circumference of the second supply pipe 130, it may flow to both ends of the second supply pipe 130.

The inside of the second supply pipe 130 is provided as a space through which the cutting oil flows.

Cutting oil is supplied to one end of the second supply pipe 130 through a predetermined cutting oil supply means, not shown. Coolant is supplied in the form of a fine mist.

Here, the direction in which the cutting oil is supplied from the second supply pipe 130 is referred to as the rear, and the direction in which the cutting oil is supplied is referred to as front.

The cutting oil flows from one end of the inner space of the second supply pipe 130 to the other end, and then is supplied to the front, that is, to a portion where cutting is performed.

The first air induction part 140A protrudes to a predetermined height toward the inner circumference of the first supply pipe 110 along the outer circumference of one end of the second supply pipe 130.

The outer periphery of the first air induction part 140A has a curved shape having a predetermined curvature.

After being supplied through the air supply hole 122, the first air induction unit 140A is divided by the second supply pipe 130 to move the air, which moves to one end of the second supply pipe 130. Air flow is achieved by the Coanda effect.

The Coanda effect is a phenomenon in which an air stream ejected from approaching a wall or ceiling surface flows along the surface.

Accordingly, the air moving to one end of the outer circumference of the second supply pipe 130 moves along the surface of the first air guide portion 140A.

In this case, the flow velocity of the air moving along the surface of the first air induction part 140A may increase.

The second air induction part 140B is formed to extend from one end of the first supply pipe 110.

The second air induction part 140B extends from one end of the first supply pipe 110 toward the coolant flow space of the first supply pipe 110. Here, the end of the second air induction part 140B may extend to the inside of the second supply pipe 130. In addition, an end of the second air induction part 140B is spaced apart from one end of the second supply pipe 130 by a predetermined distance.

At this time, the second air induction part 140B may have a curved cross section of a predetermined curvature protruding toward the rear.

The space between the end of the second air induction part 140B and the second supply pipe 130 is a first unit air that allows the air in the air chamber C to flow into the coolant flow space inside the second supply pipe 130. It is provided with a supply port 150A.

Since the first unit air supply port 150A is formed in a ring shape surrounding the coolant flow space, the air flowing into the coolant flow space through the first unit air supply port 150A surrounds the coolant and together with the cutting oil. It can flow forward.

The third air induction part 140C is formed to extend from the other end of the first supply pipe 110 toward the front of the central axis of the second supply pipe 130, and the end of the third air induction part 140C is the second supply pipe 130 It is spaced a certain distance from the other end of.

A space apart from the end of the third air induction part 140C and the other end of the second supply pipe 130 is a first to allow the air in the air chamber C to flow around the coolant flowing through the second supply pipe 130. It is provided as a two-unit air supply port 150B.

Since the second unit air supply port 150B is formed in a ring shape surrounding the coolant flow space, air flowing through the second unit air supply port 150B is supplied through the coolant and the first unit air supply port 150A. It forms an air curtain surrounding the circumference of the air and prevents the spread of supplied cutting oil.

The operation of the present invention configured as described above will be described.

The operator arranges the cutting oil supply nozzle 100 according to the present invention toward a workpiece on which a predetermined cutting process is performed.

At one end of the coolant supply nozzle 100, coolant is supplied in the form of a mist through a predetermined coolant supply means, and at the same time, a predetermined cooled air is supplied to the air chamber C through the air supply hole 122. .

3 is a view showing the supply of cutting oil by the cutting oil supply nozzle according to an embodiment of the present invention.

In FIG. 3, only the first and second supply pipes and the first to third air guide units are illustrated in order to facilitate understanding of the drawings.

Here, the air supplied through the air supply hole 122 generates the following flow.

Air supplied to the air chamber C through the air supply hole 122 is divided and flows from the outer periphery of the second supply pipe 130 to the rear and the front of the second supply pipe 130.

After the air moving to the rear of the second supply pipe 130 moves along the surface of the first induction part 140A due to the Coanda effect, the air of the second supply pipe 130 through the first unit air supply port 150A Flows inward.

The air flowing through the first unit air supply port 150A surrounds the circumference of the cutting oil introduced through one end of the second supply pipe 130 and moves to the front of the second supply pipe 130 together with the cutting oil.

In this case, the flow rate of the cutting oil may increase by air supplied through the first unit air supply port 150A.

The cutting oil may be supplied to a predetermined cutting portion through the other end of the second supply pipe 130.

Meanwhile, air flowing from the outer periphery of the second supply pipe 130 to the front of the second supply pipe 130 is supplied through the second unit air supply port 140B.

The air flowing through the second unit air supply port 140B forms the coolant flowing through the second supply pipe 130 and an air curtain surrounding the air, preventing the supplied coolant from spreading. do.

The supplied cutting oil is supplied to the cutting part, so that the cutting process is easily performed.

In addition, air supplied together with the cutting oil may cool heat generated from the object to be cut during cutting.

In the present invention, cutting oil is supplied in the form of mist, but intensive supply can be made to a portion where cutting is performed, and the flow rate of the supplied cutting oil can be increased and supplied by the Coanda effect, and the cooled air is cut together with the cutting oil. It is possible to cool the cutting area by supplying it to the processing area, and by forming an air curtain around the supplied cutting oil, the cutting oil can be concentrated and supplied to the cutting surface.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of the present invention should be determined by the technical spirit of the appended claims.

100: coolant supply nozzle 110: first supply pipe
120: air supply unit 130: second supply pipe
140A, 140B, 140C: first to third air guide units
150A: first unit air supply port 150B: second unit air supply port

Claims (11)

As a nozzle that supplies cutting oil to the cutting surface,
A first supply pipe in which a coolant flow space through which the coolant flows is formed;
An air supply unit disposed outside the first supply pipe and having an air supply hole for supplying air to the inside of the first supply pipe;
A second supply pipe having an outer circumferential surface spaced apart from the inner circumferential surface of the first supply pipe and forming an air chamber between the first supply pipe;
A first air guide part protruding at a predetermined height toward the inner circumference of the first supply pipe along the periphery of one end of the second supply pipe;
A second air induction part extending from one end of the first supply pipe and having one end spaced apart from the first air induction part to form a first unit air supply port through which air in the air chamber flows into the cutting oil flow space ; And
The third air is formed extending from the other end of the first supply pipe, and has one end spaced apart from the other end of the second supply pipe to form a second unit air supply port through which the air of the air chamber flows into the coolant flow space. Coolant supply nozzle including a guide portion.
delete The method of claim 1,
The cutting oil,
Coolant supply nozzle in mist state. The method of claim 1,
The first supply pipe and the second supply pipe,
Coolant supply nozzle with coincident central axis. The method of claim 1 or 4,
The second supply pipe,
Coolant supply nozzle whose diameter increases from one end to the other. The method of claim 1,
A cutting oil supply nozzle formed in a curved shape having a predetermined curvature on the outer periphery of the first air guide part. The method of claim 1,
The second air induction part,
A coolant supply nozzle extending into the second supply pipe. The method of claim 7,
The second air induction part,
A cutting oil supply nozzle having a curved cross section protruding toward the rear of the first supply pipe. The method of claim 1,
The third air induction part,
A cutting oil supply nozzle disposed at an angle from the other end of the first supply pipe toward the front of the other end of the second supply pipe. The method of claim 1,
The air is,
Coolant supply nozzle containing carbon dioxide. The method of claim 10,
The air is,
Coolant supply nozzle supplied by cooling.

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