JP2020085074A - Sealing device - Google Patents

Abstract

To return oil leaking to an atmospheric side to an in-machine side without causing the leakage of oil scatters to the atmospheric side even if a rotating shaft rotates in any of forward/reverse directions.SOLUTION: A sealing device 101 comprises a seal lip 131 for making a tip edge 133 at which an inner slope 134 at an in-machine O side and an outer slope 135 at an atmosphere A side intersect with each other tightly adhere to a rotating shaft 11. In the seal lip 131, a plurality of oil returns 141 protruding from the outer slope 135 are aligned at equal intervals along the tip edge 133. The oil returns 141 have shapes enlarged in widths toward the atmosphere A side from an apex 142 facing the tip edge 133 of the seal lip 131, for example, triangle shapes in cross sections, and constitute groups G which are aligned in one row in parallel with the tip edge 133. The groups G are arranged in a plurality of sets (G1, G2 and G3), and aligned toward a direction separating from the tip edge 133 of the seal lip 131.SELECTED DRAWING: Figure 1

Description

The present invention relates to a sealing device.

In fields such as automobiles, general machines, and industrial machines, a sealing device that seals the outer circumference of a rotary shaft with a seal lip is widely used. 2. Description of the Related Art Some sealing devices have a screw lip provided on a seal lip to exert a screw pump action to enhance the sealing performance.

Patent Document 1 describes a sealing device of this type.

As shown in FIG. 5, the sealing device described in Patent Document 1 includes a plurality of screw protrusions (4) on the slope (3) on the atmosphere A side of the seal lip (2) that seals the rotating shaft (1). Is provided. The seal lip (2) is pressed against the rotary shaft (1) by the garter spring (5). Pressed is the leading edge (6) having a triangular cross-section.

The threaded ridge (4) is formed on the slope (3) so as to be continuous with the tip edge (6). These thread ridges (4) are divided into two groups (G1, G2). The group A (G1) is inclined in one direction from the leading edge (6) and the group B (G2) is inclined in the opposite direction. These two groups (G1, G2) are arranged alternately in opposite directions along the inner circumferential direction of the seal lip (2). In FIG. 5, each group (G1, G2) includes two screw protrusions (4), but Patent Document 1 shows some embodiments including a larger number.

The screw ridge (4) plays a role of returning the oil leaked to the atmosphere A side beyond the tip edge (6) of the seal lip (2) to the in-machine O side when the rotating shaft (1) rotates. .. The thread ridge (4) is divided into an A group (G1) and a B group (G2) for the purpose of adapting to the rotating shaft (1) that rotates in both forward and reverse directions.

In FIG. 6(A), the behavior of the oil when the rotating shaft (1) is rotating in the clockwise direction CW is indicated by arrows. At this time, the screw ridges (4) belonging to the group A (G1) are in the forward direction with respect to the rotation shaft (1). When the screw ridge (4) is in the forward direction with respect to the rotating shaft (1), the screw ridge (4) exerts a screw pump action to return the oil leaking to the atmosphere A side to the in-machine O side. Therefore, when the rotary shaft (1) is rotating in the clockwise direction CW, the screw ridges (4) of the group A (G1) return the leaked oil to the in-machine O side.

In FIG. 6B, the behavior of the oil when the rotating shaft (1) is rotating in the counterclockwise direction AW is indicated by an arrow. At this time, the screw ridges (4) belonging to the group B (G2) are in the forward direction with respect to the rotating shaft (1). Therefore, when the rotating shaft (1) is rotating in the counterclockwise direction AW, the screw ridges (4) of the group B (G2) return the leaked oil to the in-machine O side.

Japanese Patent Laid-Open No. 01-112274

In the sealing device as described in Patent Document 1, the screw ridges (4) belonging to the two groups (G1, G2) are alternately arranged in the inner circumferential direction of the seal lip (2) in opposite directions. .. In such an arrangement, when the screw ridges (4) of one group exert a screw pump action and return oil from the atmosphere A side to the in-machine O side, the screw ridges (4) of the other group are It has a screw pump action of scraping oil from the tip edge (6) of the seal lip (2). As a result, oil may leak from the threaded ridges (4) of the group that are opposite to the direction of rotation of the rotating shaft (1). Improvement is required.

An object of the present invention is to return the oil leaked to the atmosphere side to the inside of the machine without causing leakage of oil to the atmosphere side regardless of whether the rotating shaft rotates in the forward or reverse direction.

The sealing device of the present invention is configured such that the tip edge where the slope on the inside of the machine and the slope on the atmosphere side intersect is brought into close contact with the rotating shaft, and a seal lip that seals the inside of the machine and the atmosphere side, and is arranged along the tip edge. And a plurality of oil returns protruding from the slope on the atmosphere side in a shape in which the width increases from the top facing the tip edge toward the atmosphere.

According to the present invention, regardless of whether the rotating shaft rotates in the forward or reverse direction, the oil leaked to the atmosphere side can be returned to the inside of the machine without causing oil leakage to the atmosphere side.

FIG. 1 is a horizontal cross-sectional view showing a sealing device cut along the axis of a rotary shaft to be sealed as an embodiment. The front view of the oil return drawn by the one-point perspective drawing method. (A) is a schematic diagram showing the behavior of oil when the rotary shaft is rotating clockwise, and (B) is the arrow showing behavior of oil when the rotary shaft is rotating counterclockwise. Pattern diagram. FIG. 3 is a horizontal cross-sectional view of the sealing device showing a state in which the leading edge of the seal lip is worn. FIG. 3 is a horizontal cross-sectional view of the sealing device described in the background art, taken along the axis of the rotary shaft to be sealed. (A) is a schematic diagram showing the behavior of oil when the rotary shaft is rotating clockwise, and (B) is the arrow showing behavior of oil when the rotary shaft is rotating counterclockwise. Pattern diagram.

An embodiment will be described with reference to FIGS. 1 to 4. The present embodiment is an application example to a sealing device 101 that seals a rotating shaft 11 that rotates in both forward and reverse directions. The sealing device 101 seals the inside O side for sealing oil (not shown) and the atmosphere A side.

The sealing device 101 is formed by vulcanizing and adhering a rubber-like elastic body 112 to a metal ring 111. The rubber-like elastic body 112 integrally forms the seal lip 131, the dust lip 151, and the fixed seal 171. As an example, the rubber-like elastic body 112 is integrally formed into a shape including a seal lip 131, a dust lip 151, and a fixed seal 171 by inserting a metal ring 111 into a rubber material which is a raw material of the rubber-like elastic body 112.

The metal ring 111 has an end of a ring-shaped base 113 bent at an inner peripheral side at a right angle, and a flange 114 is formed at the bent portion. The metal ring 111 is, for example, a pressed product. The base 113 and the flange 114 are integrally formed by press working.

The flange 114 has an inner hole 115 provided coaxially with the metal ring 111. The inner hole 115 has a larger diameter than the rotary shaft 11 and surrounds the rotary shaft 11.

The sealing device 101 is fitted in a mounting hole of a housing (not shown) and is fixedly attached to the housing. The base 113 of the metal ring 111 is fitted in the mounting hole. A fixed seal 171 is adhesively fixed to the outer peripheral surface of the base 113. Since the fixed seal 171 has a larger diameter than the mounting hole of the housing, it is elastically deformed when mounted in the mounting hole, and the close contact force to the mounting hole is increased.

The seal lip 131 has a tip portion 132 extending obliquely toward the in-machine O side, starting from the vicinity of the tip of a flange 114 provided on the metal ring 111. The tip end portion 132 of the seal lip 131 has a triangular cross-section with a tip end edge 133 at the apex where an inner slope surface 134 that is a slope surface on the O side in the machine and an outer slope surface 135 that is a slope surface on the atmosphere A side intersect. The leading edge 133 is in close contact with the rotating shaft 11 to define a space on the O side in the machine and a space on the atmosphere A side, and seal the two spaces.

The tip portion 132 of the rubber-like elastic body 112 that forms the seal lip 131 is provided with a mounting groove 136 having a semicircular cross section at a position that contacts the back side of the tip edge 133. A garter spring 137 in which both ends of the coil spring are annularly connected is fitted into the mounting groove 136. The tightening force of the garter spring 137 increases the close contact force of the tip edge 133 of the seal lip 131 with respect to the rotating shaft 11.

The seal lip 131 has a plurality of oil returns 141 on the outer slope 135.

As shown in FIGS. 1 and 2, the oil return 141 has a triangular shape protruding from the outer slope 135. The triangular shape is an isosceles triangular shape in which the top portion 142 faces the tip edge 133 of the seal lip 131 and the width increases from the top portion 142 toward the atmosphere A side. Therefore, the right side 143R and the left side 143L intersecting at the apex 142 have the same angle with the center line C of the isosceles triangle. The center line C of the isosceles triangle is a line that passes through the apex 142 along a direction (axial direction of the rotating shaft 11) orthogonal to the leading edge 133. The bottom side 144 of the oil return 141 is parallel to the leading edge 133.

The oil return 141 has a three-dimensional shape protruding from the outer slope 135, as described above. The three-dimensional shape of the oil return 141 is a shape in which the top 142 is positioned in the same plane as the outer slope 135 and the height gradually increases from the top 142 toward the bottom 144.

FIG. 2 depicts the oil return 141 in a single point perspective view. In FIG. 2, the oil return 141 seems to rise from the bottom portion located in the same plane as the outer slope 135 so as to reduce the area, but this is due to the one-point perspective drawing method. The right side 143R, the left side 143L, and the bottom side 144 of the oil return 141 all stand vertically from the outer slope 135.

The seal lip 131 includes a plurality of groups G in which a plurality of oil returns 141 are arranged in a line in parallel with the leading edge 133. The plurality of groups G are arranged in a direction orthogonal to the leading edge 133. In this embodiment, three groups G1 to G3 are provided. Within each group G, a plurality of oil returns 141 are arranged at equal intervals. The arrangement interval at this time is common to the individual groups G.

The oil return 141 belonging to the group G1 has the top portion 142 connected to the tip edge 133 of the seal lip 131.

The oil return 141 belonging to the group G2 is arranged at a position farther from the tip edge 133 of the seal lip 131 than the group G1. The oil returns 141 belonging to these two groups G1 and G2 are arranged alternately along the tip edge 133 of the seal lip 131. More specifically, the oil return 141 belonging to the group G2 is positioned at the center of two adjacent oil returns 141 belonging to the group G1.

As described above, the oil return 141 has a gradient in which the height gradually increases from the top 142 toward the bottom 144. The oil return 141 belonging to the group G2 has a larger gradient than the oil return 141 belonging to the group G1. Therefore, when comparing the bottoms 144 having the highest height, the oil return 141 belonging to the group G2 is higher than the oil return 141 belonging to the group G1.

The oil return 141 belonging to the group G3 is arranged at a position farther from the tip edge 133 of the seal lip 131 than the groups G1 and G2. In the direction along the leading edge 133, the oil return 141 belonging to the group G3 is arranged at the same position as the oil return 141 belonging to the group G1. Therefore, similarly to the oil returns 141 belonging to the group G1, the oil returns 141 belonging to the group G2 are arranged alternately in the direction along the tip edge 133 of the seal lip 131.

The oil return 141 belonging to the group G3 has a larger gradient than the oil return 141 belonging to the groups G1 and G2. Therefore, when comparing the bottoms 144 having the highest height, the oil return 141 belonging to the group G3 is higher than the oil return 141 belonging to the groups G1 and G2.

For example, the oil return 141 described above is integrally formed with the outer slope 135 by the mold when integrally molding the rubber elastic body 112 in which the metal ring 111 is inserted into the mold.

The dust lip 151 has a tip portion 152 obliquely extended toward the atmosphere A side, starting from the vicinity of the tip of a flange 114 provided on the metal ring 111. A tip portion 152 of the dust lip 151 extending toward the atmosphere A faces the rotating shaft 11 with a gap. The gap is set to a size that can prevent foreign matter such as sludge and dust from entering from the atmosphere A side by the air flow generated by the rotation of the rotating shaft 11. Therefore, the dust lip 151 constitutes a labyrinth seal.

The operation will be described.

The seal lip 131 brings the leading edge 133 into close contact with the rotating shaft 11 and seals the in-machine O side and the atmosphere A side regardless of the rotating or non-rotating state of the rotating shaft 11.

When the rotating shaft 11 rotates, oil may leak from the in-machine O side to the atmosphere A side. At this time, the oil return 141 exerts a pumping action by the right side 143R or the left side 143L thereof to return the oil to the in-machine O side.

FIG. 3A shows a state where the rotating shaft 11 is rotating in the clockwise direction CW. At this time, the left side 143L of the oil return 141 is in the forward direction with respect to the rotating shaft 11. Each side 143R, 143L of the oil return 141 exerts a pumping action so as to return the oil leaking to the atmosphere A side to the in-machine O side when it goes in the forward direction with respect to the rotating shaft 11. Therefore, when the rotary shaft 11 is rotating in the clockwise direction CW, the left side 143L of the oil return 141 returns the leaked oil to the in-machine O.

FIG. 3B shows a state where the rotating shaft 11 is rotating in the counterclockwise direction AW. At this time, the right side 143R of the oil return 141 is in the forward direction with respect to the rotating shaft 11. Therefore, when the rotary shaft 11 is rotating in the counterclockwise direction AW, the right side 143R of the oil return 141 returns the leaked oil to the in-machine O.

As shown in FIGS. 3A and 3B, in each of the sides 143R and 143L of the oil return 141, even if one side 143R or 143L is in the forward direction with respect to the rotating shaft 11 and exerts a pumping action, it is opposite. The side 143L or 143R on the side does not exert a pumping action. Therefore, the oil return 141 does not have a function of returning the leaked oil to the in-machine O side, but leaking the oil from the tip end edge 133 of the seal lip 131 to the atmosphere A side. Therefore, no matter whether the rotating shaft 11 rotates in the forward or reverse direction, the oil leaked to the atmosphere A side can be returned to the in-machine O side without causing oil leakage to the atmosphere A side.

The rotary shaft 11 of the present embodiment also exhibits the following operational effects.

The top portion 142 of the oil return 141 belonging to the group G1 is continuous with the tip edge 133 of the seal lip 131. Therefore, the oil leaked to the atmosphere A side can be reliably returned to the in-machine O side.

The protruding height of the oil return 141 increases as it goes from the top 142 toward the atmosphere. Therefore, as illustrated in FIG. 4, even if the tip edge 133 of the seal lip 131 is worn, the oil return 141 can be brought into contact with the rotating shaft 11 in a stable state, and the oil leaked to the atmosphere A side can be removed from the inside of the machine. It can be surely returned to the O side.

The oil returns are evenly spaced. Therefore, the oil return 141 can be evenly contacted in the axial direction of the rotary shaft 11, and the oil leaking to the atmosphere A side can be reliably returned to the in-machine O side.

A plurality of groups G in which a plurality of oil returns 141 are arranged in a line in parallel with the leading edge 133 of the seal lip 131 are provided, and the plurality of groups G (G1, G2, G3) are in a direction orthogonal to the leading edge 133. Are arranged for. Therefore, as illustrated in FIG. 4, even if the leading edge 133 of the seal lip 131 is worn and the oil return 141 disappears from the side close to the leading edge 133, the remaining oil return 141 of the group G can function. .. At this time, since the protruding height of the oil return 141 is higher in the row (group G) farther from the tip edge 133, the oil return 141 can be brought into contact with the rotating shaft 11 in a stable state and leaks to the atmosphere A side. The oil can be reliably returned to the O side in the machine.

Moreover, the oil returns 141 are arranged alternately in each row (each group G) in the direction along the leading edge 133 of the seal lip 131, and the arrangement positions of the oil returns 141 in adjacent rows are orthogonal to the leading edge 133. Overlapping. Therefore, the oil return 141 of the second row group G2 can be brought into contact with the rotating shaft 11 before the first row group G1 completely disappears, and the third row before the second row group G2 completely disappears. The oil return 141 of the eye group G3 can be brought into contact with the rotating shaft 11. As a result, the oil return 141 can be brought into contact with the rotating shaft 11 without interruption, and the oil leaking to the atmosphere A side can be reliably returned to the in-machine O side.

Various modifications and changes are allowed in implementation.

For example, referring to the shape of the oil return 141, the oil return 141 may have a shape in which the width increases from the top portion 142 facing the tip edge 133 of the seal lip 131 toward the atmosphere A side.

Therefore, the top 142 of the oil return 141 does not have to be continuous with the tip edge 133 of the seal lip 131.

The shape of the oil return 141 is not limited to the isosceles triangle. For example, the angle formed by the right side 143R and the angle formed by the left side 143L with respect to the center line C may be different. Even if it is a triangle, it is not essential, and the oil return 141 of various shapes such as another polygon such as a hexagon or an octagon, or a shape having a curved surface partially is allowed.

In the present embodiment, the shape of the oil return 141 that increases as it goes from the top 142 toward the atmosphere A side is shown, but this is not essential. An oil return 141 of the same height from the top 142 to the bottom 144 is also acceptable.

Various modifications and changes can be made to the arrangement of the oil return 141.

For example, the oil returns 141 do not necessarily have to be arranged at equal intervals.

In the present embodiment, an example in which the oil return 141 is divided into a plurality of groups G (G1, G2, G3) and arranged in the direction orthogonal to the tip edge 133 of the seal lip 131 has been introduced. Also, the arrangement for each group G is not essential. The oil return 141 may be provided in only one row, and at this time, it is not essential to arrange the tops 142 in one row.

Alternatively, even when the oil return 141 is divided into a plurality of groups G (G1, G2, G3) and arranged in a direction orthogonal to the leading edge 133 of the seal lip 131, the row farther from the leading edge 133 becomes It is not essential to increase the protruding height of the oil return 141. The protrusion height of the oil return 141 may be common to each row. It is not always essential that the oil returns 141 of the individual groups G are staggered in the direction along the leading edge 133 for each row.

In other implementations, any modifications and changes are allowed.

11 rotary shaft 101 sealing device 111 metal ring 112 rubber-like elastic body 113 base portion 114 flange 115 inner hole 131 seal lip 132 tip portion 133 tip edge 134 inner slope (slope inside the machine)
135 Outer slope (atmosphere side slope)
136 Mounting groove 137 Garter spring 141 Oil return 142 Top 143R Right side 143L Left side 144 Bottom 151 dust lip 152 Tip part A Atmosphere G (G1, G2, G3) Group O Inside the aircraft

Claims (7)

A seal lip that seals the inside of the machine and the atmosphere side by bringing the tip edge where the inside slope and the atmosphere side slope intersect each other into close contact with the rotating shaft.
A plurality of oil returns arranged along the tip edge and protruding from the slope on the atmosphere side in a shape in which the width increases from the top facing the tip edge toward the atmosphere side,
A sealing device comprising. The top of the oil return is continuous with the tip edge,
The sealing device according to claim 1. The protruding height of the oil return increases from the top toward the atmosphere side,
The sealing device according to claim 1. The oil returns are arranged at equal intervals,
The sealing device according to claim 1. A plurality of groups in which the plurality of oil returns are arranged in a line parallel to the leading edge,
The groups of the plurality of sets are arranged in a direction orthogonal to the leading edge,
The sealing device according to any one of claims 1 to 4. The protruding height of the oil return is higher as the row is farther from the tip edge.
The sealing device according to claim 5. The oil return is arranged in a staggered manner in a direction along the leading edge for each row,
The arrangement positions of the oil returns in adjacent rows overlap in a direction orthogonal to the leading edge,
The sealing device according to claim 5 or 6.

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