Patent Application
20180023600
This application is based upon and claims the benefit of priority under 35 USC 119 of Korean Patent Application No. 2016-0094458 filed on Jul. 25, 2016, the entire disclosure of which is incorporated herein by reference in its entirety for all purposes.
The present invention relates to a fluid supply pipe for an apparatus for supplying a fluid. More specifically, the present invention relates to a fluid supply pipe which applies a predetermined flow characteristic to a fluid flowing therethrough. For example, the fluid supply pipe of the present invention is applicable to a cutting fluid supply apparatus for various machine tools such as a grinding machine, a drilling machine, and a cutting machine.
Conventionally, when a workpiece made of a metal or the like is machined into a desired shape by a machine tool such as the grinding machine or the drilling machine, a machining fluid (for example, coolant) is supplied to a contact portion between the workpiece and a tool (for example, a blade) in order to cool heat generated during machining or remove debris of the workpiece (also referred to as chips) from a machining spot. Cutting heat caused by high pressure and frictional resistance at the contact portion between the workpiece and the blade abrades the edge of the blade and lowers the strength of the blade, thereby reducing tool life of the blade. In addition, if the chips of the workpiece are not sufficiently removed, they can stick to the edge of the blade during machining, which may degrade machining accuracy.
The machining fluid (also referred to as a cutting fluid) decreases the frictional resistance between the tool and the workpiece, removes the cutting heat, and performs cleaning to remove the chips cut off from a surface of the workpiece. For this, the machining fluid should have a low coefficient of friction, a high boiling point, and good penetration into the contact portion between the blade and the workpiece.
For example, Japanese Patent Application Laid-Open Publication No. 1999-254281 published on Sep. 21, 1999 (published also as U.S. Pat. No. 6,095,899), discloses providing a gas emitting means for emitting a gas (for example, air) in a machining apparatus in order to forcibly infiltrate a machining liquid into a contact portion between a working element (i.e. a blade) and a workpiece.
According to the conventional technology as disclosed in the above patent document, the means for emitting the gas at a high speed and high pressure should be provided in the machining apparatus in addition to a means for spraying the machining liquid, thus increasing the cost and the size of the apparatus. Further, in the grinding machine, the machining liquid cannot sufficiently reach a contact portion between a grindstone and the workpiece because the air rotates along the outer circumferential surface of the grindstone together with the grindstone rotating at a high speed. Thus, there is still a problem that it is difficult to cool the heat generated during machining sufficiently because the machining liquid cannot sufficiently penetrate into the contact portion by simply emitting the air in the same direction as the rotation direction of the grindstone.
The present invention was made in light of the problems mentioned above. An object of the present invention is to provide a fluid supply pipe for applying a predetermined flow characteristic to a fluid flowing therethrough to improve lubricity, penetration, and a cooling effect of the fluid.
In order to achieve the above object, an embodiment of the present invention provides a fluid supply pipe including an internal structure and a pipe body configured to house the internal structure. The pipe body has an inlet and an outlet and has a circular cross-section. The internal structure includes a first portion for diffusing a fluid flowing into the fluid supply pipe through the inlet radially from the center of the fluid supply pipe, the first portion being placed in the inlet side of the pipe body when the internal structure is housed in the pipe body, a second portion placed downstream from the first portion and including a plurality of spiral vanes to swirl the fluid diffused by the first portion, and a third portion placed downstream from the second portion and including a plurality of protrusions on its outer circumferential surface.
Another aspect of the present invention provides an internal structure of a fluid supply pipe which comprises a pipe body having an inlet and an outlet. The internal structure includes a fluid diffusing portion for diffusing a fluid flowing into the fluid supply pipe through the inlet radially from the center of the fluid supply pipe, the fluid diffusing portion being placed in the inlet side of the pipe body when the internal structure is housed in the pipe body, a swirl generating portion placed downstream from the fluid diffusion portion for swirling the fluid diffused by the fluid diffusion portion, and a bubble generating portion placed downstream from the swirl generating portion for generating multi bubbles in the fluid swirled by the swirl generating portion.
If the fluid supply pipe according to some embodiments of the present invention is provided in a fluid supply unit of a machine tool or the like, a cleaning effect is improved over the prior art due to vibration and impact generated during a process in which a plurality of micro bubbles generated in the fluid supply pipe collide with the tool and the workpiece and break. Thus, the life of the tool such as the cutting blade can be extended and the cost of replacing the tool can be reduced. In addition, the characteristic applied by the fluid supply pipe according to some embodiments of the present invention can increase the cooling effect and improve the lubricity by increasing penetration of the fluid, thereby enhancing the precision of machining.
Further, according to many embodiments of the present invention, the internal structure of the fluid supply pipe is manufactured as one integrated component. Therefore, assembly of the internal structure with a pipe body is simplified.
The fluid supply pipe can be applied to a machining fluid supply unit in various machine tools such as the grinding machine, the cutting machine, and the drilling machine. In addition, it can be effectively used in an apparatus for mixing two or more fluids (liquid and liquid, liquid and gas, or gas and gas).
The above and further objects and novel features of the present invention will more fully appear from the following detailed description when the same is read in conjunction with the accompanying drawings. It is to be expressly understood, however, that the drawings are for the purpose of illustration only and are not intended to limit the scope of the invention.
Here:
Embodiments in which the present invention is applied to machine tools such as a grinding machine will be mainly described herein. However, the field of application of the present invention is not intended to be limited to the illustrated examples. The present invention is applicable to various situations requiring supply of a fluid, such as a household shower nozzle or a fluid mixing apparatus.
Hereinafter, the embodiments of the present invention will be described with reference to the accompanying drawings.
The fluid supply unit 5 includes a delivery pipe 6 into which a fluid stored in the tank is flowed by the pump, a fluid supply pipe 10 having an internal structure for applying a predetermined flow characteristic to the fluid, and a nozzle 7 having a discharge port disposed close to the grinding spot G. The fluid supply pipe 10 and the delivery pipe 6 are connected, for example, by engaging a female screw of a nut 11 which is a connecting member provided on the side of the inlet 8 of the fluid supply pipe 10 with a male screw (not shown in the drawing) formed on the outer peripheral surface of one end of the delivery pipe 6 (by thread cutting, for example). The fluid supply pipe 10 and the nozzle 7 are connected, for example, by engaging a female screw of a nut 12 which is a connecting member provided on the side of the outlet 9 of the fluid supply pipe 10 with a male screw (not shown in the drawing) formed on the outer peripheral surface of one end of the nozzle 7 (by thread cutting, for example). The fluid flowing into the fluid supply pipe 10 from the delivery pipe 6 has a predetermined flow characteristic applied by the internal structure while passing though the fluid supply pipe 10. The fluid is discharged toward the grinding spot G through the outlet 9 of the fluid supply pipe 10 and the nozzle 7. According to many embodiments of the present invention, the fluid passing through the fluid supply pipe includes micro bubbles. Hereinafter, various embodiments of the internal structure of the fluid supply pipe will be described with reference to the drawings.
The pipe body 30 includes an inlet side member 31 and an outlet side member 34. Each of the inlet side member 31 and the outlet side member 34 is formed in a hollow tube shape. The inlet side member 31 has the inlet 8 having a predetermined diameter at one end and a female screw 32 at the other end which is formed by thread-cutting an inner circumferential surface for connection with the outlet side member 34. As explained with respect to
The outlet side member 34 has the outlet 9 having a predetermined diameter at one end and a male screw 35 at the other end which is formed by thread-cutting an outer circumferential surface for connection with the inlet side member 31. The diameter of the outer circumferential surface of the male screw 35 of the outlet side member 34 is the same as the inner diameter of the female screw 32 of the inlet side member 31. As explained with respect to
The above described configuration of the pipe body 30 is merely an embodiment, and the present invention is not limited to the configuration. For example, connection of the inlet side member 31 and the outlet side member 34 is not limited to the screw-joining and any method for connecting mechanical components known in the art is applicable. Further, the shapes of the inlet side member 31 and the outlet side member 34 are not limited to ones shown in
Referring to
In the present embodiment, the fluid diffusing portion 22 can be formed by machining (for example, spinning) one end of a cylindrical member in a cone shape. The fluid diffusing portion 22 diffuses the fluid flowing into the inlet side member 31 through the inlet 8 outward from the center of the pipe, i.e. radially.
The swirl generating portion 24 is formed by machining a part of the cylindrical member and includes a shaft portion having a circular cross-section and three spiral vanes, as shown in
The bubble generating portion 26 is formed by machining the downstream portion of the cylindrical member, that is, a portion of the cylindrical member remaining after forming the fluid diffusion portion 22 and the swirl generating portion 24. As shown in
In the present embodiment, the diameter of the shaft portion of the swirl generating portion 24 is smaller than the diameter of the shaft portion of the bubble generating portion 26, as shown in
Hereinafter, flow of the fluid passing through the fluid supply pipe 10 will be described. The fluid enters the inlet 8 of the fluid supply pipe 10 through the delivery pipe 6 (see
Then, the fluid passes between the plurality of rhombic protrusions formed regularly on the outer circumferential surface of the shaft portion of the bubble generating portion 26. The plurality of rhombic protrusions form a plurality of narrow flow paths. As the fluid passes through the plurality of narrow flow paths formed by the plurality of rhombic protrusions, a flip-flop phenomenon (a phenomenon occurring when the direction in which a fluid flows changes alternately and periodically) occurs to generate a large number of minute vortices. Due to the flip-flop phenomenon, the fluid passing between the plurality of protrusions of the bubble generating unit 26 in the fluid supply pipe 10 flows with directions being changed alternately in a periodic manner, which causes mixing and diffusion of the fluid. The structure of the bubble generating unit 26 is also useful when two or more fluids having different properties need to be mixed.
The internal structure 20 is configured such that the fluid flows from the upstream side (the swirl generating portion 24) having a large cross-sectional area to the downstream side (the flow paths formed between the plurality of rhombic protrusions of the bubble generating portion 26) having a small cross-sectional area in the fluid supply pipe 10. This configuration changes static pressure of the fluid as described below. The relationship between pressure, velocity, and potential energy with no external energy to a fluid is given by the Bernoulli equation.
Here, p is the pressure at a point on a streamline, p is the density of the fluid, v is the fluid flow speed at the point, g is the gravitational acceleration, h is the height of the point with respect to a reference plane, and k is a constant. The Bernoulli's law expressed as the above equation is the energy conservation law applied to fluids and explains that the sum of all the forms of energy on a streamline is constant for flowing fluids at all times. According to the Bernoulli's law, the fluid velocity is low and the static pressure is high in the upstream side having the large cross-sectional area. On the other hand, the fluid velocity is increased and the static pressure is lowered in the downstream side having the small cross-sectional area.
In the case that the fluid is a liquid, the liquid begins to vaporize when the lowered static pressure reaches the saturated vapor pressure of the liquid. Such a phenomenon in which a liquid is rapidly vaporized because the static pressure becomes lower than the saturated vapor pressure (for water, 3000 to 4000 Pa) in extremely short time at almost constant temperature is called cavitation. The internal structure of the fluid supply pipe 10 of the present invention causes the cavitation phenomenon. Due to the cavitation phenomenon, the liquid is boiled with minute bubbles of a particle size less than 100 microns existing in the liquid as nuclei or many minute bubbles are generated due to isolation of dissolved gas. That is, many micro bubbles are generated while the fluid passes the bubble generating portion 26.
In the case of water, one water molecule can form hydrogen bonds with four other water molecules, and this hydrogen bonding network is not easy to break down. Thus, the water has much higher boiling point and melting point than other liquids that do not form hydrogen bonds, and is highly viscous. Since the water having the high boiling point exhibits an excellent cooling effect, the water is frequently used as the coolant for the machine tool for performing operations such as grinding. However, the water has a problem that the size of the water molecule is large and its penetration to a machining spot and/or lubricity is not so good. Thus, conventionally, a special lubricant (i.e. cutting oil) other than the water is frequently used alone or mixed with the water. In the case of using the fluid supply pipe of the present invention, the cavitation phenomenon described above causes vaporization of the water and, as a result, the hydrogen bonding network of the water is destroyed to lower the viscosity. Further, the micro bubbles generated by the vaporization improve the penetration and lubricity. The improved penetration results in increased cooling efficiency. Therefore, according to the embodiment of the present invention, it is possible to improve machining quality (i.e. the performance of the machine tool) even if only water is used without using a special lubricant.
The fluid which has passed the bubble generating unit 26 enters the tapered portion 37 of the outlet side member 34. Since the tapered portion 37 has a flow path whose cross section is much larger than that of the bubble generating portion 26, the flip-flop phenomenon almost disappears in the tapered portion 37. The fluid flows out of the outlet 9 after passing through the tapered portion 37, and is discharged toward the grinding spot G through the nozzle 7. When the fluid is discharged through the nozzle 7, the many micro bubbles generated in the bubble generating portion 26 are exposed to atmospheric pressure. Then, the micro bubbles collide with the grinding blade 2 and the workpiece 3 and break, or explode and disappear. Vibration and shock generated during the extinction of the bubbles effectively remove sludge or chips generated at the grinding spot G. In other words, the cleaning effect around the grinding spot G is improved as the micro bubbles disappear.
By providing the fluid supply unit of the machine tool with the fluid supply pipe 10 of the embodiment of the present invention, it is possible to cool the heat generated in the grinding blade and the workpiece more effectively than by using a conventional fluid supply unit. Further, the permeability and lubricity of the fluid are improved, thereby enhancing the precision of machining. Furthermore, by effectively removing the debris of the workpiece from the machining spot, it is possible to extend the service life of the tool such as the cutting blade and reduce the cost of replacing the tool.
In addition, since the fluid diffusing portion 22, the swirl generating portion 24, and the bubble generating portion 26 of the internal structure 20 are formed by processing one member according to the present embodiment, the internal structure 20 is manufactured as a single integrated component. Therefore, it is possible to manufacture the fluid supply pipe 10 only by a simple process of inserting the internal structure 20 into the outlet side member 34 and then engaging the male screw 35 of the outlet side member 34 with the female screw 32 of the inlet side member 31.
The fluid supply pipe of the present invention can be applied to a machining liquid supply unit in various machine tools such as the grinding machine, the cutting machine, and the drilling machine. In addition, the fluid supply pipe of the present invention can be effectively used in an apparatus for mixing two or more kinds of fluids (liquid and liquid, liquid and gas, or gas and gas). For example, in the case of applying the fluid supply pipe of the present invention to a combustion engine, combustion efficiency can be improved by sufficiently mixing fuel and air. Further, in the case of applying the fluid supply pipe of the present invention to a cleaning apparatus, a cleaning effect can be further improved compared to a conventional cleaning apparatus.
Referring to
The internal structure 200 of the second embodiment is formed by machining a cylindrical member made of a metal, for example, and includes the fluid diffusing portion 22, the swirl generating portion 24, the bubble generating portion 26, and a dome-shaped guiding portion 202 from the upstream side to the downstream side. As described with respect to the first embodiment, the fluid diffusing portion 22 is formed by machining one end of the cylindrical member in the cone shape.
The internal structure 20 of the first embodiment includes the bubble generating portion 26 formed by machining the surface of the downstream portion of the cylindrical member, but its end is not specially machined. On the other hand, the internal structure 200 of the second embodiment includes the guiding portion 202 formed by machining the downstream end of the cylindrical member in a dome shape.
As shown in
When the fluid flows from the plurality of narrow flow paths formed on the surface of the bubble generating portion 26 to the tapered portion 37 of the outlet side member 34, the flow path is rapidly expanded. Thus, the flip-flop phenomenon induced by the bubble generating portion 26 is almost eliminated and a Coanda effect occurs. The Coanda effect is the phenomenon in which a fluid flowing around a curved surface is drawn to the curved surface due to a pressure drop between the fluid and the curved surface and thus the fluid flows along the curved surface. Due to the Coanda effect, the fluid is induced to flow along the surface of the guiding portion 202. The fluid guided toward the center by the dome-shaped guiding portion 202 passes through the tapered portion 37 and flows out of the outlet 9. The fluid discharged from the fluid supply pipe 100 adheres well to the cutting blade or the surface of the workpiece due to the Coanda effect amplified by the guiding portion 202 of the internal structure 200, which increases the cooling effect of the fluid.
Referring to
The internal structure 210 of the third embodiment is formed by machining a cylindrical member made of a metal, for example, and includes the fluid diffusing portion 22, the swirl generating portion 24, the bubble generating portion 26, and a cone-shaped guiding portion 212 from the upstream side to the downstream side. As described with respect to the first embodiment, the fluid diffusing portion 22 is formed by machining one end of the cylindrical member in the cone shape.
The internal structure 20 of the first embodiment includes no guiding portion in the other end, and the internal structure 200 of the second embodiment includes the guiding portion 202 formed by machining the downstream end of the cylindrical member in the dome shape. On the other hand, the internal structure 210 of the third embodiment includes the guiding portion 212 formed by machining the downstream end of the cylindrical member in a cone shape, as shown in
As shown in
After passing the bubble generating portion 26, the fluid flows toward the end of the internal structure 210. Due to the Coanda effect, the fluid is induced to flow along the surface of the guiding portion 212. The fluid guided toward the center by the guiding portion 212 passes through the tapered portion 37 and flows out of the outlet 9. As described with respect to the second embodiment, the fluid discharged from the fluid supply pipe 110 adheres well to the cutting blade or the surface of the workpiece due to the Coanda effect amplified by the guiding portion 212 of the internal structure 210, which increases the cooling effect of the fluid.
Referring to
The internal structure 220 of the fourth embodiment is formed by machining a cylindrical member made of a metal, for example, and includes a fluid diffusing portion 222, the swirl generating portion 24, and the bubble generating portion 26 from the upstream side to the downstream side. While the internal structure 20 according to the first embodiment includes the fluid diffusing portion 22 formed in the cone shape in the front end, the internal structure 220 according to the fourth embodiment includes the fluid diffusing portion 222 formed in a dome shape in the front end. The fluid diffusing portion 222 is formed by machining one end of the cylindrical member in the dome shape. The swirl generating portion 24 includes the shaft portion having the circular cross-section and the three spiral vanes. The bubble generating portion 26 includes the plurality of rhombic protrusions formed in the net shape on the outer circumferential surface of the shaft portion having the circular cross-section.
The fluid diffusing portion 222 diffuses the fluid flowing into the inlet side member 31 through the inlet 8 outward from the center of the pipe. The fluid flows toward the dome-shaped fluid diffusing portion 222, and flows along the surface of the fluid diffusing portion 222 due to the Coanda effect. Thus, it is possible to diffuse the fluid outward while minimizing loss of kinetic energy of the fluid. The fluid supply pipe 120 can improve the cooling effect and the cleaning effect of the coolant compared to a conventional pipe.
Referring to
The internal structure 230 of the fifth embodiment is formed by machining a cylindrical member made of a metal, for example, and includes the dome-shaped fluid diffusing portion 222, the swirl generating portion 24, the bubble generating portion 26, and a dome-shaped guiding portion 232 from the upstream side to the downstream side.
In
Referring to
The internal structure 240 of the sixth embodiment is formed by machining a cylindrical member made of a metal, for example, and includes the dome-shaped fluid diffusing portion 222, the swirl generating portion 24, the bubble generating portion 26, and a cone-shaped guiding portion 242 from the upstream side to the downstream side.
In
Although some embodiments of the present invention have been described above, the embodiments are for illustrative purposes only and not intended to limit the technical scope of the present invention. It will be apparent to those skilled in the art that many other possible embodiments and various modifications of the present invention may be made in light of the specification and drawings. Although a plurality of specific terms are used herein, they are used in a generic sense only for the purpose of explanation and are not used for the purpose of limiting the invention. The embodiments and modifications fall within the scope and the spirit of the invention described in this specification and within the scope of the invention as defined in the appended claims and equivalents thereof.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2016-0094458 | Jul 2016 | KR | national |
