KR101494098B1 - Oil diluting device and oil supply machine having the same - Google Patents

Abstract

The present invention relates to an oil diluting device and an oil supply machine having the same. The present invention comprises: a first mixer tube having one side to be blocked by a covered plate and the other side to be opened; a second mixer tube bonded to the open side of the first mixer tube; a supporting shaft positioned inside the second mixer tube; a helical blade connected to a supporting tube and the second mixer tube in order to be disposed between the supporting shaft and the second mixer tube and to mix flowing fluid; a water supply pipe combined in the covered plate of the first mixer tube in order to be connected with the first mixer tube and to supply pressurized water; and an oil supply pipe combined in the outer periphery of the first mixer tube in order to be connected with the first mixer tube and to supply pressurized oil. According to the present invention, the mixing of the water and the oil is efficiently accomplished, and the present invention also prevents the oil from being flowing backward to the side in which water is supplied. In addition, the configuration is simple and the flow resistance is reduced when mixing the water and the oil.

Description

Technical Field [0001] The present invention relates to an oil diluting device,

The present invention relates to an oil dilution device and an oil supply device having the oil dilution device.

In general, a machine tool is a machine that processes a workpiece of a metal or non-metal material to a set dimension. The machine tool is used to cut a workpiece with a cutting tool while reciprocating or rotating the workpiece. Types of machine tools include lathe, milling machine, drilling machine, grinder, planer, shaper and so on.

When a machine tool cuts a workpiece with a cutting tool, frictional heat is generated due to friction between the cutting tool and the workpiece. When the frictional heat generated from the cutting tool and the object to be processed is not cooled, thermal deformation occurs in the cutting tool and the object to be processed, and the accuracy of the processing dimension of the object to be processed is lowered. Therefore, not only the frictional heat is cooled by supplying oil to the cutting tool and the object Thereby minimizing friction.

The oil supplied when the cutting tool of the machine tool is machined varies depending on the material of the object to be processed and the processing conditions of the object to be processed. Depending on the concentration of the oil, thermal deformation of the object, And so on.

The object to be machined is replaced with an oil tank filled with oil at a proper concentration according to the material and processing conditions of the object to be machined by the machine tool so that the oil is supplied to the cutting tool and the object to be machined of the machine tool. In this case, the efficiency of the machine tool is lowered because the oil tank must be replaced according to the material and processing conditions of the object to be processed.

In Korean Registered Patent No. 10-1183220 (hereinafter referred to as "Prior Art 1") (hereafter referred to as "Prior Art 1"), the concentration of the cutting oil is automatically adjusted by mixing the cutting oil with water, There is disclosed an apparatus for supplying a coolant having a controlled concentration.

However, in the prior art 1, there are provided a coolant tank (first storage portion) for storing cutting oil and a water tank (second storage portion) for storing water, and a metering pump for pumping water filled in the water tank and a coolant tank And a metering pump for pumping the filled cutting oil, respectively, the components are complicated, the size of the equipment is large, the manufacturing cost is high, and the installation space is large. Further, when the water tank is used for a long time, corrosion occurs in the water tank, and impurities are mixed in the water to be mixed with the cutting oil.

In addition, in the mixed vortex mixer in which the cutting oil and the water are mixed, the mixing of the cutting oil and the water is not sufficiently performed, and the flow resistance greatly acts. In addition, when the metering pump is stopped, the cutting oil flows back to the water tank, so that the concentration can not be precisely adjusted.

In Korean Patent No. 10-1183221 (hereinafter referred to as "Prior Art 2") (hereinafter referred to as Prior Art 2), the concentration of the cutting oil is automatically adjusted by mixing the cutting oil with water, There is disclosed an apparatus for supplying a coolant having a controlled concentration.

However, in the prior art 2, the mixing of the cutting oil and the water is not sufficiently performed in the vortex mixer (mixing vortex mixer) in which the cutting oil and the water are mixed, and the flow resistance greatly acts, .

Korean Registered Patent No. 10-0866555 (registered on October 28, 2008) (hereinafter referred to as Prior Art 3) and Korea Patent Publication No. 2011-0121951 (published on November 11, 2011) each have a spiral wing And the object is rotated by the rotation unit. However, the prior arts 3 and 4 have a complicated configuration because they are equipped with a rotation unit for rotating the spiral wing.

SUMMARY OF THE INVENTION An object of the present invention is to provide an oil diluting device and an oil supply device having the oil diluting device, which prevent the oil from flowing back to the side where water is supplied as well as the mixing of oil and water efficiently.

Another object of the present invention is to provide an oil diluting device and an oil feeding equipment having the oil diluting device which simplify the construction and reduce the flow resistance.

In order to achieve the object of the present invention as described above, a first mixing tube in which one side is clogged with a double sheath and the other side is opened; A second mixing tube coupled to an open side of the first mixing tube; A support shaft located inside the second mixing tube; A spiral blade coupled to the support tube and the second mixing tube so as to be positioned between the support shaft and the second mixing tube and mixing the flowing fluid; A water supply pipe connected to the double blades of the first mixing pipe to communicate with the first mixing pipe and supplied with pressurized water; And an oil supply pipe connected to the outer circumferential surface of the first mixing pipe to communicate with the first mixing pipe and supplied with pressurized oil.

Preferably, the first mixing pipe is located in a horizontal direction, the water supply pipe is located in parallel with the first mixing pipe, and the oil supply pipe is connected to the upper portion of the first mixing pipe.

The oil supply pipe may include an inner diameter pipe portion connected to the first mixing pipe and an inner diameter pipe portion connected to the inner diameter pipe portion with an inner diameter smaller than that of the inner diameter pipe portion, and the inner diameter of the water supply pipe is preferably uniform.

Wherein a cross sectional area of the flow path of the water supply pipe is equal to a cross sectional area of the flow path of the inner surface portion of the oil supply pipe and the cross sectional flow area of the water supply pipe is smaller than that of the second mixing pipe, Is in the range of 1: 0.4 to 1: 0.6, and the ratio of the cross-sectional area of the flow path of the interior surface portion of the oil supply pipe to the cross-sectional area of the flow path of the interior surface portion is preferably 1: 0.3 to 1: 0.5.

The helical wings are preferably provided over the whole of the support shaft.

The helical wings may be provided at both ends of the support shaft.

Further, in order to achieve the object of the present invention, a mixing tank; An oil diluting device according to claim 1 coupled to said mixing tank; An oil storage tank connected to the oil supply pipe of the oil dilution device and filled with the oil stock solution; A pumping unit connected to the oil supply pipe to pump the oil; The oil diluting device includes a water supply pipe connected to a water supply pipe to which tap water is supplied and a water supply pipe connected to the water supply pipe to block the tap water supplied to the first mixing pipe of the oil diluting device through the water supply pipe, 1 opening / closing unit; A second opening / closing unit connected to the water supply pipe so as to be positioned between the first opening / closing unit and the first mixing pipe of the oil dilution device; And a diluting oil supply pipe connecting the mixing tank and the machine tool.

The present invention is characterized in that an oil stock solution in which a certain flow rate is pumped by a pumping unit and water supplied from a water pipe are mixed first in a first mixing pipe and then in a second order while flowing through a spiral wing of a second mixing pipe, Is effectively mixed. In addition, the water supply pipe is connected to the blending plate of the first mixing pipe, the water flowing into the first mixing pipe through the water supply pipe flows in parallel with the first mixing pipe, and the oil supply pipe is connected to the outer peripheral surface of the first mixing pipe Since the oil stock solution flowing into the first mixing tube through the oil supply pipe flows in the radial direction of the first mixing pipe, the water and the oil stock solution are effectively mixed in the first mixing pipe. In addition, when the oil supply pipe is composed of the inner and outer scopes, the flow rate is lowered when the oil stock solution flows into the inner scape through the inner diameter of the inner diameter of the inner diameter of the inner diameter of the inner diameter portion.

In addition, since the water supply pipe is connected to the blending plate of the first mixing pipe and the oil supply pipe is connected to the upper part of the outer circumference of the first mixing pipe, water is prevented from flowing into the oil supply pipe To prevent backflow.

In addition, since the water supply pipe is connected to the water pipe to dilute the oil solution with water (tap water) supplied from the water pipe, the use of the water pump and the metering pump for pumping water from the water tank is eliminated, . As a result, the manufacturing cost of the apparatus is reduced, and the size of the apparatus is reduced, thereby reducing the installation space.

1 is a plan view showing an embodiment of an oil supply apparatus equipped with an oil dilution device according to the present invention,
2 is a side sectional view showing an embodiment of an oil dilution device according to the present invention,
3 is a front view showing a spiral wing constituting an embodiment of the oil dilution device according to the present invention, Fig.
4 is a side sectional view showing another embodiment of a helical blade constituting one embodiment of the oil diluting device according to the present invention,
5 is a side sectional view showing an operating state of the oil diluting device according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of an oil diluting apparatus and an oil supplying apparatus having the oil diluting apparatus according to the present invention will be described with reference to the accompanying drawings.

1 is a plan view showing an embodiment of an oil supply apparatus provided with an oil dilution device according to the present invention. 2 is a side cross-sectional view showing an embodiment of an oil dilution device according to the present invention.

1 and 2, an embodiment of the oil diluting device and the oil supplying equipment provided with the oil diluting device according to the present invention includes a mixing tank 100, an oil diluting device 200, an oil storage tank 300, Unit 400, a first opening and closing unit 500, a second opening and closing unit 600, and a diluting oil supply pipe 700.

The mixed liquid (or diluent) is stored in the mixing tank 100. The shape of the mixing tank 100 may be various shapes such as a cylindrical shape or a hexahedron shape.

The oil dilution device 200 mixes the oil and water. Preferably, the oil dilution device 200 is installed above the side surface of the mixing tank 100.

In an embodiment of the oil dilution device 200, the oil dilution device 200 includes a first mixing pipe 210, a second mixing pipe 220, a support shaft 230, a spiral wing 240, A water supply pipe 250, and an oil supply pipe 260.

The first mixing pipe 210 has a predetermined length, one of which is blocked by the double bladder 211 and the other is opened. The first mixing pipe 210 is preferably a cylindrical pipe. The first mixing pipe 210 may be a rectangular pipe. The first mixing pipe 210 is coupled to the mixing tank 100. At this time, a through hole is formed in the upper side of the mixing tank 100, and a part of the opening of the first mixing pipe 210 is inserted into the through hole, and the first mixing pipe 210 and the mixing tank 100 ) Are preferably combined. It is preferable that the first mixing pipe 210 is positioned in a horizontal state.

The second mixing pipe 220 is coupled to the opened side of the first mixing pipe 210 and a portion of the second mixing pipe 220 is coupled to the opened portion of the first mixing pipe 210. The second mixing tube 220 has a predetermined length and is opened at both sides. The cross-sectional shape of the second mixing pipe 220 is preferably the same as the cross-sectional shape of the first mixing pipe 210. The second mixing pipe 220 is located on the same line as the first mixing pipe 210.

The support shaft 230 is preferably a round bar or tube having a predetermined length. The support shaft 230 is located inside the second mixing pipe 220. The length of the support shaft 230 is preferably shorter than the length of the second mixing pipe 220.

The spiral wing 240 has a shape in which a plate having a uniform width, thickness, and length is wound many times so as to form a spiral along the outer peripheral surface of the support shaft 230. It is preferable that the inner surface of the helical wing 240 is in contact with the outer circumferential surface of the support shaft 230 and the outer surface of the helical wing 240 is in contact with the inner circumferential surface of the second mixing tube 220. Preferably, the helical wings 240 are provided over the whole of the support shaft 230.

Preferably, the surface of the helical wing 240 is provided with a resistance element 241 for promoting mixing of the fluid. The resistance element 241 is preferably provided on one side of the helical blade 240, as shown in FIG. The resistance element 241 is preferably a plurality of protrusions or grooves protruding from one side of the helical blade 240, respectively.

4, the helical wing 240 includes a first unit helical wing 240A and a second helical wing 240A provided at one end of the support shaft 230 and a support shaft 230, And a second unit spiral blade 240B provided at the other end of the second unit spiral blade 240B. The first and second unit spiral blades 240A and 140B have the same shape as the spiral blades 240 and are shorter than the spiral blades 240, respectively. When the first and second unitary helical wings 240A and 24B are provided at both ends of the support shaft 230, when the fluid flows through the second mixing tube 220, the unit helical wings 240 pass through The fluid is firstly mixed and flows between the two unit helical blades 240 as a laminar flow, and then passes through another unit helical blades 240 and is mixed with the second unit to increase the mixing efficiency of the fluid. In addition, since unit spiral blades are provided at both ends of the support shaft 230, the use amount of the spiral blades 240 is reduced, and assembly work is facilitated.

The water supply pipe 250 is connected to the blending plate 211 of the first mixing pipe 210 so as to communicate with the first mixing pipe 210. The pressurized water is supplied to the water supply pipe 250. The water supplied to the water supply pipe 250 flows into the first mixing pipe 210. The water supply pipe 250 is preferably disposed in parallel with the first mixing pipe 210. The inner diameter of the water supply pipe 250 is preferably uniform.

The oil supply pipe 260 is coupled to the outer circumferential surface of the first mixing pipe 210 to communicate with the first mixing pipe 210. The oil pressurized by the oil supply pipe 260 is supplied. The oil supplied to the oil supply pipe 260 flows into the first mixing pipe 210. The oil supply pipe 260 is connected to the upper portion of the first mixing pipe 210. The oil supply pipe 260 includes an inner pipe section 261 connected to the first mixing pipe 210 and an inner pipe section 262 connected to the inner pipe section 261 with an inner diameter smaller than that of the inner pipe section 261 do. When the oil supply pipe 260 includes the in-house scenery section 261 and the in-house scenery section 262, the flow rate is lowered when the oil that has passed through the in-house scenery section 262 flows into the inside scenery section 261. On the other hand, the inner diameter of the oil supply pipe 260 may be uniformly formed.

The cross sectional flow area of the water supply pipe 250 is equal to the cross sectional area of the inner hood pipe section 261 of the oil supply pipe 260 and the cross sectional area of the water supply pipe 250 is preferably smaller than that of the second mixing pipe 220 Do. The ratio (A: B) of the flow cross sectional area A of the second mixing pipe 220 to the flow cross sectional area B of the water supply pipe 250 is preferably 1: 0.4 to 1: 0.6, more preferably 1: : 0.5. The ratio (C: D) of the flow path cross-sectional area C of the inside flow path portion 261 of the oil supply pipe 260 to the flow path cross-sectional area D of the inside flow path portion 262 is preferably 1: 0.3 to 1: 0.5 , More preferably 1: 0.4. When the ratio of the flow path cross-sectional area A of the second mixing pipe 220 to the flow path cross-sectional area B of the water supply pipe 250 becomes 1: 0.3 or less, the water introduced into the water supply pipe 250 and the oil supply pipe 260 The amount of the fluid flowing to the second mixing pipe 220 is small and the resistance of the fluid in the second mixing pipe 220 is reduced. However, since the amount of the fluid flowing into the second mixing pipe 220 is small, The wings 240 are not sufficiently mixed. On the other hand, when the ratio of the flow cross-sectional area A of the second mixing pipe 220 to the flow cross-sectional area B of the water supply pipe 250 becomes larger than 1: 0.6, the water flows into the water supply pipe 250 and the oil supply pipe 260 The amount of the fluid flowing to the second mixing pipe 220 is increased due to the increased flow rate of the water and the oil, so that the water and the oil are sufficiently mixed by the spiral wing 240 located inside the second mixing pipe 220 The mixing efficiency can be increased, but the resistance of the fluid flowing into the second mixing pipe 220 is increased.

The oil storage tank 300 is connected to the oil supply pipe 260 of the oil dilution device 200. The oil supply pipe 260 is coupled to the oil storage tank 300 in a penetrating manner. The oil reservoir 300 is filled with the oil stock solution. The shape of the oil storage tank 300 may be various shapes such as a cylindrical shape or a hexahedron shape.

The pumping unit 400 is connected to the oil supply pipe 260. The pumping unit (400) pumps the oil. The pumping unit 400 preferably includes a metering pump.

The water supply pipe 250 of the oil dilution device 200 is connected to the water pipe 800 to which tap water is supplied. Since the water supply pipe 250 is connected to the water pipe 800, the use of a separate water tank and a metering pump for pumping water from the water tank is excluded.

The first opening and closing unit 500 is installed in the water supply pipe 250 of the oil dilution device 200. The first opening / closing unit 500 blocks or prevents the internal flow path of the water supply pipe 250 to prevent water from flowing into the water supply pipe 250 or prevent water from flowing. The first opening and closing unit 500 preferably includes a solenoid valve.

The second opening / closing unit 600 is installed in the water supply pipe 250 so as to be positioned between the first opening / closing unit 500 and the first mixing pipe 210. The second opening and closing unit 600 is preferably a check valve. The second opening and closing unit 600 prevents the water from flowing back to the first opening and closing unit 500 while the first opening and closing unit 500 blocks the flow path of the water supply pipe 250.

The dilution oil supply pipe 700 connects the mixing tank 100 and the machine tool FM so that the mixed liquid filled in the mixing tank 100 can be supplied to the machine tool FM. One of the dilution oil supply pipes 700 is coupled to penetrate the interior of the mixing tank 100.

The mixing tank 100, the oil dilution device 200, the oil storage tank 300, the pumping unit 400, the first opening / closing unit 500, the second opening and closing unit 600, . At this time, a part of the water supply pipe 250 of the oil dilution device 200 is exposed to the outside of the outer case.

Hereinafter, the operation and effects of the oil diluting device and the oil supplying device having the oil diluting device according to the present invention will be described.

First, the first opening and closing unit 500 is opened in a state where tap water of the water pipe is introduced into the water supply pipe 250. At the same time, the pumping unit 400 is operated to pump a predetermined amount of the oil stock solution stored in the oil storage tank 300 through the oil supply pipe 260. The water (tap water) supplied to the water supply pipe 250 is introduced into the first mixing pipe 210 in parallel with the first mixing pipe 210 and supplied to the oil supply pipe 260, And flows into the first mixing pipe 210 in a direction perpendicular to the longitudinal direction (radial direction) of the pipe 210.

As shown in FIG. 5, the water and the oil stock flowing into the first mixing pipe 210 are first mixed in the first mixing pipe 210, and then flows into the second mixing pipe 220. The water and the oil stock solution are uniformly mixed by the helical wing 240 while flowing through the spiral wing 240 of the second mixing tube 220 while the stock solution of water and oil flows through the second mixing tube 220 . The mixing tank 100 is filled with the oil stock solution mixed with water while flowing through the second mixing pipe 220. When the mixture liquid in which the amount of water and the oil stock solution set in the mixing tank 100 is filled is filled, the operation of the pumping unit 400 is stopped, and the first opening / closing unit 500 is closed, (210). The mixed liquid to be filled in the mixing tank 100 is a mixture of water and diluted oil. The concentration of the diluting oil filled in the mixing tank 100 is adjusted by adjusting the amount of the oil stock solution pumped in the pumping unit 400 since the amount of water supplied through the water pipe 800 is constant. The diluted oil to be filled in the mixing tank 100 is supplied to the machine tool FM through the dilution oil supply pipe 700.

The present invention is characterized in that the oil source liquid in which a predetermined flow rate is pumped by the pumping unit 400 and the water supplied from the water pipe 800 are mixed first in the first mixing pipe 210 and then in the spiral wing of the second mixing pipe 220 (240) so that the oil stock solution and water are effectively mixed. The water supply pipe 250 is connected to the blending plate 211 of the first mixing pipe 210 so that the water flowing into the first mixing pipe 210 through the water supply pipe 250 flows into the first mixing pipe 210, And the oil supply pipe 260 is connected to the outer circumferential surface of the first mixing pipe 210 and the oil mixture flowing into the first mixing pipe 210 through the oil supply pipe 260 flows into the first mixing pipe 210 So that the water and the oil stock solution are effectively mixed in the first mixing pipe 210. In addition, when the oil supply pipe 260 is composed of the in-house scenic section 261 and the in-house scenic section 262, the flow rate of the oil is lowered when the original oil flows into the in-house scenic section 261 through the in-situ landscape section 262 And is more effectively mixed with the flowing water in the first mixing pipe 210.

Since the water supply pipe 250 is connected to the replenishment plate 211 of the first mixing pipe 210 and the oil supply pipe 260 is connected to the upper part of the outer circumferential surface of the first mixing pipe 210, It prevents water from flowing back to the oil supply pipe 260 when blocking the water and the oil stock solution flowing into the pipe 210.

The water supply pipe 250 is connected to the water pipe 800 to dilute the oil solution with water supplied from the water pipe 800. Therefore, the use of the water pump and the metering pump for pumping water from the water tank The configuration is simplified. As a result, the manufacturing cost of the apparatus is reduced, and the size of the apparatus is reduced, thereby reducing the installation space.

100; A mixing tank 200; Oil dilution device
210; A first mixing tube 220; The second mixing tube
230; A support shaft 240; Spiral wing
250; A water supply pipe 260; Oil supply pipe
300; Oil storage tank 400; Pumping unit
500; A first opening and closing unit 600; The second opening /
700; Dilution oil supply pipe

Claims (7)

Mixing tank;
A first mixing pipe connected to the mixing tank so as to be pierced, one of which is clogged by the double bladder and the other of which is opened;
A second mixing tube connected to an opening side of the first mixing tube;
An oil storage tank filled with the oil stock solution;
An oil supply pipe connecting the oil storage tank and the first mixing pipe;
A pumping unit connected to the oil supply pipe for pumping the oil stock solution from the oil storage tank to the first mixing pipe;
A water supply pipe connecting the first mixing pipe and the water pipe and supplying tap water to the first mixing pipe;
A first opening / closing unit connected to the water supply pipe to block or stop the flow of tap water;
A second opening / closing unit provided in the water supply pipe so as to be positioned between the first opening / closing unit and the first mixing pipe;
A support shaft located inside the second mixing tube;
A spiral blade provided between the support shaft and the second mixing tube to mix the fluid;
And a dilution oil supply pipe connecting the mixing tank and the machine tool,
Wherein the first mixing pipe is disposed in a horizontal direction and the water supply pipe is coupled to allow water to flow in parallel with the first mixing pipe, the oil supply pipe is connected to an upper portion of the first mixing pipe, And the second mixing tube is connected to the outer circumferential surface of the first mixing tube so as to be introduced into the first mixing tube in the vertical direction,
Wherein the oil supply pipe includes an in-house landscape part connected to the first mixing pipe, and an in-house landscape part connected to the in-building landscape part with an inner diameter smaller than that of the inside in-landscape part. delete delete 2. The water treatment system according to claim 1, wherein the flow path cross-sectional area of the water supply pipe and the flow path cross-sectional area of the inner flow path portion of the oil supply pipe are the same, the flow path cross-sectional area of the water supply pipe is smaller than that of the second mixing pipe, Wherein the ratio of the cross-sectional area of the flow path of the water supply pipe to the cross-sectional area of the flow path of the oil supply pipe is 1: 0.4 to 1: 0.6, equipment. The oil supply apparatus according to claim 1, wherein the helical vanes are provided at both ends of the support shaft. The oil supply apparatus according to claim 1, wherein a resistance element is provided on one side of the helical blade.



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