JP7051443B2 - Sealing device - Google Patents

Description

The present invention relates to a sealing device for sealing between a shaft and a hole into which the shaft is inserted.

In vehicles, general-purpose machines, etc., a sealing device has been conventionally used to seal between a shaft and a hole into which the shaft is inserted in order to prevent leakage of a sealed object such as lubricating oil. .. In such a sealing device, the sealing lip is brought into contact with the shaft or an annular member attached to the shaft to seal between the shaft and the sealing device. Some of such sealing devices are called end face contact type. The end face contact type sealing device is designed to prevent leakage of the sealed object by contacting a slinger attached to the shaft with a seal lip extending along the shaft.

In the conventional end face contact type sealing device, a groove is provided in the slinger that the seal lip contacts, and by the pumping action of the groove when the slinger rotates, the sealed object such as oil is sealed together with the air on the atmospheric side. Some have improved sealing performance by sending to the side. In such a conventional end face contact type sealing device, as described above, when the slinger is rotated, the exuded sealed object can be returned to the sealed object side by the pumping action, but when the slinger is stopped. May cause so-called static leakage, in which the sealed object leaks from the gap formed between the slinger groove and the end face lip.

In order to prevent this static leakage, the conventional end face contact type sealing device is further provided with a seal lip that contacts the slinger on the inner peripheral side of the seal lip, and seeps out due to the static leakage generated in the seal lip on the outer peripheral side. Some of the sealed objects are intended to prevent further leakage to the outside (see, for example, Patent Document 1).

Jikkenhei 4-88773 Gazette

In such a conventional end face contact type sealing device, as described above, the seal lip on the inner peripheral side is used to prevent static leakage, but since the two seal lips are in contact with the slinger. , The sliding resistance to the shaft increases when the slinger rotates. In recent years, due to the demand for low fuel consumption of vehicles and the like, the sealing device is required to reduce the sliding resistance with respect to the shaft, and the end face contact type sealing device is required to slide with respect to the shaft while preventing static leakage. There is a demand for a structure that can reduce dynamic resistance.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a sealing device capable of preventing static leakage of a sealed object without increasing sliding resistance with respect to the shaft. ..

In order to achieve the above object, the sealing device according to the present invention is a sealing device for sealing an annular gap between a shaft and a hole into which the shaft is inserted, and is fitted into the hole. The sealing device main body is provided with a slinger attached to the shaft, and the sealing device main body is annular around the axis formed by an annular reinforcing ring around the axis and an elastic body attached to the reinforcing ring. The slinger has a flange portion which is an annular portion around the axis extending toward the outer peripheral side, and the elastic body portion has one side in the axial direction. It has an end face lip that is an annular lip around the axis that contacts the other side surface of the flange portion in the axial direction and extends toward the other side of the flange portion of the slinger. At least one groove is formed on the surface, and the groove has a chamfered portion formed at the open end of the groove.

In the sealing device according to one aspect of the present invention, the slinger has a plurality of grooves.

In the sealing device according to one aspect of the present invention, the groove has a groove depth of 0.1 mm or less.

In the sealing device according to one aspect of the present invention, the chamfered portion is subjected to R chamfering or C chamfering.

In the sealing device according to one aspect of the present invention, the groove has a V-shaped or U-shaped cross section.

According to the sealing device according to the present invention, it is possible to prevent static leakage of the sealed object without increasing the sliding resistance with respect to the shaft.

It is sectional drawing in the cross section along the axis for showing the schematic structure of the sealing apparatus which concerns on embodiment of this invention. It is a partially enlarged cross-sectional view which shows by enlarging a part of the cross section along the axis of the sealing device which concerns on embodiment of this invention. It is a side view which looked at the slinger in the sealing apparatus which concerns on embodiment of this invention from the outside. It is a figure for demonstrating the shape of a groove, FIG. 4A is a partially enlarged side view of the slinger which looked at the groove adjacent to each other from the outside, and FIG. 4B is the groove in the cross section along the axis. FIG. 4C is a partially enlarged cross-sectional view showing the shape of the chamfered portion of the groove, and FIG. 4C is a partially enlarged cross-sectional view showing the shape of the chamfered portion of the groove. FIG. 3 is a partially enlarged cross-sectional view of a sealing device in a used state in which the sealing device shown in FIG. 1 is attached to a housing as an attachment target and a shaft inserted into a shaft hole which is a through hole formed in the housing.

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

FIG. 1 is a cross-sectional view taken along the axis x for showing a schematic configuration of the sealing device 1 according to the embodiment of the present invention, and FIG. 2 is an axis of the sealing device 1 according to the embodiment of the present invention. It is a partially enlarged cross-sectional view which shows by enlarging a part of the cross section along x.

The sealing device 1 according to the present embodiment is a sealing device for sealing an annular gap between a shaft and a hole into which the shaft is inserted, and is formed on the shaft and a housing in a vehicle or a general-purpose machine. This shaft is used to seal between the inserted hole (shaft hole). For example, it is used to seal an annular space between the crankshaft of an engine and a crank hole which is a shaft hole formed in a front cover, a cylinder block, and a crankcase. The object to which the sealing device 1 according to the embodiment of the present invention is applied is not limited to the above.

Hereinafter, for convenience of explanation, the arrow a (see FIG. 1) direction (one side in the axis direction) is inside in the axis x direction, and the arrow b (see FIG. 1) direction (the other side in the axis direction) in the axis x direction. Is the outside. More specifically, the inside is the side of the space to be sealed (the side of the object to be sealed), the side of the space where the object to be sealed such as lubricating oil is present, and the outside is the side opposite to the inside. .. Further, in the direction perpendicular to the axis x (hereinafter, also referred to as “diameter direction”), the direction away from the axis x (direction of arrow c in FIG. 1) is set as the outer peripheral side, and the direction closer to the axis x (arrow d in FIG. 1). Direction) is the inner circumference side.

As shown in FIG. 1, the sealing device 1 includes a sealing device main body 2 fitted in a hole as a mounting target described later, and a slinger 3 mounted on a shaft as a mounting target described later. The sealing device main body 2 includes an annular reinforcing ring 10 around the axis x, and an annular elastic body portion 20 around the axis x formed from the elastic body attached to the reinforcing ring 10.

The slinger 3 has a flange portion 31 which is an annular portion around an axis x extending toward the outer peripheral side (direction of arrow c). The elastic body portion 20 is an outer surface that extends toward one side (inside, arrow a direction) in the axis x direction and is a surface on the other side (outside, arrow b direction side) in the axis direction x of the flange portion 31. It has an end face lip 21 which is an annular lip around the axis x in contact with 31d. At least one shallow groove 33 is formed on the outer surface 31d of the flange portion 31 of the slinger 3. Hereinafter, each configuration of the sealing device main body 2 and the slinger 3 of the sealing device 1 will be specifically described.

As shown in FIGS. 1 and 2, the reinforcing ring 10 in the sealing device main body 2 is an annular metal member centered on or substantially centered on the axis x, and the sealing device main body 2 is press-fitted into the shaft hole of the housing described later. It is formed so as to be fitted, fitted, and fitted. The reinforcing ring 10 is, for example, a tubular portion 11 which is a tubular portion located on the outer peripheral side (arrow c direction) and an inner peripheral side (arrow d direction) from an end portion on the outside (arrow b direction) of the tubular portion 11. The disk portion 12 which is a hollow disk-shaped portion extending to the inside (arrow a direction) and the inner peripheral side (arrow d direction) from the end portion of the disk portion 12 on the inner peripheral side (arrow d direction). The pyramidal ring portion 13 which is an annular portion of the above and the end portion of the inside (arrow a direction) or the inner peripheral side (arrow d direction) of the pyramidal ring portion 13 extends radially toward the inner peripheral side (arrow d direction). It has a disk portion 14 which is a hollow disk-shaped portion extending to the end on the inner peripheral side (arrow d direction) of the reinforcing ring 10.

More specifically, the tubular portion 11 of the reinforcing ring 10 is outside the outer peripheral side cylindrical portion 11a, which is a cylindrical or substantially cylindrical portion located on the outer peripheral side (direction of arrow c), and the outer peripheral side cylindrical portion 11a. The inner peripheral side cylindrical portion 11b, which is a cylindrical or substantially cylindrical portion extending on the inner peripheral side (arrow b direction) and the inner peripheral side (arrow d direction), is connected to the outer peripheral side cylindrical portion 11a and the inner peripheral side cylindrical portion 11b. It has a connecting portion 11c which is a portion.

When the sealing device main body 2 is fitted into the shaft hole 51 of the housing 50 (FIG. 3) described later, the outer peripheral side cylindrical portion 11a of the tubular portion 11 becomes the axis x of the sealing device main body 2 and the axis of the shaft hole 51. It is fitted into the shaft hole 51 so that the two can be matched. An elastic body portion 20 is attached to the reinforcing ring 10 from the substantially outer peripheral side (direction of arrow c) and the outside (direction of arrow b), and the elastic body portion 20 is reinforced by the reinforcing ring 10.

As shown in FIGS. 1 and 2, the elastic body portion 20 includes a base portion 25, which is a portion attached to an end portion on the inner peripheral side (arrow d direction) of the disk portion 14 of the reinforcing ring 10, and a reinforcing ring. It is a portion attached to the reinforcing ring 10 from the outside between the gasket portion 26, which is a portion attached to the tubular portion 11 of the 10 from the outer peripheral side (direction of arrow c), and the base portion 25 and the gasket portion 26. It has a rear cover portion 27.

More specifically, as shown in FIG. 2, the gasket portion 26 is attached to the inner peripheral side cylindrical portion 11b of the tubular portion 11 of the reinforcing ring 10. Further, the outer diameter of the gasket portion 26 is larger than the diameter of the inner peripheral surface 51a (see FIG. 5) of the shaft hole 51, which will be described later. Therefore, when the sealing device main body 2 is fitted into the shaft hole 51 described later, the gasket portion 26 is compressed in the radial direction between the inner peripheral side cylindrical portion 11b of the reinforcing ring 10 and the shaft hole 51, and the shaft The hole 51 and the inner peripheral side cylindrical portion 11b of the reinforcing ring 10 are sealed. As a result, the space between the sealing device main body 2 and the shaft hole 51 is sealed.

Further, the outer diameter of the gasket portion 26 does not have to be larger than the diameter of the inner peripheral surface of the shaft hole 51 over the entire axis x direction, and the outer diameter of the gasket portion 26 is partially the inner peripheral surface of the shaft hole 51. It may be larger than the diameter. For example, an annular convex portion whose tip diameter is larger than the diameter of the inner peripheral surface 51a of the shaft hole 51 may be formed on the outer peripheral side (arrow c direction) surface of the gasket portion 26.

Further, in the elastic body portion 20, the end face lip 21 extends inwardly (in the direction of arrow a) from the substrate portion 25 in an annular shape with the axis x as the center or substantially the center. In the used state in which the sealing device 1 is mounted at a desired position in the mounting target, the end face lip 21 has a slinger contact portion 23 of the inner peripheral surface 22 which is a surface on the inner peripheral side (arrow c direction) of the end face lip 21. It is formed so as to come into contact with the flange portion 31 of the slinger 3 from the outside (direction of arrow b) with the tightening margin of.

The end face lip 21 has, for example, a conical cylinder shape whose diameter increases inward (in the direction of arrow a) in the axis x direction. That is, as shown in FIGS. 1 and 2, the end face lip 21 has an inner side (arrow a direction) and an outer peripheral side (arrow c direction) from the base portion 25 in a cross section along the axis x (hereinafter, also simply referred to as a cross section). In addition, it extends diagonally with respect to the axis x.

Further, the elastic body portion 20 has a dust strip 28 and an intermediate lip 29. The dust strip 28 is a lip extending from the base portion 25 toward the axis x, extending from the base portion 25 in an annular shape with the axis x as the center or substantially the center, and the tip portion in the state of use of the sealing device 1 described later. Is formed so as to come into contact with the slinger 3 from the outer peripheral side (direction of arrow c) with a predetermined tightening allowance.

The dust strip 28 has, for example, a conical cylindrical shape whose diameter is reduced toward the outside (direction of arrow b) in the axis x direction. The dust strip 28 is intended to prevent foreign matter such as dust and moisture from entering the inside of the sealing device 1 from the outside (direction of arrow b) opposite to the sealing object side in the used state. The dust strip 28 may be formed so as not to come into contact with the slinger 3 in the state of use of the sealing device 1.

As shown in FIG. 2, the intermediate lip 29 is a lip extending inward (in the direction of arrow a) in a substantially L-shaped cross section from the base portion 25, and is a base portion in an annular shape with the axis x direction as the center or the substantially center. It extends from 25 and forms an annular recess extending inward (in the direction of arrow a) from the substrate portion 25.

The intermediate lip 29 is not in contact with the slinger 3 in the state of use of the sealing device 1. As described above, the sliding resistance is reduced as compared with the conventional case because the intermediate lip 29 is not in contact with the intermediate lip 29. In the intermediate lip 29, when the end face lip 21 penetrates the slinger contact portion 23 in contact with the slinger 3 and the sealed object penetrates into the inside, the impregnated sealed object moves to the dust strip 28 side. It is formed to prevent it from flowing out. The intermediate lip 29 may have another shape, for example, it may have a conical cylindrical shape whose diameter is reduced toward the inside (direction of arrow a) in the axis x direction.

As described above, the elastic body portion 20 has an end face lip 21, a base portion 25, a gasket portion 26, a rear cover portion 27, a dust strip 28, and an intermediate lip 29, and each portion is integrated. , The elastic body portion 20 is integrally formed of the same material. The shape of the elastic body portion 20 is not limited to the above-mentioned shape, and may be various shapes depending on the application target.

The above-mentioned reinforcing ring 10 is formed of a metal material, and examples of the metal material include stainless steel and SPCC (cold rolled steel). Further, as the elastic body of the elastic body portion 20, for example, there are various rubber materials. Examples of various rubber materials are synthetic rubbers such as nitrile rubber (NBR), hydrogenated nitrile rubber (H-NBR), acrylic rubber (ACM), and fluororubber (FKM).

The reinforcing ring 10 is manufactured by, for example, press working or forging, and the elastic body portion 20 is molded by cross-linking (vulcanization) molding using a molding die. At the time of this cross-linking molding, the reinforcing ring 10 is arranged in the molding die, the elastic body portion 20 is adhered to the reinforcing ring 10 by cross-linking adhesion, and the elastic body portion 20 and the reinforcing ring 10 are integrally molded. Will be done.

The slinger 3 is an annular member attached to a shaft in the state of use of the sealing device 1 described later, and is an annular member having an axis x as a center or a substantially center. The slinger 3 has a substantially L-shaped cross section, and has a tubular portion or a substantially tubular tubular portion extending in the x-axis direction connected to the flange portion 31 and the end portion on the inner peripheral side of the flange portion 31. It has 34 and.

Specifically, the flange portion 31 has a hollow disk-shaped or substantially hollow disk-shaped inner peripheral side disk portion 31a extending in the radial direction from the tubular portion 34, and an outer peripheral side (arrow c direction) from the inner peripheral side disk portion 31a. ), A hollow disk-shaped or substantially hollow disk-shaped outer peripheral side disk portion 31b extending in the radial direction, and an outer peripheral side (arrow c direction) end portion and an outer peripheral side disk portion 31b of the inner peripheral side disk portion 31a. It has a connecting portion 31c that connects to the end portion on the inner peripheral side (direction of arrow d). The outer peripheral side disk portion 31b is located outside (arrow b direction) in the axis x direction with respect to the inner peripheral side disk portion 31a.

The shape of the flange portion 31 is not limited to the above-mentioned shape, and may be various shapes depending on the application target. For example, the flange portion 31 does not have the inner peripheral side disk portion 31a and the connecting portion 31c, and the outer peripheral side disk portion 31b extends to the tubular portion 34 and is connected to the tubular portion 34, and has a diameter from the tubular portion 34. It may be a hollow disk-shaped or substantially hollow disk-shaped portion extending in the direction.

The lip contact portion 32, which is a portion where the slinger 3 contacts the end face lip 21, is located on the outer surface 31d, which is a surface facing the outside (arrow b direction) of the outer peripheral side disk portion 31b in the flange portion 31. The outer side surface 31d is preferably a surface along a plane extending in the radial direction.

As described above, at least one shallow groove 33 is formed on the outer surface 31d of the slinger 3. In the present embodiment, as shown in FIG. 3, a plurality of grooves 33 are formed on the outer surface 31d of the slinger 3.

FIG. 3 is a side view of the slinger 3 in the sealing device 1 as viewed from the outside. As shown in FIG. 3, n grooves 33 of grooves 33 ₁ , 332, 33 ₃ ... 33 _n are formed on the outer surface 31d of the slinger ₃ . That is, the number of grooves 33 (number of rows) of the slinger 3 is n. In this case, for example, Article 4.

As shown in FIG. 3, each of the plurality of grooves 33 ₁ to 33 _n , each of the grooves 33 _m (m = 1, 2, 3, and n) intersects the portion where the end face lip 21 contacts. Specifically, the groove 33 _m extends between the inner peripheral side (direction of arrow d) and the outer peripheral side (direction of arrow c), and the outer surface 31d of the outer peripheral side disk portion 31b of the flange portion 31 of the slinger 3 It intersects with the lip contact portion 32, which is the contact portion with the end face lip 21 in the above.

FIG. 4 is a diagram for explaining the shape of the groove 33 _m (m = 1 to n), and FIG. 4 (A) shows the grooves 33 _m and 33 _{m + 1} (m = 1 to n) adjacent to each other outside. It is a partially enlarged side view of the slinger 3 seen from the above, and FIG. 4 (B) is a partially enlarged cross-sectional view of the slinger 3 showing the shape of the groove 33 _m (m = 1 to n) in the cross section along the axis x. FIG. 4C is a partially enlarged cross-sectional view showing the shape of the chamfered portion of the groove. As shown in FIG. 4A, a radial spacing (pitch) p is provided between the grooves 33 _m and the grooves 33 _{m + 1} , which are adjacent to each other and different from each other.

Further, as shown in FIG. 3, the groove 33 _m extends in a spiral shape (spiral shape), and the lead of the groove 33 _m is a lead l. The lead l has a width in which the groove 33 _m expands in the radial direction when the groove 33 _m goes around.

Further, as shown in FIG. 4B, the groove 33 _m is a concave space recessed inward (in the direction of arrow a), and for example, the bottom surface 44 has a V-shaped or substantially V-shaped contour. ing. The sandwiching angle of the bottom surface 44 is an angle α (hereinafter, this is also referred to as “pinching angle α”). This narrowing angle α is 0 degrees <α <180 degrees. However, the groove 33 _m is not limited to the V-shaped or substantially V-shaped bottom surface 44, and may have a U-shaped or substantially U-shaped contour.

As shown in FIG. 4C, the groove 33 _m includes chamfered portions ec1 and ec2 formed at intersections k1 and k2 of the opening end where the outer surface 31d of the flange portion 31 and the bottom surface 44 intersect. .. The chamfered portions ec1 and ec2 are portions in which the two open ends (intersection points k1 and k2) of the groove 33 _m are subjected to R chamfering, and both have a common structure. Only the chamfer ec1 will be described.

The chamfered portion ec1 has the shape of a part of the inscribed circle Cir1 having a radius r1 inscribed with the two sides of the outer surface 31d and the bottom surface 44 (sides 44a and 44b) intersecting at the intersections k1 and k2, and the outer surface 31d. It forms an R surface that smoothly connects to the side 44a and the side 44b.

In this case, the width wL of the groove 33 _m is the distance between the contact point t1 connecting the chamfered portion ec1 and the outer surface 31d and the contact point t2 connecting the chamfered portion ec2 and the outer surface 31d. That is, the width wL of the groove 33 _m is significantly larger than the width wr, which is the distance between the open ends (intersection points k1 and k2) when the chamfered portions ec1 and ec2 are not provided.

Further, a chamfered portion ec3 is also formed at the bottom portion of the bottom surface 44 of the groove 33 _m (the top portion which is the intersection of the sides 44a and the sides 44b). The chamfered portion ec3 is a part of the inscribed circle Cir2 having a radius r2 inscribed in the two sides of the side 44a and the side 44b that intersect at the intersection k3 of the side 44a and the side 44b, and is smoothly connected to the side 44a and the side 44b. The R side is made.

The chamfered portions ec1 to ec3 do not necessarily have to be R-chamfered by the inscribed circles Cir1 and Cir2, and may be a part of an ellipse or may be R-chamfered by another method. You may. Further, the chamfered portions ec1 to ec3 may be not only when the R chamfering process is performed, but also when, for example, the C chamfering process is performed. The radius r2 of the inscribed circle Cir2 is smaller than the radius r1 of the inscribed circle Cir1 and has a relationship of r2 <r1. Here, the depth of the groove 33 _m is the depth hL, which is the distance between the bottom point bt1 in the chamfered portion ec3 of the groove 33 _m and the outer surface 31d of the flange portion 31.

Next, the operation of the sealing device 1 having the above-mentioned configuration will be described. FIG. 5 is a partially enlarged cross-sectional view of the sealing device 1 in a used state in which the sealing device 1 is attached to the housing 50 to be attached and the shaft 52 inserted into the shaft hole 51 which is a through hole formed in the housing 50. Is.

The housing 50 is, for example, an engine front cover or a cylinder block and a crankcase, and the shaft hole 51 is a crank hole formed in the front cover or the cylinder block and the crankcase. Further, the shaft 52 is, for example, a crankshaft.

As shown in FIG. 5, in the state of use of the sealing device 1, the sealing device main body 2 is press-fitted into the shaft hole 51 and fitted into the shaft hole 51, and the slinger 3 is tightly fitted to the shaft 52 and fitted to the shaft 52. It is attached.

Specifically, the outer peripheral side cylindrical portion 11a of the reinforcing ring 10 comes into contact with the inner peripheral surface 51a of the shaft hole 51 to align the axis of the sealing device main body 2 with respect to the shaft hole 51, and the elastic body portion 20. The gasket portion 26 is compressed in the radial direction between the inner peripheral surface 51a of the shaft hole 51 and the inner peripheral side cylindrical portion 11b of the reinforcing ring 10, and the gasket portion 26 is in close contact with the inner peripheral surface 51a of the shaft hole 51. , The sealing device main body 2 and the shaft hole 51 are sealed. Further, the cylindrical portion 35 of the slinger 3 is press-fitted into the shaft 52, the inner peripheral surface 35a of the cylindrical portion 35 is in close contact with the outer peripheral surface 52a of the shaft 52, and the slinger 3 is fixed to the shaft 52.

In the state of use of the sealing device 1, the end face lip 21 of the elastic body portion 20 is outside the outer peripheral side disk portion 31b of the flange portion 31 of the slinger 3 at the slinger contact portion 23 which is a portion of the inner peripheral surface 22 on the tip end 21a side. The relative position in the axis x direction between the sealing device main body 2 and the slinger 3 is determined so as to come into contact with the lip contact portion 32 which is a portion of the side surface 31d.

In the non-use state of the sealing device 1, particularly in the stationary state where the shaft 52 is not rotating, the contact between the end face lip 21 and the lip contact portion 32 of the flange portion 31 causes the sealing between the sealing device main body 2 and the slinger 3 to be sealed. This is intended to prevent leakage of the sealed object from the sealed object side.

The dust strip 28 is in contact with the tubular portion 34 of the slinger 3 from the outer peripheral side at the tip end side portion. The dust strip 28 is in contact with, for example, the outer peripheral surface 35b of the cylindrical portion 35 of the slinger 3.

Further, as described above, the groove 33 _m intersects the lip contact portion 32, which is the portion of the slinger 3 with which the end face lip 21 contacts, between the inner peripheral side (arrow d direction) and the outer peripheral side (arrow c direction). A gap extending between the inner peripheral side (arrow d direction) and the outer peripheral side (arrow c direction) is formed by the groove 33 _m between the slinger contact portion 23 and the lip contact portion 32 that are in contact with each other. The arrow. Therefore, in the stationary state of the sealing device 1 in which the shaft 52 is stationary, that is, the slinger 3 is stationary, a static leakage occurs in which the sealed object seeps out from the sealed object side through the groove 33 _m . It is thought that.

However, in the sealing device 1 of the present invention, as described above, the slinger contact portion 23 of the inner peripheral surface 22 of the end face lip 21 has a predetermined tightening allowance and is attached to the flange portion 31 of the slinger 3 from the outside (direction of arrow b). At the time of contact, the slinger contact portion 23 of the end face lip 21 easily enters the recessed space of the groove 33 _m having a large width wL formed by the chamfered portions ec1 and ec2 whose open ends are rounded. In close contact with the bottom surface 44 (side 44a, side 44b). As a result, the space between the slinger contact portion 23 of the end face lip 21 and the outer surface 31d of the flange portion 31 of the slinger 3 is further sealed, so that the occurrence of static leakage can be prevented even in the stationary state of the sealing device 1. Can be done.

Specifically, in this case, the chamfered portions ec1 and ec2 in which R chamfering is performed at the intersections k1 and k2 of the open end and the slinger contact portion 23 of the end surface lip 21 are in close contact with each other without a gap, and the groove 33 _m . Since the chamfered portion ec3 on which the R chamfering process is applied to the bottom portion (intersection of the sides 44a and the sides 44b) of the bottom surface 44 and the slinger contact portion 23 of the end face lip 21 are in close contact with each other without a gap, the sealing device 1 is in a stationary state. It is possible to further improve the static leakage prevention performance in the above.

In the sealing device 1 of the present invention, especially in the rotating operating state of the shaft 52, the slinger contact portion 23 of the end face lip 21 is slightly lifted from the bottom surface 34 of the groove 33 _m due to the high speed rotation of the shaft 52, so that the pumping action is performed. The sealing property can be exhibited by sending the sealed object such as oil to the sealed object side. That is, in the sealing device 1, it is possible to secure the sealing property against the object to be sealed such as oil when the shaft 52 is rotating or stationary.

Next, the sealing performance of the sealing device 1 according to the embodiment of the present invention will be described. Specifically, the static leakage prevention performance of the sealing device 1 will be described.

The present applicant has manufactured a sealing device 1 according to an embodiment of the present invention having a groove 33 _m in which the above-mentioned chamfered portions ec1 and ec2 are formed (Test Examples 1 to 3 and Comparative Example (conventional technique)). , An evaluation test of the static leakage prevention performance of the sealing device 1 was conducted. Although the angle of the sandwiching angle α is constant, the width wL of the groove 33 _m is also changed according to the size of the radius r1 of the chamfered portions ec1 and ec2. The results of the evaluation test are shown in Table 1 below.

In this evaluation test, in all of Comparative Example (conventional), Test Example 1 to Test Example 3, the lead l = 5.6 mm and the groove number n = 4 were set to 33 _m .

The evaluation test was conducted under the following test conditions.
[Test conditions]
Axis eccentricity of shaft 52: 0.2 mmT. I. R. (Total Indicator Reading)
Mounting eccentricity (eccentricity of shaft hole 51): 0.2 mmT. I. R. (Total Indicator Reading)
Surface runout of Slinger 3: 0.05 mm (actual measurement value)
Oil temperature: 120 ° C
Oil type: 0W-20 (based on SEA standard, SAEJ300 engine oil viscosity classification (January 2015))
Amount of oil: Filled (The space to be sealed is filled with oil, and the back of the entire circumference of the lip is filled with oil.)
Rotational speed of shaft 52 (slinger 3): 0 rpm

The evaluation test was carried out by measuring the time until the occurrence of leakage under the above test conditions was confirmed, with an upper limit of 1,000 hours. Further, the evaluation test was carried out in an evaluation device in which the usage state as shown in FIG. 5 was simulated. In this evaluation device, the oil as the above-mentioned sealing object was poured on the sealing object side so that the entire sealing device 1 was covered with oil on the sealing object side. The static leakage start time (h) is the static leakage start time (h). In order to measure the static leakage amount of the oil, the dust strip 28 and the intermediate lip 29 are deleted, and the oil exuded from the end face lip 21 after the start of the test is the sealing device 1. The time (h) is until it leaks to the outside.

As shown in Table 1, in the comparative example (conventional), the radius r2 of the chamfered portion ec3 in which the bottom portion (intersection of the sides 34a and the sides 34b) of the bottom surface 34 of the groove 33 _m is subjected to R chamfering is 0.3 mm. In addition, when the chamfered portions ec1 and ec2 were not formed at the open end, the static leakage start time (h) was 16 hours.

On the other hand, in Test Example 1, the radius r2 of the chamfered portion ec3 in which the bottom portion (intersection point of the side 34a and the side 34b) of the bottom surface 34 is subjected to R chamfering is 0.3 mm, and the open end. When the radius r1 of the chamfered portions ec1 and ec2 subjected to the R chamfering process was 0.3 mm, the static leakage start time (h) was 33 hours.

Further, in Test Example 2, the radius r2 of the chamfered portion ec3 in which the bottom portion of the bottom surface 34 (the intersection of the sides 34a and 34b) is chamfered is 0.4 mm, and the open end is chamfered. When the radius r1 of the chamfered portions ec1 and ec2 that had been processed was 0.4 mm, the static leakage start time (h) was 48 hours.

Further, the radius r2 of the chamfered portion ec3 in which the bottom portion (intersection point of the side 34a and the side 34b) of the bottom surface 34 is subjected to R chamfering is 0.5 mm, and the opening end is subjected to R chamfering. When the radius r1 of the chamfered portions ec1 and ec2 was 0.5 mm, the static leakage start time (h) was 66 hours.

That is, it was found that the static leakage start time (h) of the groove 33 _m becomes longer as the radius r1 of the chamfered portions ec1 and ec2 formed at the open end becomes larger. This is because the radius r1 of the chamfered portions ec1 and ec2 increases and the width wL increases, and the slinger contact portion 23 of the end face lip 21 easily enters the recessed space of the groove 33 _m and the bottom surface 34 (side 34a, side). It is considered that this is because the degree of close contact with 34b) is increased and the sealing performance is improved.

As described above, from the result of the above-mentioned evaluation test of the static leakage prevention performance, the groove 33 _m can suppress the static leakage as the radius r1 of the chamfered portions ec1 and ec2 becomes larger and the width wL becomes wider. It was found that the static leakage prevention performance was high. More specifically, from the evaluation test of the static leakage prevention performance, it was found that the static leakage prevention is preferable in the order of Test Example 3, Test Example 2, and Test Example 1 among Test Examples 1 to 3. ..

For reference, the applicant has manufactured a sealing device 1 according to an embodiment of the present invention having a groove 33 _m in which the above-mentioned chamfered portions ec1 and ec2 are formed (Test Examples 4 and 5), and the sealing device. The evaluation test of the static leakage prevention performance of No. 1 was also performed. In this case, in Test Example 4, the sandwich angle α was set to 150 degrees, the lead l = 5.6 mm, and the groove number n = 2 and the groove 33 _m . Further, in Test Example 5, the sandwich angle α was 170 degrees, the lead l = 5.6 mm, and the groove number n = 1 was 33 _m . Since the conditions of Test Examples 4 and 5 are different from those of Test Examples 1 to 3, it may not be possible to make an accurate comparison, but they are disclosed for reference. The evaluation conditions are as described above. The results of the evaluation test are shown in Table 2 below.

In Test Example 4, the radius r2 of the chamfered portion ec3 in which the bottom portion (intersection point of the side 34a and the side 34b) of the bottom surface 34 is subjected to R chamfering is 1.0 mm, and the opening end is R chamfered. When the radius r1 of the chamfered portions ec1 and ec2 was 1.0 mm, the static leakage start time (h) was 300 hours.

In Test Example 5, the radius r2 of the chamfered portion ec3 in which the bottom portion (intersection point of the side 34a and the side 34b) of the bottom surface 34 is subjected to R chamfering is 3.0 mm, and the open end is R chamfered. When the radius r1 of the chamfered portions ec1 and ec2 is 3.0 mm, the static leakage start time (h) is only 500 hours. Stopping for 500 hours means that if the test is continued, a longer quiescent leakage time can be expected.

As described above, from the result of the above-mentioned evaluation test of the static leakage prevention performance, the groove 33 _m can suppress the static leakage as the radius r1 of the chamfered portions ec1 and ec2 becomes larger and the width wL becomes wider. It was found that the static leakage prevention performance was high.

As described above, according to the sealing device 1 according to the embodiment of the present invention, it is possible to prevent static leakage of the sealed object without increasing the sliding resistance with respect to the shaft 52 (slinger 3).

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to the sealing device 1 according to the above-described embodiment, and all aspects included in the concept of the present invention and the scope of claims. including. In addition, each configuration may be selectively combined as appropriate so as to achieve at least a part of the above-mentioned problems and effects. Further, for example, the shape, material, arrangement, size, etc. of each component in the above embodiment can be appropriately changed depending on the specific usage mode of the present invention.

Further, although the sealing device 1 according to the present embodiment is applied to the crank hole of the engine, the application target of the sealing device according to the present invention is not limited to this, and other vehicles and general-purpose machines are not limited to this. The present invention is applicable to all configurations that can utilize the effects of the present invention, such as industrial machinery.

1 ... Sealing device, 2 ... Sealing device body, 3 ... Slinger, 10 ... Reinforcing ring, 11 ... Cylinder part, 11a ... Outer peripheral side cylindrical part, 11b ... Inner peripheral side cylindrical part, 11c ... Connection part, 12 ... Disk part, 13 ... Cylinder ring part, 14 ... Disk part, 20 ... Elastic body part, 21 ... End face lip, 21a ... Tip, 22 ... Inner peripheral surface, 23 ... Slinger contact part, 25 ... Base part, 26 ... Gasket part, 27 ... Rear cover part, 28 ... dust strip, 29 ... middle lip, 21 ... end face lip, 31 ... flange part, 31a ... inner peripheral side disk part, 31b ... outer peripheral side disk part, 31c ... connection part, 31d ... outer surface, 32 ... Lip contact part, 33 _m ... Groove, 34 ... Cylinder part, 35 ... Cylindrical part, 35a ... Inner peripheral surface, 35b ... Outer peripheral surface, 44 ... Bottom surface, 44a, 44b ... Side, 50 ... Housing, 51 ... Shaft hole, 51a ... inner peripheral surface, 52 ... axis, 52a ... outer peripheral surface, h ... depth, l ... lead, p ... pitch, S ... sandwich space, w ... width, x ... axis line, α ... flange angle

Claims (5)

A sealing device for sealing an annular gap between a shaft and a hole into which the shaft is inserted.
The sealing device body fitted in the hole and
Equipped with a slinger attached to the shaft
The sealing device main body has an annular reinforcing ring around the axis and an annular elastic body portion around the axis formed from the elastic body attached to the reinforcing ring.
The slinger has a flange portion which is an annular portion around the axis extending toward the outer peripheral side.
The elastic body portion has an end face lip that is an annular lip around the axis that contacts the other side surface of the flange portion in the axial direction that extends toward one side in the axial direction.
At least one groove is formed on the other side surface of the flange portion of the slinger.
The groove is a sealing device having a chamfered portion at the open end of the groove. The sealing device according to claim 1, wherein the slinger has a plurality of grooves. The sealing device according to claim 2, wherein the groove has a groove depth of 0.1 mm or less. The sealing device according to any one of claims 1 to 3, wherein the chamfered portion is subjected to R chamfering or C chamfering. The sealing device according to any one of claims 1 to 4, wherein the groove has a V-shaped or U-shaped cross section.

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