KR101366082B1 - Friction reduction apparatus and friction reduction method using lyophilization and lyophobicity - Google Patents

Abstract

The present invention relates to a friction reducing device and a method for reducing friction using lyophilic and liquid-liquidity. It can be used like a ball to minimize friction.
The present invention, in the case of a friction reducing device, includes a first member and a second member adjacent to each other, and at least one of the opposing surfaces of the first member and the second member is lyophilic to attract and attract liquid A lyophilic region made of a material and a lyophilic region formed around the lyophilic region and capable of rejecting the liquid and forcing it into the lyophilic region are provided so that the liquid aggregates in the lyophilic region. It is characterized in that the agglomerated liquid rolls during the movement of the second member relative to the first member.

Description

FRICTION REDUCTION APPARATUS AND FRICTION REDUCTION METHOD USING LYOPHILIZATION AND LYOPHOBICITY}

The present invention relates to a friction reducing technology, and in particular, by agglomerated liquid into a fine droplet form by a surface formed by a patterned combination of a lyophilic region and a small liquid region, so that the friction can be minimized by utilizing it as a ball for rolling. It relates to a friction reducing device and a friction reducing method using a lyophilic and liquid-liquidity.

In general, when two objects are in contact with each other, or when they are in relative motion, a resistance that occurs in the tangential direction of the force that suppresses the motion at the interface is called friction. Such friction is divided into static friction and motion friction with and without relative motion, and sliding friction and rolling friction depending on the type of relative motion.

The amount of friction depends largely on the cleanliness of the surface, and the main causes of friction are as follows.

First, the actual contact occurs at some point inside the apparent contact area, causing two surfaces to adhere (adhesion occurs with plastic deformation, and the area around it is elastically deformed), and relative motion is always the layer milling of this contact area. Formation and the like.

Second, when one side moves up and down the concave or convex surface of the mating surface with movement, part of the mechanical energy becomes heat.

Third, friction occurs when the convex portion of one side is digging the other side.

This friction causes damage to parts and shortens their life, while reducing reliability. Therefore, in various parts, mechanisms, and mechanisms that require reliability, various measures have been taken to minimize the friction between objects. It is taking.

Lubrication technology using a fluid having friction reducing characteristics is widely applied to general power transmission machine elements. In the case of small mechanical systems, their small size reduces their volume, resulting in low moments of inertia, which allows them to control moving mechanical elements with low force, resulting in excellent energy efficiency. In contrast, as the ratio of the surface to volume increases, the forces acting between the surfaces can act relatively large, negatively affecting the operation of the entire system. For example, a lubricant having a viscosity in the range of 2 to 400 [cP] is considered to have a very high viscosity, considering that the absolute viscosity of air is 0.02 [cP] and the absolute viscosity of water is 1 [cP]. In energy driven microsystems, lubrication performance becomes difficult to achieve.

In particular, this traditional method of friction reduction has to be devised in a new form because it is difficult to apply in the smallest mechanical devices such as friction sensitive micro scale bearings.

Therefore, the present invention has been proposed to solve the conventional problems as described above, the object of the present invention is to aggregate the liquid in the form of fine droplets by the surface formed by the combination of the lipophilic region and the liquid-liquid region for the cloud In order to minimize the friction by using like a ball to provide a friction reducing method and a friction reducing device using a lyophilic and liquid-like pattern.

In order to achieve the above object, the friction reducing apparatus according to the technical spirit of the present invention includes a first member and a second member adjacent to each other, and at least one of the opposing surfaces of the first member and the second member. A lyophilic region made of a lyophilic material for attracting and attracting a liquid, and a lyophilic region formed around the lyophilic region, and made of a lyophilic material for discharging the liquid and forcing it into the lyophilic region, It is characterized in that the technical configuration characterized in that the liquid to agglomerate in the lyophilic region and to cause the agglomerated liquid to flow or roll in the relative movement of the second member relative to the first member.

Here, the lyophilic region may be arranged in a plurality of spaced apart form, and the remaining portion may be filled with a small liquid region.

In addition, the lyophilic region and the lyotropic region may be patterned and arranged in a cross shape with each other.

In addition, the lyophilic region may be arranged in a plurality of spaced apart form, and the small liquid region may surround the lipophilic region.

In addition, the lipophilic region and the liquid-liquid region is formed and the remaining portion may be characterized in that the friction reducing material is provided.

In addition, at least one of the facing surfaces of the first member and the second member may be characterized in that the friction reducing material is further provided.

In addition, the friction reducing material may be made of a PTFE material.

In addition, a lyotropic region or a lyophilic region may be further provided on an opposite surface of the opposing surfaces of the first member and the second member not provided with the lyophilic region and the lyotropic region.

On the other hand, in the method of manufacturing a friction reducing device according to the present invention, the entire surface of the member which should be provided with the lyophilic region and the lyophilic region among the first member and the second member is one of the lyophilic region or the lyotropic region. Forming a first step; And a second step of forming a part of the surface of the member whose entire surface is formed of one of the lyophilic region or the lyotropic region into the other of the lyophilic region or the lyotropic region. It is done.

Here, the second step may include forming a resist layer on the surface of the member whose entire surface is formed of one of the lyophilic region or the small liquid region; Forming a micropattern in the resist layer to pattern and form the other of the lyophilic region or the lyotropic region, which is not yet formed; Etching away the surface of the member along the micropattern and forming a lyophilic region in place; And removing the resist layer present on the surface of the member.

On the other hand, the friction reducing method according to the present invention, by supplying a liquid between the spaced apart of the first member and the second member adjacent to each other, the liquid supplied to agglomerated in the form of a drop, the second member to the first member Its technical feature is to reduce the friction between the first and second members as the agglomerated liquid flows or rolls in its relative motion.

Here, the liquid may be characterized in that the oil or water.

According to the present invention, a friction reducing device and a friction reducing method using a lyophilic and a liquid soluble pattern are agglomerated into fine droplets by a surface formed by a patterned combination of a lyophilic region and a liquid liquefaction, and then flowed therein. Rolling can be used to minimize friction.

In addition, the present invention can be applied to a variety of mechanisms, including cylinders and pistons of automobile engines, and in particular, can be usefully applied to ultra-small mechanisms such as micro-scale bearings.

In addition, the present invention may utilize various liquids such as water and oil.

1 is a reference perspective view for explaining a friction reducing apparatus according to the present invention applied to a micro-scale bearing.
Figure 2 is an exploded perspective view for explaining the configuration of the friction reducing apparatus according to the present invention.
3 is a reference diagram showing the agglomeration of the liquid in the friction reducing device according to the present invention.
4 and 5 are a series of reference diagrams for explaining the operation and action of the agglomerated liquid in the friction reducing device according to the present invention.
Figure 6 is a reference perspective view for explaining the configuration of the friction reducing device of the present invention according to the first modified embodiment.
Figure 7 is a reference perspective view for explaining the configuration of the friction reducing device of the present invention according to the second modified embodiment.
Figure 8 is a reference perspective view for explaining the configuration of the friction reducing device of the present invention according to the third modified embodiment.
9 is a reference perspective view for explaining the configuration of a friction reducing device of the present invention according to a fourth modified embodiment.
10 to 12 are a series of reference diagrams for explaining the configuration of the friction reducing device of the present invention according to the fifth to seventh modified embodiments.
13A to 13G are a series of cross-sectional reference views for explaining a method of forming a lyophilic region and a liquid soluble region in a method of manufacturing a friction reducing device according to the present invention.

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

1 is a reference perspective view for explaining a friction reducing apparatus according to the present invention applied to a micro-scale bearing.

As shown in the figure, the friction reducing device according to the present invention includes a bearing for the purpose of friction reduction, such as a micro scale bearing, a cylinder and a piston of an automobile engine, mechanical seals, a motor for a hard disk, etc. Applicable to the products.

The friction reducing device according to the present invention aggregates the liquid 130 into fine droplets by a surface formed by the combination of the lyophilic region 110 and the small liquid region 120, and then utilizes it as a ball for rolling. It is configured to minimize friction.

Hereinafter will be described in detail with respect to the friction reducing apparatus according to the present invention.

Figure 2 is an exploded perspective view for explaining the configuration of the friction reducing apparatus according to the present invention, Figure 3 is a reference diagram showing the agglomeration phenomenon of the liquid in the friction reducing apparatus according to the present invention, Figures 4 and 5 Is a series of reference diagrams for explaining the operation and action of agglomerated liquid in a friction reducing device.

As shown, the friction reducing device according to the present invention includes a first member 140 and a second member 150 adjacent to each other (for reference, in the above-described Figure 1 the outer ring 11 of the micro-scale bearing is Corresponding to the first member 140, the bearing shaft 12 corresponds to the second member 150), a friendly material made of a lyophilic material to attract the liquid 130 to the first member 140 to attract A liquid liquefied region 110 having a liquid liquefied region 110 and formed at the same time around the lipophilic region 110 and made of a liquid crystalline material so that the liquid 130 can be rejected and pushed into the lipophilic region 110. 120).

However, in the case of the embodiment shown in FIG. 2, the lyophilic region 110 is disposed in a plurality spaced apart form, and the remaining portion is illustrated as being filled with the small liquid region 120. However, various forms of modified embodiments are possible and will be described later.

In this case, the lyophilic region 110 may be obtained through various methods such as a method of printing a lyophilic material or material on the surface of the first member 140 or a method by chemical treatment such as nicking. In addition, in the case of the liquid liquefied region 120, the method may be obtained by printing a liquid or a liquid material on the surface of the first member 140, by a chemical treatment such as nicking, or by a mechanical treatment such as direct surface processing. have.

Thus, the liquid 130 such as water or oil may be directly supplied between the first member 140 and the second member 150 by a combination of the lyophilic region 110 and the small liquid region 120. Once the saturation of the 130 is increased to create an atmosphere, the supplied liquid 130 reacts in a direction of decreasing the surface area due to the surface tension and aggregates into fine droplets in the lyophilic region 110 as shown in FIG. 3.

As such, the liquid 130 has a tendency to reduce the surface area by deformation, while forming a resistance force indicated by the reference numeral 'F' as shown in FIG. 4 while naturally pushing the second member 150 with respect to the first member 140. Let it be. Subsequently, as shown in FIG. 5, when the second member 150 moves relative to the first member 140 as shown by an arrow, the liquid aggregated in the form of droplets 130 flows freely or rotates freely. The friction between the first member 140 and the second member 150 is allowed while not allowing contact with each other or allowing only minimal contact. At this time, the agglomerated liquid (130) droplets, unlike the fixed ball ball made of a metal material in the general bearing, its shape is fluidly changed during the rolling operation, the first member 140 and the second member 150 The relative displacement of the liver is very smooth and natural.

Meanwhile, the present invention may be modified in various forms depending on the form or arrangement of the lyophilic region 110 and the lyophilic region 120. Hereinafter, the modified embodiment as described above will be described.

Figure 6 is a reference perspective view for explaining the configuration of the friction reducing device of the present invention according to the first modified embodiment.

As shown, the present invention according to the first modified embodiment is characterized in that the lyophilic region 110 and the liquid-free region 120 is patterned in a small rectangular shape and arranged in a cross shape with each other. Such a pattern in which the lyophilic region 110 and the lyotropic region 120 are alternately patterned can be said to be the most important form in the present invention together with the embodiment before deformation.

7 is a reference perspective view for explaining the configuration of the friction reducing device of the present invention according to the second modified embodiment.

As shown, according to the second modified embodiment of the present invention, a plurality of lipophilic regions 110 are disposed in the form of being spaced apart from each other on the first member 140, and the remaining portion is PTFE (friction reducing material 160). polytetrafluoroethylene) is provided.

According to such a configuration, the lyophilic region 110 is basically provided in the first member 140 as compared with the embodiment before deformation, but the friction reducing member 160 may be provided in place of the liquefied region 120. Shows. According to such a configuration, since there is no small liquid region 120, the tendency of the liquid 130 to agglomerate in the form of droplets to the lyophilic region 110 may be partially weakened, but the parent may still exist in the lipophilic region 110. By the liquid effect, the liquid 130 may be aggregated in the form of droplets, as well as the friction reduction effect by the friction reducing material 160 may be expected to act in combination.

8 is a reference perspective view for explaining the configuration of the friction reducing device of the present invention according to the third modified embodiment.

As shown, according to the third modified embodiment of the present invention, a plurality of lyophilic regions 110 are disposed in a spaced apart form, and the lyophilic region 120 surrounds the periphery of the lipophilic region 110. In addition, the portion of the lyophilic region 110 and the non-liquid region 120 that is not formed is composed of PTFE (polytetrafluoroethylene), which is a friction reducing material 160.

However, the size or ratio of the region in which the lyophilic region 110, the liquid soluble region 120, and the friction reducing material 160 are provided may be variously adjusted.

9 is a reference perspective view for explaining the configuration of the friction reducing device of the present invention according to the fourth modified embodiment.

As shown, according to the fourth modified embodiment of the present invention, the friction reducing material 160 (polytetrafluoroethylene) is provided in place of the pattern of the microfluidic region 120 from the first modified embodiment described above. It consists of features.

Even in such a configuration, the lyophilic region 110 is basically provided in the first member 140 in comparison with the embodiment before deformation, but the friction reducing material 160 may be provided in place of the liquefied region 120. Shows that there is. According to such a configuration, since there is no small liquid region 120, the tendency of the liquid 130 to agglomerate in the form of droplets to the lyophilic region 110 may be partially weakened, but the parent may still exist in the lipophilic region 110. By the liquid effect, the liquid 130 may be aggregated in the form of droplets, as well as the friction reduction effect by the friction reducing material 160 may be expected to act in combination.

10 to 12 are a series of reference diagrams for explaining the configuration of the friction reducing apparatus of the present invention according to the fifth modified embodiment to the seventh modified embodiment.

As shown in the drawings, the present invention provides a modified embodiment having a configuration in which the liquid-soluble region 120 or the lyophilic region 110 is formed on the surface of the second member 150 or includes PTFE as the friction reducing material 160. It is possible.

Here, FIG. 10 illustrates a fifth modified embodiment in which the microfluidic region 120 is formed on the entire surface of the second member 150 facing the first member 140, whereas FIG. The sixth modified embodiment in which the lyophilic region 110 is formed on the entire surface of the two members 150 facing the first member 140 is illustrated. FIG. 12 illustrates a seventh modified embodiment having a configuration in which a PTFE reducing member 160 is provided on the entire surface of the second member 150 facing the first member 140.

Subsequently, a method for manufacturing a friction reducing device according to the present invention will be described with a focus on a method for forming the lyophilic region 110 and the small-liquid region 120 in combination with each other.

The formation of the microscale lyophilic region 110 and the microfluidic region 120 in the first member 140 according to the present invention requires very precise processing. Accordingly, in a conventional metal working method, mass production of a friction reducing device in which a lyophilic region 110 and a small liquid region 120 having a pattern form is required requires considerable cost and time.

Therefore, it is proposed to form a combination of the lyophilic and liquid-liquidity by etching, which is a method by chemical treatment, in order to lower the production cost and shorten the production time.

13A to 13F are a series of cross-sectional reference views for explaining a method of forming a lyophilic region and a liquid soluble region in the method of manufacturing a friction reducing device according to the present invention.

As shown, the method of manufacturing a friction reducing device according to the present invention uses etching, which is a chemical treatment method, to form the lyophilic region 110 and the small liquid region 120 having a fine pattern shape. This is explained in order as follows.

First, as shown in FIG. 13A, the first member 140 is prepared.

Thereafter, as shown in FIG. 13B, the entire surface of the first member 140 is processed to form the liquid liquefied region 120. Although it is difficult to pattern and partially process the surface of the first member 140, it is not difficult to process the entire surface of the first member 140 to form the liquid liquefied region 120 in the same manner as a simple mechanical treatment. Can be.

Subsequently, as shown in FIG. 13C, the resist layer 141 is formed on the surface of the first member 140 formed entirely of the small liquid region 120. The material constituting the resist layer 141 may be a variety of commonly used resists such as photoresist or thermosetting resist, and may be formed by a film form or spray coating.

Thereafter, as shown in FIG. 13D, the micro pattern 142 is formed to partially form the lyophilic region 110 in the resist layer 141. The micro pattern 142 may be formed on the resist layer 141 by various methods such as optical lithography, imprint lithography, soft etching, injection molding, and the like.

Thereafter, as shown in FIG. 13E, a portion of the surface of the first member 140 is etched by etching to remove the liquid soluble region 120 according to the micro pattern 142. In this case, the etching may be applied in various ways such as dry etching or wet etching. That is, the surface of the first member 140 may be exposed to a corrosion solution to corrode, or may be exposed to a plasma to remove the small liquid region 120.

Thereafter, as shown in FIG. 13F, the lyophilic region 110 is partially formed along the micro pattern 142. As described above, the method of forming the lyophilic region 110 may be used in various ways. The melt of the lyophilic material may be applied to the surface of the first member 140 through the micropattern 142.

Subsequently, as shown in FIG. 13G, when the resist layer 141 existing on the surface of the first member 140 is removed, the lyophilic region 110 and the liquid liquefied region ( A series of processes for forming 120 in a pattern form is completed.

Subsequently, the friction reducing method according to the present invention will be described.

Friction reduction method according to the present invention by supplying the liquid 130 between the spaced apart of the first member 140 and the second member 150 adjacent to each other, so that the supplied liquid 130 is agglomerated in a drop shape, During the relative movement of the first member 140 with respect to the first member 140, the agglomerated liquid 130 flows therein or freely rotates to friction between the first member 140 and the second member 150. The technical point is to reduce it.

Here, the specific method for the liquid 130 to be agglomerated in the form of a drop, to attract and draw the liquid 130 to the surface of the first member 140 facing the second member 150 Small liquid made of a small liquid material so as to form a lyophilic region 110 made of a liquid material, and to withdraw the liquid 130 around the lipophilic region 110 and to push it into the lipophilic region 110. To form the castle region 120. Then, the supplied liquid 130 reacts in the direction of reducing the surface area due to the surface tension to deform into a drop shape.

Here, since the method and action of constituting the lyophilic region 110 and the lyotropic region 120 have been described in detail with reference to the friction reducing apparatus according to the present invention, further description will be omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be suitably modified and applied in the same manner. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

110: lyophilic region 120: lyotropic region
130 liquid 140 first member
141: resist layer 142: micro-pattern
150: second member 160: friction reducing material

Claims (18)

A first member and a second member adjacent to each other,
At least one of the opposing surfaces of the first member and the second member is a lipophilic region made of a lyophilic material so as to attract and attract liquid, and is formed around the lipophilic region, and the liquid is rejected to It is provided with a liquid-liquid region made of a liquid-liquid material so that the liquid can be pushed out to the liquid region, so that the liquid is agglomerated in the form of droplets,
Microfluidic regions are provided on the opposite surface of the opposing surfaces of the first member and the second member that are not provided with the lyophilic region and the lyotropic region,
Friction reducing device, characterized in that the liquid agglomerated in the form of droplets to flow or roll inside the relative movement of the second member relative to the first member. The method of claim 1,
The lipophilic region is arranged in a plurality of spaced apart form, the remaining portion is friction reducing device, characterized in that filled with a small liquid region. The method of claim 1,
And the lyophilic region and the lyotropic region are patterned and intersected with each other. The method of claim 1,
The lyophilic region is disposed in a plurality of spaced apart form, the friction reducing device, characterized in that the small liquid region surrounds the periphery of the lipophilic region. delete delete delete delete Supplying the liquid between the spaced apart of the first member and the second member adjacent to each other, so that the supplied liquid is agglomerated in the form of drops,
In the relative movement of the second member with respect to the first member to reduce the friction between the first member and the second member while the liquid agglomerated in the drop form flows or rolls therein,
In order to cause the supplied liquid to agglomerate in the form of droplets, a lipophilic region made of a lipophilic material is formed to attract and attract liquid to one of the opposing surfaces of the first member and the second member, and And a liquid-liquid region is formed on the opposite surface of the first and second members on which the lyophilic region and the liquid-liquid region are not provided. delete 10. The method of claim 9,
Forming a lyotropic region made of a lyotropic material so as to displace liquid around the lyophilic region and push the liquid into the lyophilic region in the member where the lyophilic region is formed among the first member and the second member. Friction reduction method comprising a. 12. The method of claim 11,
And a plurality of the lyophilic regions are arranged in a spaced apart form, and the remaining portion is filled with the small liquid region. 12. The method of claim 11,
And the lipophilic region and the microliquid region are patterned and intersected with each other. 12. The method of claim 11,
And a plurality of the lyophilic regions are arranged in a spaced apart form, and the microfluidic region surrounds the periphery of the lipophilic region. delete delete delete 12. The method of claim 11,
And the liquid is oil or water.

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