JP2019015350A - Sealing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sealing device capable of preventing lubricating oil from leaking from the inside of a machine to the outside of a machine even when the rotation speed of the rotating shaft is rotating at a high speed of a predetermined value or more. SOLUTION: A slinger having a cylindrical portion mounted on an outer peripheral surface of a rotating shaft rotating with respect to a housing, and an annular flange portion extending in a direction away from the axis of the rotating shaft from an inner end portion of the cylindrical portion. And a seal portion that is mounted on the housing and has a main lip that slidably contacts the outer surface of the flange portion to seal the lubricating oil to the inside of the housing, and contacts the main lip on the outer surface of the flange portion. A threaded portion is formed in the portion where the lubricating oil is discharged back to the inside of the housing during rotation, and the relative contact angle when the outer surface of the flange portion and the main lip come into contact is small. The flange portion is curved so as to be. [Selection diagram] Fig. 1

Description

  The present invention relates to a sealing device, and is used, for example, as a seal for rotation in the field of automobiles, and in particular, as a seal for an engine in which lubricating oil is present in the machine.

  2. Description of the Related Art Conventionally, a sealing device used as an engine seal is mounted, for example, between an engine housing and a crankshaft in order to prevent the lubricating oil sealed in the machine from leaking out of the machine. As this sealing device, a screw portion provided on the flange portion of the slinger exhibits a pumping action when the crankshaft rotates and seals lubricating oil in the machine (see, for example, Patent Document 1).

  As shown in FIG. 10, such a sealing device 100 is attached to the outer peripheral surface of a crankshaft 201 as a rotation shaft and attached to the inner peripheral surface of the housing 202 and the slinger 101 that rotates together with the crankshaft 201. The seal part 102 is provided.

  The slinger 101 includes a cylindrical portion 105 that is mounted on the outer peripheral surface of the crankshaft 201, and a flange portion 103 that extends from the end of the cylindrical portion 105 on the in-machine A side to the outer peripheral side. The flange portion 103 has a hollow disc-like bulging portion 103e that swells toward the machine A side, and a hollow disc shape that expands toward the outer circumference side after being bent from the outer peripheral side end of the bulging portion 103e to the outside B side. Disk portion 103f.

  In the sealing device 100, the main lip 111 of the seal portion 102 is slidably in close contact with the outer surface 103 a that is the end surface on the outer side B in the axial direction of the disk portion 103 f of the flange portion 103, so The lubricating oil (oil) existing in A is prevented from leaking outside B.

  In the sealing device 100, a plurality of screw grooves 104 are provided on the outer surface 103a of the disk portion 103f of the flange portion 103 with which the main lip 111 is slidably in close contact.

  The screw grooves 104 are arranged independently at regular intervals, and are four equal spiral grooves that are rotated clockwise from the inner diameter side to the outer diameter side corresponding to the rotation direction of the crankshaft 201. The start point and end point of the groove are different. The thread groove 104 is formed on the outer surface 103 a of the disk portion 103 f of the flange portion 103 in the slinger 101, and the lip tip 111 a of the main lip 111 of the seal portion 102 is in contact with the four screw grooves 104. .

  Therefore, in the sealing device 100, even when the lubricating oil oozes out into the space S surrounded between the slinger 101 and the seal member 110 of the seal portion 102, the flange portion 103 when the slinger 101 rotates together with the crankshaft 201. The swinging action of returning the lubricating oil from the space S to the in-machine A side by the centrifugal force, and the action of returning the lubricating oil from the space S to the in-machine A side due to the influence of the thread groove 104 when the disk portion 103f of the flange portion 103 rotates. (Hereinafter, this is also referred to as “screw action”). Note that the effect of returning the lubricating oil from the space S to the in-machine A side by both the swing-off action and the screw action is referred to as a pumping effect.

JP 2014-1229837 A

  In the sealing device 100 described above, if the rotational speed of the crankshaft 201 is a diesel engine that rotates at a low speed of, for example, about 5000 rpm (revolution per minute) or less, the flange 103 of the slinger 101 and the lip tip 111a of the main lip 111 The lubricating oil does not ooze out from the gap into the space S.

  However, when the sealing device 100 is applied to, for example, a gasoline engine in which the crankshaft 201 rotates at a high speed of about 6000 rpm or more, the lubricant oil enters the space S from the gap between the flange portion 103 of the slinger 101 and the lip tip 111a of the main lip 111. There was a risk that the oil would ooze out and the lubricating oil would be stored in the space S.

  The present invention has been made in view of the above problems, and the purpose of the present invention is to provide the lubricating oil inside the machine to the flange portion of the slinger and the main lip even when the rotational speed of the rotary shaft is higher than a predetermined value. It is an object of the present invention to provide a sealing device that can prevent leakage from the gap and finally leakage.

  In order to achieve the above object, in the present invention, a cylindrical portion mounted on the outer peripheral surface of a rotating shaft that rotates with respect to a housing, and an axis of the rotating shaft that is separated from an inner end of the cylindrical portion. A slinger having an annular flange portion extending in a direction, and a main lip that is attached to the housing and that slidably contacts the outer surface of the flange portion of the slinger to seal lubricating oil to the inside of the housing of the housing. A groove for demonstrating a discharge action for returning the lubricating oil to the inside of the housing at the time of rotation in a portion that contacts the main lip on the outer surface of the flange portion, and The relative contact angle between the flange portion and the main lip when the outer surface of the flange portion and the main lip come into contact with each other is small. The flange portion Kunar so is characterized by being curved.

  In the present invention, the flange portion is curved concavely with respect to the main lip, and the curved outer surface of the flange portion is in contact with the lip tip of the main lip.

  In this invention, the said flange part is curving convexly with respect to the said main lip, The outer surface of the curved said flange part and the lip front-end | tip of the said main lip contact, It is characterized by the above-mentioned.

  In the present invention, the flange portion has an arch shape that bulges in a convex shape from the inner end portion of the cylindrical portion toward an outer peripheral side separated from the axis of the rotation shaft. To do.

  According to the present invention, even when the rotational speed of the rotary shaft is higher than a predetermined value, the lubricating oil inside the machine oozes out from the gap between the flange portion of the slinger and the main lip and eventually leaks. It is possible to realize a sealing device that can prevent this.

It is sectional drawing which shows the mounting state of the oil seal which concerns on the 1st Embodiment of this invention. It is an expanded sectional view showing the composition of the simple substance of the oil seal concerning a 1st embodiment of the present invention. It is a top view which shows the structure of the slinger which concerns on the 1st Embodiment of this invention. It is a top view which shows the other structural example of the slinger which concerns on the 1st Embodiment of this invention. It is sectional drawing with which it uses for description of the storage amount of the lubricating oil according to the contact angle of the conventional main lip and the flange part of a slinger. In the oil seal concerning the 1st embodiment of the present invention, it is a top view used for explanation of the amount of storage of lubricating oil according to the contact angle of the main lip and the flange part of a slinger. It is a graph which shows the relationship between the contact angle of the oil seal and slinger which concern on the 1st Embodiment of this invention, and the air suction amount of the air containing lubricating oil. It is an expanded sectional view showing the composition of the simple substance of the oil seal concerning a 2nd embodiment of the present invention. It is an expanded sectional view showing the composition of the simple substance of the oil seal concerning a 3rd embodiment of the present invention. It is an expanded sectional view which shows the structure of the conventional sealing device (oil seal).

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

<First Embodiment>
FIG. 1 is a cross-sectional view showing an installed state of an oil seal according to the first embodiment of the present invention. FIG. 2 is an enlarged cross-sectional view showing a single structure of the oil seal according to the first embodiment of the present invention. FIG. 3 is a plan view showing the configuration of the slinger according to the first embodiment of the present invention. FIG. 4 is a plan view showing another configuration example of the slinger according to the first embodiment of the present invention. FIG. 5 is a cross-sectional view for explaining the amount of lubricating oil stored according to the contact angle between the conventional main lip and the flange portion of the slinger. FIG. 6 is a plan view for explaining the amount of lubricating oil stored according to the contact angle between the main lip and the flange portion of the slinger in the oil seal according to the first embodiment of the present invention.

  Hereinafter, for convenience of explanation, the direction of the arrow a (see FIG. 1) in the direction of the axis x is the outside, and the direction of the arrow b (see FIG. 1) in the direction of the axis x is the inside. More specifically, the outside is the outside B side away from the engine, and the inside is the inside direction of the engine and the inside A side. Further, in a direction perpendicular to the axis x (hereinafter also referred to as “radial direction”), the direction away from the axis x (the direction of arrow c in FIG. 1) is the outer peripheral side, and the direction approaching the axis x (the arrow d in FIG. 1). Direction) is the inner circumference.

<Configuration of oil seal>
As shown in FIGS. 1 and 2, an oil seal 1 as a sealing device according to an embodiment of the present invention is used as a seal for an automobile engine (particularly a gasoline engine) in which lubricating oil is present in an in-machine A. This prevents the lubricant A from leaking out of the machine B and prevents foreign matter such as dust from entering the machine A from the machine B.

  The oil seal 1 includes a seal portion 10 that is mounted on an inner peripheral surface 202 a that is a surface on the inner peripheral side (in the direction of arrow d) of an engine housing (hereinafter also referred to simply as “housing”) 202, and the housing 202. And a slinger 130 mounted on an outer peripheral surface 201a which is a surface on the outer peripheral side (in the direction of arrow c) of the crankshaft 201 as a rotating shaft that rotates relative to each other.

  The seal portion 10 includes a reinforcing ring 20 and an elastic body portion 21 formed integrally with the reinforcing ring 20. The reinforcing ring 20 is made of an annular metal material centered on the axis x. Examples of the metal material of the reinforcing ring 20 include stainless steel and SPCC (cold rolled steel). On the other hand, examples of the elastic body of the elastic body portion 21 include various rubber materials. Examples of the various rubber materials include synthetic rubbers such as nitrile rubber (NBR), hydrogenated nitrile rubber (H-NBR), acrylic rubber (ACM), and fluorine rubber (FKM).

  The reinforcing ring 20 is manufactured by, for example, pressing or forging, and the elastic body portion 21 is formed by cross-linking (vulcanization) molding using a molding die. At the time of this cross-linking molding, the reinforcing ring 20 is disposed in the mold, the elastic body portion 21 is bonded to the reinforcing ring 20 by cross-linking (vulcanization) bonding, and the elastic body portion 21 is integrated with the reinforcing ring 20. Molded.

  The reinforcing ring 20 has, for example, a substantially L-shaped cross section, and includes a cylindrical part 20a, an outer peripheral side disk part 20b, a tapered part 20c, and an inner peripheral side disk part 20d. The disk part 20b, the taper part 20c, and the inner peripheral disk part 20d are all formed integrally.

  In this case, the cylindrical portion 20a has a curved shape that bulges in a convex shape toward the outer peripheral side (arrow c direction). Moreover, the outer peripheral side disk part 20b, the taper part 20c, and the inner peripheral side disk part 20d form a substantially S-shaped flange part as a whole.

  The cylindrical portion 20 a is a cylindrical portion that extends substantially parallel to the axis x, and is fitted into the inner peripheral surface 202 a of the housing 202. The outer peripheral disk portion 20b is a hollow disk-shaped portion that extends in a direction substantially perpendicular to the axis x, that is, from the outer end (arrow a direction) of the cylindrical portion 20a toward the inner peripheral side (arrow d direction). . The taper portion 20c is a hollow disc-shaped portion that extends obliquely further from the end portion on the inner peripheral side (arrow d direction) of the outer peripheral disc portion 20b toward the inner peripheral side (arrow d direction) and the inner side (arrow b direction). It is. The inner circumferential disk portion 20d is a hollow disk-shaped portion that further expands from the end on the inner circumferential side (arrow d direction) of the tapered portion 20c toward the inner circumferential side (arrow d direction).

  In this case, the cylindrical portion 20a of the reinforcing ring 20 has a curved shape that bulges toward the outer peripheral side (in the direction of arrow c), but is not limited thereto, and is along the axis x. It may be a cylindrical portion that extends straight. Further, the reinforcing ring 20 is formed in a substantially S shape by the outer peripheral side disk part 20b, the tapered part 20c, and the inner peripheral side disk part 20d, but the outer peripheral side disk part 20b, the tapered part 20c, and The inner circumferential disk part 20d may extend straight in a direction substantially perpendicular to the axis x.

  The elastic body portion 21 is integrally attached to the reinforcing ring 20, and the reinforcing ring 20 is arranged on the outer side (arrow a direction), on the outer peripheral side (arrow c direction), and on the inner peripheral side (arrow d direction). Is formed integrally with the reinforcing ring 20.

  The elastic body portion 21 covers the lip covering portion 21a that covers a part of the outer peripheral side (arrow c direction) of the cylindrical portion 20a of the reinforcing ring 20 and the outer peripheral disk portion 20b of the reinforcing ring 20 from the outer side (arrow a direction). A lip covering portion 21b, a lip covering portion 21c that covers the tapered portion 20c of the reinforcing ring 20, a lip covering portion 21d that covers the inner peripheral side disk portion 20d of the reinforcing ring 20 from the outside (in the direction of arrow a), and a lip covering portion 21d. And a main lip 22, a dust lip 23, and an intermediate lip 24 that are integrally formed with the lip waist 21e.

  The lip waist part 21e of the elastic body part 21 is a part located in the vicinity of the inner peripheral side (arrow d direction) end part of the inner peripheral side disk part 20d of the reinforcing ring 20, and includes a main lip 22, a dust lip 23, and , The base of the intermediate lip 24.

  The main lip 22 of the elastic body portion 21 is centered on an axis line x that extends obliquely from the inner (arrow b direction) end of the lip waist portion 21e toward the inner side (arrow b direction) and the outer peripheral side (arrow c direction). The diameter of the lip portion is increased from the inner peripheral side (arrow d direction) to the outer peripheral side (arrow c direction).

  The main lip 22 is formed such that the base portion 22r extending from the inner end (in the direction of arrow b) of the lip waist portion 21e is thinner than the main body portion 22b. This is because in the elastic body portion 21, the main lip 22 is easily bent from the root starting from the root portion 22r. Such a type of main lip 22 may be referred to as a thin lip in this specification.

  The dust strip 23 of the elastic body portion 21 extends from the end portion on the inner peripheral side (arrow d direction) of the lip waist portion 21e obliquely toward the outer side (arrow a direction) and the inner peripheral side (arrow d direction). Is a ring-shaped lip portion centering on the outer diameter side (arrow c direction), and the diameter is increased from the inner circumference side (arrow d direction). The extending direction of the dust lip 23 is substantially opposite to the extending direction of the main lip 22.

  The intermediate lip 24 of the elastic body portion 21 is located on the inner peripheral side (arrow d direction) of the main lip 22 in the lip waist portion 21e and on the inner side (arrow b direction) of the dust lip 23, and the lip waist portion 21e is an annular lip portion centered on the axis line x that extends slightly from the inner peripheral side (arrow d direction) end toward the inside (arrow b direction). The intermediate lip 24 has a short lip length, and the lip tip does not come into contact with the slinger 30.

  The slinger 130 is, for example, a metal plate member that rotates along with the rotation of the crankshaft 201 in a state where the slinger 130 is attached to the outer peripheral surface 201a of the crankshaft 201, and includes a cylindrical portion 131 and a curved flange that is curved. Part 133 is provided. The slinger 130 can be formed, for example, by bending a plate-like member.

  The cylindrical portion 131 of the slinger 130 is a cylindrical portion that extends substantially parallel to the axis x, and is mounted by being press-fitted and fixed to the outer peripheral surface 201 a of the crankshaft 201 that rotates with respect to the housing 202. The cylindrical portion 131 has a shorter length in the direction of the axis x than the cylindrical portion 105 of the conventional slinger 101. The cylindrical portion 131 of the slinger 130 has an outer peripheral surface 131a which is a surface on the outer peripheral side (arrow c direction), and the lip end of the dust lip 23 of the elastic body portion 21 is slidable with respect to the outer peripheral surface 131a. To touch. This prevents foreign matter such as dust from entering the inside A from the outside B.

  The curved flange portion 133 extends from the inner end (in the direction of arrow b) of the cylindrical portion 131 while curving in a curved manner in a direction away from the axis x of the crankshaft 201, and is an annular flange centering on the axis x. It is a portion and is formed in a concave shape with respect to the elastic body portion 21. The curved flange portion 133 includes a small radius flange portion 133m having a small curvature radius and a large radius flange portion 133s having a curvature radius larger than that of the small radius flange portion 133m. The small-radius flange portion 133m and the large-radius flange portion 133s are integrated so that the outer surface 133a that is the surface on the outer side (in the direction of arrow a) is smoothly connected.

  The curved flange portion 133 has a small radius flange portion 133m that is curved from the inner end (arrow b direction) of the cylindrical portion 131 having a short length along the axis x direction. When facing the lip 24 in the direction of the axis x, the distance between the lip tip of the intermediate lip 24 and the outer side surface 133a of the curved flange portion 133 (small radius flange portion 133m) is narrower than in the prior art.

  The large radius flange portion 133s has a very large radius of curvature compared to the small radius flange portion 133m, and has a curved portion so as not to approach the main lip 22 toward the outer peripheral side (in the direction of arrow c). It is a disk-shaped part centering on the axis line x with a gentle curve.

  That is, in the large-radius flange portion 133s, the outer surface 133a, which is the outer end surface on the outside B side (in the direction of arrow a), does not approach the main lip 22 toward the front end on the outer peripheral side (in the direction of arrow c). The curve is slightly bent. For this reason, the relative contact angle θ1 (FIG. 2) between the lip tip of the main lip 22 and the outer surface 133a of the large radius flange portion 133s is set to a relative value between the cylindrical portion 105 of the conventional slinger 101 and the main lip 111. It is smaller than the contact angle θ0 (FIG. 5).

  In addition, in the edge part area | region of the outer peripheral side (arrow c direction) of the outer side surface 133a of the large radius flange part 133s, it is used in order to discharge | emit the lubricating oil G1 (FIG. 5) which entered the space S to the exterior A 4 A spiral groove-like screw groove 36 is provided.

  As shown in FIG. 3, these four screw grooves 36 are formed at positions where the respective start points st are spaced from each other by 90 degrees, and the respective end points et are also formed at positions spaced from each other by 90 degrees. ing. The screw groove 36 is formed in a spiral shape of about one turn from the start point st to the end point et, but is not limited to this, and is less than one turn, such as about a half turn, about 3/4 turn, It may be formed in a spiral shape of one or more rounds, such as about one and a half rounds, or about two rounds.

  The screw grooves 36 are independently formed as four equal grooves that gradually increase in radius in the clockwise direction (clockwise) from the inner diameter side to the outer diameter side of the large radius flange portion 133s. Yes. However, the present invention is not limited to this, and the screw grooves 36 may be in various other numbers such as two-way, three-way, and six-way. In this case, the slinger 130 rotates counterclockwise (counterclockwise) as indicated by an arrow in the figure, contrary to the thread groove 36.

  However, the groove formed on the outer surface 133a of the curved flange portion 133 of the slinger 130 is not necessarily the screw groove 36. For example, as shown in FIG. 4A, the slinger 130s has a radial shape extending from the inner diameter side to the outer diameter side of the curved flange portion 133 of the flange portion 133, and in a direction perpendicular to the axis of the slinger 130. It may be a radial groove 137 (137a to 137h) extending linearly. In this case, the lip tip of the main lip 22 slides with the outer side surface 133a of the curved flange portion 133, for example, at a position POS1 near the center of the radial groove 37.

  Similarly, as shown in FIG. 4B, in the slinger 130v, the curved flange portion 133 of the flange portion 133 extends from the inner diameter side toward the outer diameter side, but from the inner diameter side toward the outer diameter side toward the outer diameter side. It may be an inclined groove 138 (138a to 138h) extending linearly so as to incline to the right in the figure. In this case, the lip tip of the main lip 22 slides with the outer side surface 133a of the curved flange portion 133, for example, at a position POS2 slightly closer to the outer periphery than the vicinity of the center of the inclined groove 38.

  In this case, the radial groove 137 and the inclined groove 138 have a very short length from the start point st to the end point et as compared with the screw groove 36, and the lubricating oil G1 is shortened along the radial groove 137 and the inclined groove 138. It is possible to swing it back in time and return to the in-flight A side. Further, since the radial grooves 137 and the inclined grooves 138 can form a larger number of grooves than the screw grooves 36, a larger amount of the lubricating oil G1 can be supplied to the in-machine A side in a shorter time than the screw grooves 36. It becomes possible to return to.

  As described above, the large-radius flange portion 133s of the curved flange portion 133 has a relative contact angle θ1 (FIGS. 2 and 6) when the lip tip of the main lip 22 of the elastic body portion 21 contacts the outer surface 133a. ) Is smaller than the conventional contact angle θ0 (FIG. 5), and is formed in a curved shape with a large curvature radius.

  In this case, since the contact area between the lip tip of the main lip 22 and the outer surface 133a of the large radius flange portion 133s increases by the amount that the contact angle θ1 is smaller than the conventional contact angle θ0, it is easy to maintain the sealing performance. . Here, although the lip tip of the main lip 22 is pressed against the outer surface 133a of the large radius flange portion 133s, the contact angle θ1 has a large radius with an interference that does not cause the lip tip side of the main lip 22 to be bent. It is assumed that the flange portion 133s is in contact with the outer surface 133a. However, the present invention is not limited to this, and the outer lip 133a of the large radius flange portion 133s and the lip tip may be in contact with each other with a margin that the tip side of the main lip 22 is bent. In this case, it is assumed that the contact angle θ1 measured at a position on the tip side shorter than the length of about 20% from the lip tip among the length from the lip tip to the base of the main lip 22 is assumed.

  Thus, in the oil seal 1, the main lip 22 of the elastic body portion 21 that contacts the outer surface 133a of the large radius flange portion 133s in the curved flange portion 133 of the slinger 130 is disposed on the in-machine A side, and the lubricating oil oozes out. The dust strip 23 of the elastic body portion 21 that contacts the outer peripheral surface 131a of the cylindrical portion 131 of the slinger 130 is disposed on the outside B side of the slinger 130, so that dust enters and the lubricating oil leaks to the outside B side. It has a structure that prevents this.

  By the way, in the hub seal generally used for the hub bearing, the side lip (corresponding to the main lip 22) of the elastic body portion that comes into contact with the flange portion of the slinger is arranged on the outside B side to prevent dust from entering, A radial lip (corresponding to the dust lip 23) in contact with the cylindrical portion of the slinger is disposed on the in-machine A side to prevent the lubricating oil from leaking.

  That is, the oil seal 1 according to the present invention is opposite to the hub seal because the arrangement of the main lip 22 in contact with the slinger 130 is opposite to that of the hub seal used in the hub bearing and the role thereof is also opposite. It has a fundamentally different seal structure.

  In the oil seal 1 having such a configuration, the main lip 22 of the elastic body portion 21, the dust strip 23, the outer peripheral surface 131 a of the cylindrical portion 131 of the slinger 130, the small radius flange portion 133 m of the curved flange portion 133, and the large size. An annular closed space S (FIG. 6) centered on the axis x is formed by the radius flange portion 133s.

  This space S is transmitted through the gap between the outer surface 133a of the large radius flange portion 133s of the curved flange portion 133 of the slinger 130 and the lip tip of the main lip 22 to the lubricating oil G1 (see FIG. FIG. 6) is a space for storing. The lubricant G1 stored in the space S is prevented from leaking to the outside B side due to the presence of the dust lip 23.

<Action and effect>
With the above configuration, the oil seal 1 in the first embodiment is fixed by the seal portion 10 being press-fitted into the inner peripheral surface 202a of the housing 202, and the slinger 130 is press-fitted into the outer peripheral surface 201a of the crankshaft 201. To be fixed.

  At this time, the dust lip 23 of the elastic body portion 21 in the seal portion 10 is brought into contact with the outer peripheral surface 131 a of the cylindrical portion 131 of the slinger 130 with a predetermined interference, and the main lip 22 of the elastic body portion 21 is curved of the slinger 130. The outer surface 133a of the flange 133 is brought into contact with a predetermined interference. In this case, since the thickness of the base lip 22r is thinner than that of the main body 22b, the main lip 22 has a margin that does not bend the lip tip even if the main lip 22 is bent from the base.

  At this time, the seal portion 10 and the slinger 130 are combined so that any one of the four screw grooves 36 and the lip tip of the main lip 22 always come into contact with the lip tip of the main lip 22 of the elastic body portion 21.

  In the oil seal 1 composed of the seal portion 10 and the slinger 130 attached in combination as described above, the slinger 130 rotates counterclockwise as the crankshaft 201 rotates.

  At this time, the oil seal 1 oozes out into the space S due to the influence of the four screw grooves 36 formed in the end region on the outer peripheral side (in the direction of arrow c) in the large radius flange portion 133s of the curved flange portion 133. Lubricating oil G1 is moved from the inner peripheral side (arrow d direction) toward the outer peripheral side (arrow c direction), and from the gap between the outer surface 133a of the large radius flange portion 133s and the lip tip of the main lip 22 toward the in-machine A side. Can be sucked and discharged (screw action). That is, the thread groove 36 has an oil discharge function as a function of sucking and discharging the lubricating oil G1 from the space S to the in-machine A side.

  In the oil seal 1, the presence of the intermediate lip 24 of the elastic body portion 21 can catch the lubricating oil G <b> 1 that has oozed into the space S, thereby preventing the lubricating oil G <b> 1 from reaching the dust lip 23 directly. However, the lubricating oil G1 that has entered the space S can be sucked out to the in-machine A side.

  Further, the oil seal 1 moves the lubricating oil G1 in the space S from the inner peripheral side (arrow d direction) to the outer peripheral side (arrow c direction) by centrifugal force accompanying the rotation of the curved flange portion 133 of the slinger 130. The lubricating oil G1 can be discharged while swinging off from the gap between the outer surface 133a of the large radius flange portion 133s of the curved flange portion 133 and the lip tip of the main lip 22 to the in-machine A side (swinging action).

  That is, the oil seal 1 is caused by the screw action on the lubricating oil G1 in the space S due to the influence of the screw groove 36 and the swing-off action on the lubricating oil G1 in the space S due to the centrifugal force of the large radius flange portion 133s of the curved flange portion 133. The pumping effect of discharging the lubricating oil G1 existing in the space S into the machine A can be activated.

  Incidentally, as shown in FIG. 5, the conventional sealing device 100 (FIG. 10) has a relative contact angle θ <b> 0 between the inner surface 111 u which is the inner surface of the main lip 111 and the outer surface 103 a of the flange portion 103. In comparison, as shown in FIG. 6, in the oil seal 1 of the present invention, the relative contact angle θ1 between the inner surface 22u of the main lip 22 and the outer surface 133a of the large radius flange portion 133s is greater than the contact angle θ0. (Θ0> θ1).

  In the conventional sealing device 100, since the contact angle θ0 between the main lip 111 and the flange portion 103 is large, the lubrication adhered by the surface tension between the inner surface 111u of the main lip 111 and the outer surface 103a of the flange portion 103. The amount of oil G0 is small. Therefore, even if the pumping effect is activated, the lubricating oil G0 that has entered the space S is not efficiently discharged to the in-machine A side, and thus partly remains.

  In contrast, in the oil seal 1 of the present invention, the relative contact angle θ1 between the main lip 22 and the large radius flange portion 133s of the curved flange portion 133 is smaller than the conventional contact angle θ0. For this reason, the amount of the lubricating oil G1 that adheres and is retained by the surface tension between the inner side surface 22u of the main lip 22 and the outer side surface 133a of the large radius flange portion 133s is larger than the conventional amount.

  That is, the adhesion area of the lubricating oil G1 that adheres to the inner side surface 22u of the main lip 22 and the outer side surface 133a of the large radius flange portion 133s is larger than the conventional one. Specifically, the attachment width W1 of the lubricating oil G1 attached to the inner side surface 22u of the main lip 22 and the outer side surface 133a of the large radius flange portion 133s is larger than that of the conventional sealing device 100 (FIG. 5).

  For this reason, since the lubricating oil G1 adhered by the surface tension between the inner side surface 22u of the main lip 22 and the outer side surface 133a of the large radius flange portion 133s is efficiently discharged as it is to the in-machine A side by the pumping action. It is possible to prevent the lubricating oil G1 from remaining in the space S.

  By the way, in the conventional flange part 103, the velocity vector which goes to the outer peripheral side (arrow c direction) when the lubricating oil G0 adhering to the outer side surface 103a of the said flange part 103 is shaken off with a centrifugal force is large.

  On the other hand, in the oil seal 1 of the present invention, the large radius flange portion 133s is curved and the outer surface 133a is inclined rather than vertical as in the prior art, so that it adheres to the outer surface 133a of the large radius flange portion 133s. The velocity vector toward the outer peripheral side (in the direction of the arrow c) when the lubricating oil G1 is shaken off by the centrifugal force is smaller than that of the conventional flange portion 103.

  Further, in the oil seal 1, since the large radius flange portion 133s is curved and the outer surface 133a is not as vertical as the conventional one, the lubricating oil G1 adhering to the outer surface 133a of the large radius flange portion 133s is more conventional. It is in a state where it is harder to separate than the lubricating oil G0 adhering to the portion 103. In the oil seal 1, since the large radius flange portion 133s is curved, the lubricating oil G1 adhering to the outer surface 133a of the large radius flange portion 133s is caused by centrifugal force and surface tension of the large radius flange portion 133s. The air is efficiently discharged along the outer side surface 133a to the in-machine A side.

  Thus, in the oil seal 1, even when the engine speed is higher than the predetermined engine speed, the lubricating oil G 1 is removed by the swinging action of the lubricating oil G 1 due to the centrifugal force of the curved flange portion 133 and the screw groove 36. The screw action to return to the in-machine A side works effectively.

  That is, the oil seal 1 can sufficiently exhibit a pumping effect that efficiently returns the lubricating oil G1 that has oozed from the interior A side to the space S from the space S to the interior A side in a short time. Thus, the oil seal 1 greatly reduces the leakage of the lubricating oil G1 from the space S to the outside B of the machine S even if the lubricating oil G1 in the machine A leaks into the space S. can do.

  Further, in the oil seal 1, the distance between the curved flange portion 133 of the slinger 130 and the intermediate lip 24 is narrower than that of the conventional sealing device 100 (FIG. 10). Therefore, from the outboard side B to the inboard side A due to the labyrinth effect. Intrusion of dust can be prevented more effectively than before.

  Furthermore, in the oil seal 1, since the relative contact angle θ1 between the lip tip of the main lip 22 and the outer surface 133a of the large radius flange portion 133s is smaller than that of the conventional one, the inner surface 22u of the main lip 22 and the large radius flange portion Since the degree of close contact with the outer surface 133a of 133s increases more than before and closes many screw grooves 36, stationary leakage can be suppressed as compared with the conventional case.

<Example>
In the oil seal 1 of the present invention, when the engine speed is 8000 rpm, for example, the relative contact angle θ1 when the main lip 22 and the large radius flange portion 133s of the curved flange portion 133 contact each other is about 30. When the angle was gradually reduced from a large angle of about 50 degrees to a small angle of about 0 degrees, the change in the amount of air sucked into the in-machine A side of the air containing the lubricating oil G1 existing in the space S was measured. FIG. 7 is a graph showing the relationship between the contact angle θ1 and the air suction amount.

  Here, as the main lip 22 used for the slinger 130 of the oil seal 1, not only the thin lip as described above, but also the thickness of the base portion 22r is substantially equal to or greater than the thickness of the main body portion 22b. It may be a thick lip having a thin lip 220n and a thick lip 220k in the following description. As a comparison object, a thin lip used for a slinger (a slinger having a shape corresponding to the slinger 130 of the present invention) in which the screw groove 36 is not formed is distinguished as a thin lip 220x.

  In this measurement result, when the contact angle θ1 is large, the air suction amount is 0 [ml / min] in any of the thin lips 220n, the thick lips 220k, and the thin lips 220x, but the contact angle θ1 becomes small. Accordingly, it is shown that the air suction amount increases almost linearly. For the thin lip 220x in which the screw groove 36 is not formed, since the screw groove 36 is not provided, the air suction amount is 0 [ml / min] even if the contact angle θ1 decreases, and the space S is lubricated. It is predicted that oil G1 is likely to ooze out.

  As described above, in the oil seal 1, the rotational speed of the engine is 8000 rpm, and the relative contact angle θ 1 between the main lip 22 and the large radius flange portion 133 s of the curved flange portion 133 becomes small, and the lubricating oil G 1 When the adhesion width W1 to the outer side surface 133a of the large radius flange portion 133s is increased, it has been found that the amount of air sucked into the in-machine A side of the air containing the lubricating oil G1 existing in the space S is significantly increased.

  That is, the oil seal 1 has a relative relationship between the main lip 22 and the large-radius flange portion 133s of the curved flange portion 133 even when the rotation speed of the crankshaft 201 is higher than a predetermined value. It has been found that if the contact angle θ1 is reduced, the lubricating oil G1 that has oozed into the space S from the in-machine A side can be efficiently returned to the in-machine A side, and the lubricating oil G1 can be prevented from being stored in the space S.

<Second Embodiment>
FIG. 8 is an enlarged cross-sectional view showing a single structure of the oil seal 200 according to the second embodiment of the present invention. As shown in FIG. 8 in which the same reference numerals are assigned to the parts corresponding to FIG. 2, the oil seal 200 includes the seal portion 10 and the slinger 230 attached to the outer peripheral surface 201a of the crankshaft 201, which are combined. Configured. That is, the oil seal 200 is characterized in that a slinger 230 is used instead of the slinger 130 of the oil seal 1 in the first embodiment.

  The slinger 230 includes a cylindrical portion 231 and a convex curved flange portion 232. The cylindrical portion 231 has substantially the same configuration as the cylindrical portion 131 in the first embodiment, but the length along the axis x direction is longer than the cylindrical portion 131 (FIGS. 1 and 2). ing. Also in the slinger 230, for example, a plate-like member can be formed by bending.

  The convex curved flange portion 232 extends from the inner end (in the direction of arrow b) of the cylindrical portion 231 in a direction away from the axis x, and is curved in a convex shape along the main lip 22 of the seal portion 10. An annular portion centered on x.

  Specifically, the convex curved flange portion 232 extends from the inner end (in the arrow b direction) of the cylindrical portion 231 to the outer peripheral side (in the arrow c direction), and its tip is directed toward the inner side (in the arrow b direction). It has an arch shape that bends and curves to bulge as a whole. The convex curved flange portion 232 has an outer surface 232a that is a surface curved in a convex manner toward the main lip 22 (in the direction of arrow a), and the outer surface 232a is similar to that of the first embodiment. A thread groove 36 is formed.

  The convex curved flange portion 232 has a relative contact angle θ1 between the outer surface 232a curved in a convex shape toward the main lip 22 and the lip tip of the main lip 22 of the elastic body portion 21 in the first embodiment. Similarly to the conventional case, it is made smaller. In this case, the contact angle θ <b> 1 is an angle between a tangent line when the lip tip of the main lip 22 and the outer side surface 232 a of the convex curved flange portion 232 are in contact with the inner side surface 22 u of the main lip 22.

  Also in the oil seal 200 having such a configuration, the same operational effects as those of the first embodiment can be obtained. Specifically, in the oil seal 200, the adhesion width of the lubricating oil G1 adhered to the main lip 22 and the convex curved flange portion 232 is larger than that of the conventional sealing device 100 (FIG. 5). For this reason, even when the engine speed is increased, the oil seal 200 causes the lubricating oil G1 to be supplied to the inboard A side by the swinging action of the lubricating oil G1 due to the centrifugal force of the convex curved flange portion 232 and the screw groove 36. The screw action of returning to the center works effectively, and the pumping effect can be sufficiently exhibited. That is, the oil seal 200 efficiently returns the lubricating oil G1 that has oozed out from the A-side to the space S to the A-side, even when the engine is rotating at high speed, and the lubricating oil G1 is stored in the space S. Since this can be prevented, the leakage of the lubricating oil G1 in the machine A to the outside B through the space S can be greatly reduced.

  Furthermore, in the oil seal 200, since the cylindrical portion 231 of the slinger 230 is longer in the axis x direction than the cylindrical portion 131 of the first embodiment, the fitting area with the outer peripheral surface 201a of the crankshaft 201 is increased. The displacement of the slinger 230 in the direction of the axis x can be suppressed accordingly.

<Third Embodiment>
FIG. 9 is an enlarged cross-sectional view showing a single structure of an oil seal 300 according to the third embodiment of the present invention. As shown in FIG. 9 in which the same reference numerals are assigned to corresponding parts to FIGS. 2 and 8, the oil seal 300 includes the seal portion 10 and a slinger 330 attached to the outer peripheral surface 201 a of the crankshaft 201. Are combined. That is, the oil seal 300 is characterized in that a slinger 330 is used instead of the slinger 130 of the oil seal 1 in the first embodiment and the slinger 230 of the oil seal 200 in the second embodiment.

  The slinger 330 can be formed, for example, by cutting out the outer (in the arrow a direction) and the outer peripheral side (in the arrow c direction) of the slinger 330 so as to have a concave cross section. And a base portion 332 that integrally connects the cylindrical portion 331 and the disc-like flange portion 333.

  The cylindrical portion 331 of the slinger 330 has an inner peripheral surface 331a similar to the inner peripheral surface 131a of the cylindrical portion 131 in the first embodiment. The base portion 332 and the disk-like flange portion 333 have an outer surface 333a similar to the outer surface 133a of the small radius flange portion 133m and the large radius flange portion 133s in the first embodiment.

  That is, the outer surface 133a of the small radius flange portion 133m and the large radius flange portion 133s, and the base portion 332 of the slinger 330 and the outer surface 333a of the disk-like flange portion 333 are the same in terms of the radius of curvature and the presence or absence of the thread groove 36. The same is true for the relative contact angle θ1 when the lip tip of the main lip 22 and the outer surface 333a of the disc-shaped flange portion 333 are in contact with each other.

  Therefore, the oil seal 300 also has the same effect as the oil seal 1 in the first embodiment, and greatly reduces the leakage of the lubricating oil G1 in the machine A to the outside B through the space S. be able to.

  Further, in the oil seal 300, the fitting area when the cylindrical portion 331 and the base portion 332 of the slinger 330 are fitted to the outer peripheral surface 201a of the crankshaft 201 is larger than in the first and second embodiments. Therefore, the positional deviation of the slinger 330 in the axis x direction can be suppressed by that amount.

<Other embodiments>
In the first to third embodiments described above, the case where a thin lip in which the thickness of the base portion 22r is thinner than the thickness of the main body portion 22b is used as the main lip 22 has been described. The present invention is not limited to this, and the thickness of the base portion 22r may be equal to or greater than the thickness of the main body portion 22b.

  The preferred embodiments of the present invention have been described above, but the present invention is not limited to the oil seals 1, 200, 300 according to the first to third embodiments described above, and the concept of the present invention. And any and all aspects falling within the scope of the claims. In addition, the respective configurations may be selectively combined as appropriate so as to achieve at least part of the above-described problems and effects. For example, the shape, material, arrangement, size, and the like of each component in the above embodiment can be changed as appropriate according to the specific usage mode of the present invention.

  Moreover, although the oil seals 1, 200, and 300 as the sealing device according to the present embodiment are used as seals for an automobile engine, the application target of the sealing device according to the present invention is not limited to this. However, the present invention is applicable to all configurations that can utilize the effects of the present invention, such as other general-purpose machines and industrial machines.

DESCRIPTION OF SYMBOLS 1,100,200,300 ... Oil seal 10, 102 ... Seal part, 20 ... Reinforcement ring, 21 ... Elastic body part, 22, 111 ... Main lip, 23 ... Dustrip, 24 ... Intermediate lip, 36 ... Screw groove (Groove), 103 ... flange portion, 104 ... thread groove, 101, 130, 230, 330 ... slinger, 131, 231, 331 ... cylindrical portion, 133 ... curved flange portion, 131a, 231a, 331a ... outer peripheral surface, 103a, 133a, 232a, 333a ... outer surface, 133m ... small radius flange portion, 133s ... large radius flange portion, 137 ... radial groove (groove), 138 ... inclined groove (groove), 201 ... crankshaft (rotating shaft), 202 ... Housing, 232 ... Convex curved flange part, 332 ... Base part, 333 ... Disc-shaped flange part, S ... Space, A ... Inside the machine, B ... Outside the machine

Claims (4)

A cylindrical portion mounted on the outer peripheral surface of the rotating shaft rotating with respect to the housing, and a slinger having an annular flange portion extending in a direction away from the axis of the rotating shaft from an inner end portion of the cylindrical portion;
A seal portion that is mounted on the housing and has a main lip that seals lubricating oil to the inside of the housing of the housing by slidably contacting the outer surface of the flange portion of the slinger;
A groove is formed in the outer surface of the flange portion in contact with the main lip so as to exert a discharge action for returning the lubricating oil to the inside of the housing during rotation, and the outside of the flange portion. The sealing device, wherein the flange portion is curved so that a relative contact angle between the flange portion and the main lip when a side surface and the main lip contact each other is reduced. 2. The sealing according to claim 1, wherein the flange portion is curved in a concave shape with respect to the main lip, and an outer side surface of the curved flange portion contacts a lip tip of the main lip. apparatus. The said flange part is curving convexly with respect to the said main lip, The outer surface of the curved said flange part and the lip | tip front-end | tip of the said main lip contact. Sealing device. The flange portion has an arch shape that bulges in a convex shape from an inner end portion of the cylindrical portion toward an outer peripheral side separated from the axis of the rotation shaft. The sealing device according to 1.

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