JP2009162310A - Floating seal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To inhibit an increase of sliding resistance torque while using a material having higher rigidity against an impact force and thermal stress than that in a conventional material for a sealing ring. <P>SOLUTION: In a floating seal provided with two members having a pair of housings, respectively, and performing relative rotational motion around a shaft, a pair of sealing rings arranged in the pair of housings and slidingly contacting with each other in a part of opposing faces, and a pair of O-rings held between the pair of housings and the pair of sealing rings, respectively, the opposing face of each sealing ring includes a sealing face having a first angle with respect to a plane perpendicular to the shaft and a taper face adjacent to the inner peripheral side of the sealing face and having a second angle larger than the first angle with respect to the plane perpendicular to the shaft, and a round part having a predetermined radius of curvature is formed at the edge of the outer peripheral side of the sealing face. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a floating seal for preventing muddy water, earth and sand, etc. from entering the interior of a rotating mechanism of a construction machine or the like and preventing leakage of lubricating oil from the inside.

  In a rotating mechanism that is placed in a poor environment in which muddy water and earth and sand are likely to enter, such as the rotating mechanism of self-propelled construction machines such as hydraulic excavators, cranes, and wheel excavators, muddy water and earth and sand are contained inside. Floating seals are used to prevent the lubricating oil from leaking from the inside while preventing the oil from entering the inside.

  FIG. 11 is a partial cross-sectional view showing a conventional floating seal. As shown in FIG. 11, the floating seal 11 includes a pair of housing parts 13 a and 14 a, each of which has two bosses 13 and 14 that relatively rotate around the shaft 12, and a pair of housing parts. A pair of seal rings 15 and 16 which are arranged in 13a and 14a and whose side surface portions are in sliding contact with each other, an inner peripheral surface of the pair of housing portions 13a and 14a and an outer peripheral surface of the pair of seal rings 15 and 16 A pair of O-rings 17 and 18 sandwiched between them.

  Since the side portions of the seal rings 15 and 16 are in contact with each other, when the bosses 13 and 14 relatively rotate, the side portions of the seal rings 15 and 16 slide. A force F is exerted on the sliding surfaces 19 by the O-rings 17 and 18, but oil leakage may occur due to variations in the contact state between the sliding surfaces.

  As a manufacturing method of the seal rings 15 and 16, in order to obtain seizure resistance and wear resistance, alloy steel having a hardness that is difficult to cut is formed by casting, and the sliding surface 19 is ground or Generally, it is formed by lapping. Since the shape accuracy of the cast product is not as high as that of the machined product, the sliding surfaces 19 of the seal rings 15 and 16 abut against each other in the radial direction, which causes oil leakage. Furthermore, since the outer peripheral side edge portion of the sliding surface 19 comes into contact with muddy water, earth and sand, and the like is insufficiently lubricated, wear progresses from the outer peripheral portion of the sliding surface 19 toward the inner peripheral portion by long-term operation.

  In order to solve such a problem, an annular contact surface is formed on the sliding surface even if the pair of seal rings contact with each other, and the outer peripheral portion of the sliding surface. A floating seal having a wide sliding surface has been considered so that a predetermined life can be ensured even if the wear of the material progresses.

  FIG. 12 is a partial cross-sectional view showing a seal ring in a floating seal having a wide sliding surface. As shown in FIG. 12, the width W of the sliding surface 19 of the seal rings 15 and 16 is set to be as wide as about 2 to 3 mm, and a pair of facing sliding surfaces 19 are in contact with each other while being displaced from each other. In this case, an annular contact surface is formed. Further, in order to avoid that the sliding surface 19 having a wide width W contacts the entire surface and the sliding resistance torque becomes excessive, the sliding surface 19 is formed as a concave conical surface or a spherical surface having a slight angle α. Is formed. At this time, in anticipation that the sliding surface 19 is elastically deformed by the moment M generated by the force F and the distance L received from the O-rings 17 and 18 (FIG. 11), the value of the angle α is slightly changed. It is set to exceed. Hereinafter, the elastic deformation of the sliding surface is also referred to as “sag”, and the angle α is also referred to as “sag look-out angle”.

  In the seal ring shown in FIG. 12, however, the width (contact width) B of the contact surface where the seal ring 15 and the seal ring 16 actually contact varies greatly due to slight variation in the sagging allowance angle α. A large variation in the sliding resistance torque between the seal rings 15 and 16 occurs.

  As a related technique, Patent Document 1 discloses a floating seal that aims to be manufactured at low cost because the sliding resistance torque of the seal ring when assembled and its variation are small. The floating seals are disposed at opposing ends of two bosses that rotate relative to each other around the shaft, and are disposed at a substantially intermediate position between the housings and a pair of housings that open facing each other. And a pair of seal rings slidably in contact with each other on the sliding surfaces of the side surfaces facing each other, and at least one sliding surface of the pair of seal rings has a concave conical surface having a sagging allowance angle α1. Alternatively, a first sliding surface formed of a spherical surface and a second sliding surface formed of a concave conical surface or a spherical surface adjacent to the inner edge side of the first sliding surface and having a sagging look-off angle α2. The relationship is α2> α1.

According to the floating seal of Patent Document 1, since the pair of seal rings abut on the first sliding surface, it is possible to reliably prevent the mutual sliding surfaces from abutting on the entire surface. As a result, variations in the sliding resistance torque of the seal ring can be suppressed, so that heat generation and oil leakage can be prevented. In addition, since the first sliding surface may be in contact with the entire surface, the manufacturing tolerance range of the sagging allowance angle α1 of the first sliding surface is set to a small angle region near zero angle, so that the grinding ring of the seal ring can be ground. This can reduce the manufacturing cost.
JP 2004-28228 A (6th page, FIG. 1)

  In such floating seals, it is desired to develop a new balanced seal ring that is tougher against impact force and thermal stress than conventional materials and also has excellent soil and sand resistance. . However, when the hardness of the material is lowered in order to obtain toughness against impact force or thermal stress, there arises a problem that sliding resistance torque is increased and oil leakage occurs at the initial contact surface formation stage.

  Therefore, in view of the above points, the present invention is a floating type that can suppress an increase in sliding resistance torque while using a material having higher toughness against impact force and thermal stress than conventional materials for a seal ring. The object is to provide a seal.

  In order to solve the above-described problem, a floating seal according to one aspect of the present invention includes a pair of housing portions, each of which has two members that relatively rotate around an axis, and a pair of housing portions. And a pair of O-rings sandwiched between a pair of housing portions and a pair of seal rings, respectively. A floating seal, wherein each seal ring has an opposing surface having a first angle with respect to the surface orthogonal to the axis, and a surface adjacent to the inner peripheral side of the seal surface and orthogonal to the axis And a tapered surface having a second angle larger than the first angle, the seal surface width being A, the seal surface width tolerance being ΔA, and the seal ring diameter tolerance being ΔD. Sometimes 0.1 A roundness having a radius of curvature of 1 mm or more and (A−ΔA−ΔD−0.2 mm) or less is formed on the outer peripheral side edge portion of the seal surface.

  According to one aspect of the present invention, by forming a round having a predetermined radius of curvature at the outer peripheral side edge portion of the seal surface, a material having higher toughness against impact force and thermal stress than a conventional material. An increase in sliding resistance torque can be suppressed while being used for a seal ring.

Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings. The same constituent elements are denoted by the same reference numerals, and the description thereof is omitted.
FIG. 1 is a partial sectional view showing a floating seal according to an embodiment of the present invention. As shown in FIG. 1, the floating seal 1 includes a pair of housing portions 3 a and 4 a, respectively, and two members (bosses) 3 and 4 that relatively rotate around the shaft 2. A pair of seal rings 5 and 6 which are disposed in the housing portions 3a and 4a and which are in sliding contact with each other at a part of the opposing side surfaces, and an inner peripheral surface and a pair of seal rings of the pair of housing portions 3a and 4a And a pair of O-rings 7 and 8 sandwiched between the outer peripheral surfaces of 5 and 6, respectively.

  Since the side surfaces of the seal rings 5 and 6 are in contact with each other, when the bosses 3 and 4 relatively rotate, the side surfaces of the seal rings 5 and 6 slide. A force is exerted on the sliding surfaces 9 by O-rings 7 and 8. Conventionally, as a material for the seal rings 5 and 6, alloy steel having a Young's modulus of about 210 GPa and a Rockwell hardness HRC of about 65 to 67 has been used in order to obtain seizure resistance and wear resistance.

  On the other hand, there is a demand for the development of a new balanced seal ring that is tougher than conventional materials and has excellent toughness against impact force and thermal stress, and is also excellent in soil and sand resistance. Therefore, as a material for the seal rings 5 and 6, in order to obtain toughness against impact force and thermal stress, it was examined to use an alloy having a Young's modulus of about 190 GPa to 220 GPa and a Rockwell hardness HRC of about 54 to 62. . Examples of such materials include iron-based alloys such as SUS440C, SKD11, and SUJ2, self-fluxing nickel alloys such as SFNi4, and self-fluxing cobalt alloys such as SFCo2. Furthermore, if carburizing is performed, the surface hardness of SCM, SMn, SCr, S ** C, SNCM, SK *, and the like will satisfy the above conditions.

  However, when the Rockwell hardness of the seal ring material is lowered, the allowable contact stress is reduced, so that the sliding resistance torque is increased and oil leakage occurs at the initial contact surface formation stage of the seal rings 5 and 6. Occurred. Therefore, in the present invention, this problem is solved by rounding the outer peripheral side edge portions of the sliding surfaces of the seal rings 5 and 6 with a predetermined radius of curvature.

  FIG. 2 is a partial cross-sectional view showing a seal ring in the floating seal according to the first embodiment of the present invention, and FIG. 3 is an enlarged cross-sectional view showing a part of one seal ring. In FIG. 3, only the seal ring 6 is shown, but the seal ring 5 has a similar shape.

  As shown in FIG. 3, the sliding surface 9 of the seal ring 6 shown in FIG. 2 is formed of a concave conical surface or a spherical surface that forms an angle α with a surface orthogonal to the axial direction of the shaft 2 (FIG. 1). The seal surface 6a, a surface orthogonal to the axial direction, and a tapered surface 6b that forms an angle β, and the angles α and β have a relationship of α <β.

A roundness having a radius of curvature R is formed on the outer peripheral edge portion of the seal surface 6 a of the seal ring 6. Here, the width of the seal surface 6a is A, the tolerance of the seal surface width A is ΔA, the diameter of the seal ring 6 is D, and the tolerance of the seal ring diameter D is ΔD. In the present embodiment, the seal surface width A is about 2.5 mm, and the seal ring diameter D is about 482 mm. The minimum value B of the width of the contact surface (contact width) is expressed by the following equation (1).
B = A−ΔA−ΔD (1)

Further, from the viewpoint of the initial familiarity of the contact surface and the sealing property, when 0.2 mm is secured as the initial contact width of the seal surface 6a, the roundness formed on the outer peripheral side edge portion of the seal surface 6a. The curvature radius R desirably satisfies the condition of the following formula (2).
0.11 mm ≦ R ≦ A−ΔA−ΔD−0.2 mm (2)
The reason for setting the minimum value of the radius of curvature R to 0.11 mm will be described in detail later.

  As described above, since the edge portion on the outer peripheral side of the seal surface 6a has a gentle curved shape, the initial contact width of the seal surface 6a is widened, so that stress concentration at the tip portion is alleviated. Therefore, the contact surface is formed cleanly during the initial sliding, the initial sliding resistance torque is reduced, and oil leakage is also prevented.

  According to the present embodiment, as the seal ring material, an alloy having a Young's modulus of about 190 GPa to 220 GPa and a Rockwell hardness HRC of about 54 to 62 is used. Therefore, the seal ring material is more resistant to impact force and thermal stress than the conventional seal ring material. Since it has toughness and stress concentration at the tip of the seal surface 6a is alleviated, it is possible to realize a seal ring that can withstand the contact stress of the sliding surface even if the Rockwell hardness is relatively small. In addition, since the contact surface is formed on the inner side by the radius of curvature R from the outer peripheral tip of the seal ring, and the initial contact surface is formed widely, the allowable range of the contact state due to dimensional tolerance increases, Sealability is improved.

Next, a sliding torque test and simulation for determining an appropriate range of the radius of curvature R will be described.
FIG. 4 is a diagram illustrating the relationship between the linear pressure of the floating seal and the sliding resistance torque in various floating seals. In this sliding torque test, sliding resistance torque (kg · m) was measured while changing the linear pressure of the floating seal to 1, 2, 3, 4, 5 kg / cm.

  As shown in FIG. 4, in a floating seal using a seal ring material (old material) having a Rockwell hardness HRC of about 65 to 67, the sliding resistance torque does not increase so much even if the linear pressure of the floating seal is increased. . Further, even if a roundness having a radius of curvature R of 0.2 mm is formed on the outer peripheral edge portion of the seal surface of the seal ring, the sliding resistance torque does not change much.

  On the other hand, in a floating seal using a seal ring material (new material) having a Rockwell hardness HRC of about 54 to 62, when the linear pressure of the floating seal is increased, the sliding resistance torque is greatly increased. Therefore, if a roundness having a radius of curvature R of 0.2 mm is formed on the outer peripheral edge portion of the seal surface of the seal ring, an increase in the sliding resistance torque is suppressed, and the linear pressure of the floating seal is in a range of 3 kg / cm or less. If so, results comparable to those obtained with a floating seal using a conventional seal ring material were obtained. In addition, the maximum linear pressure usually used is 2.4 kg / cm.

FIG. 5 is a diagram showing a result of obtaining the contact stress by simulation when the curvature radius R and the linear pressure are changed when the Young's modulus of the seal ring material is 190 GPa. Here, when the radius of curvature R is 0.2 mm, the sliding torque test result is good when the linear pressure of the floating seal is 3 kg / cm, and the linear pressure of the floating seal is 4 kg / cm. The sliding resistance torque increased. Therefore, between the contact stress of 63.8 kg / mm ² when the linear pressure of the floating seal is 3 kg / cm ² and the contact stress of 69.8 kg / mm ² when the linear pressure of the floating seal is 4 kg / cm ² , It is believed that there is a maximum allowable contact stress value.

FIG. 6 is a diagram showing a change in contact stress with respect to the radius of curvature R when the Young's modulus of the seal ring material is 190 GPa. The five solid lines are approximated by an exponential function of the contact stress when the line pressure of the floating seal is changed to 1, 2, 3, 4, 5 kg / cm as a parameter. The curve is an approximation of an exponential function of the contact stress at the maximum linear pressure of 2.4 kg / cm that is normally used. The value of the radius of curvature R at a position where the dashed curve intersects with a straight line representing a maximum allowable contact stress of 63.8 kg / mm ^{2 to} 69.8 kg / mm ² (a straight line parallel to the horizontal axis) is 0.08 mm to 0. .14 mm.

FIG. 7 is a diagram illustrating a result of obtaining the contact stress by simulation when the curvature radius R and the linear pressure are changed when the Young's modulus of the seal ring material is 205 GPa. Here, when the radius of curvature R is 0.2 mm, the sliding torque test result is good when the linear pressure of the floating seal is 3 kg / cm, and the linear pressure of the floating seal is 4 kg / cm. The sliding resistance torque increased. Therefore, between the contact stress of 67.5 kg / mm ² when the linear pressure of the floating seal is 3 kg / cm ² and the contact stress of 73.2 kg / mm ² when the linear pressure of the floating seal is 4 kg / cm ² , It is believed that there is a maximum allowable contact stress value.

FIG. 8 is a diagram showing a change in contact stress with respect to the radius of curvature R when the Young's modulus of the seal ring material is 205 GPa. The five solid lines are approximated by an exponential function of the contact stress when the line pressure of the floating seal is changed to 1, 2, 3, 4, 5 kg / cm as a parameter. The curve is an approximation of an exponential function of the contact stress at the maximum linear pressure of 2.4 kg / cm that is normally used. The dashed curve is the value of the radius of curvature R at the position intersecting the straight line (a straight line parallel to the horizontal axis) representing the maximum allowable contact stress 67.5kg ^/ mm ² ~73.2kg ^/ mm 2 is, 0.08Mm～0 .14 mm.

FIG. 9 is a diagram showing a result of obtaining a contact stress by simulation when the radius of curvature R and the linear pressure are changed when the Young's modulus of the seal ring material is 220 GPa. Here, when the radius of curvature R is 0.2 mm, the sliding torque test result is good when the linear pressure of the floating seal is 3 kg / cm, and the linear pressure of the floating seal is 4 kg / cm. The sliding resistance torque increased. Therefore, between the contact stress of 70.2 kg / mm ² when the linear pressure of the floating seal is 3 kg / cm ² and the contact stress of 76.1 kg / mm ² when the linear pressure of the floating seal is 4 kg / cm ² , It is believed that there is a maximum allowable contact stress value.

FIG. 10 is a diagram showing a change in contact stress with respect to the radius of curvature R when the Young's modulus of the seal ring material is 220 GPa. The five solid lines are approximated by an exponential function of the contact stress when the line pressure of the floating seal is changed to 1, 2, 3, 4, 5 kg / cm as a parameter. The curve is an approximation of an exponential function of the contact stress at the maximum linear pressure of 2.4 kg / cm that is normally used. The dashed curve is the value of the radius of curvature R at the position intersecting the straight line (a straight line parallel to the horizontal axis) representing the maximum allowable contact stress 70.2kg ^/ mm ² ~76.1kg ^/ mm 2 is, 0.08Mm～0 .14 mm.

  From the above, at least when the Young's modulus of the seal ring material is 190 GPa to 220 GPa, an intermediate value between 0.08 mm and 0.14 mm (addition average value) at a normally used maximum linear pressure of 2.4 kg / cm. ) 0.11 mm is the minimum value of the radius of curvature R so as not to increase the sliding resistance torque at the normally used maximum linear pressure of 2.4 kg / cm.

  As described above, by forming a round having a predetermined radius of curvature R at the outer peripheral edge portion of the seal surface of the seal ring, the initial sliding resistance torque is reduced, and the heat generation of the seal ring is suppressed, The possibility of breakage of the seal ring due to thermal embrittlement can be reduced. Moreover, since the margin of the sliding resistance torque with respect to the holding torque of the O-ring increases, the risk of accompanying the O-ring can be reduced. By holding the O-ring firmly, oil leakage from the O-ring surface is prevented, and the risk of breakage accompanied by thermal expansion due to frictional heat generated by sliding of the O-ring is reduced. Further, since the contact surface of the seal ring can be formed widely and on the inner peripheral side, a change in the contact surface due to dimensional tolerance and a margin for an external load are dramatically improved.

  INDUSTRIAL APPLICABILITY The present invention can be used in a floating seal for preventing muddy water, earth and sand, etc. from entering the interior and preventing lubricating oil from leaking from the inside in a rotating mechanism section of a construction machine or the like. is there.

It is a fragmentary sectional view showing the floating seal concerning one embodiment of the present invention. It is a fragmentary sectional view which shows the seal ring in the floating seal which concerns on the 1st Embodiment of this invention. It is sectional drawing which expands and shows a part of one seal ring. It is a figure which shows the relationship between the linear pressure and the sliding resistance torque of a floating seal in various floating seals. It is a figure which shows the result of having calculated | required the contact stress by changing a curvature radius R and a linear pressure in case the Young's modulus of a seal ring material is 190 GPa. It is a figure which shows the change of the contact stress with respect to the curvature radius R, when the Young's modulus of a seal ring material is 190 GPa. When the Young's modulus of a seal ring material is 205 GPa, it is a figure which shows the result of having calculated | required the contact stress by changing a curvature radius R and a linear pressure by simulation. It is a figure which shows the change of the contact stress with respect to the curvature radius R, when the Young's modulus of a seal ring material is 205 GPa. When the Young's modulus of a seal ring material is 220 GPa, it is a figure which shows the result of having calculated | required the contact stress by changing a curvature radius R and a linear pressure by simulation. It is a figure which shows the change of the contact stress with respect to the curvature radius R, when the Young's modulus of a seal ring material is 220 GPa. It is a fragmentary sectional view showing the conventional floating seal. It is a fragmentary sectional view which shows the seal ring in the floating seal which made the width | variety of a sliding surface wide.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Floating seal, 2 ... Shaft, 3, 4 ... Boss, 3a, 4a ... Housing part, 5, 6 ... Seal ring, 6a ... Seal surface, 6b ... Tapered surface, 7, 8 ... O-ring, 9 ... Sliding surface

Claims (3)

A pair of housing portions each formed with two members for relative rotational movement about an axis;
A pair of seal rings disposed within the pair of housing portions and in sliding contact with each other on a part of the opposing surfaces;
A pair of O-rings sandwiched between the pair of housing portions and the pair of seal rings,
A floating seal comprising
The facing surface of each seal ring has a seal surface having a first angle with respect to the surface orthogonal to the axis, and is adjacent to the inner peripheral side of the seal surface and is orthogonal to the surface orthogonal to the axis. A taper surface having a second angle larger than the first angle, the seal surface width being A, the seal surface width tolerance being ΔA, and the seal ring diameter tolerance being ΔD. The round seal having a radius of curvature of 0.11 mm or more and (A−ΔA−ΔD−0.2 mm) or less is formed at the outer peripheral edge portion of the seal surface.   The floating seal according to claim 1, wherein the pair of seal rings is formed using a material having a Rockwell hardness of HRC54 to 62.   The floating seal according to claim 1 or 2, wherein the pair of seal rings is formed using a material having a Young's modulus of 190 GPa to 220 GPa.