KR20200117324A - Sealing ring with leaf spring for tolerance range reduction - Google Patents

Abstract

The present invention relates to a sealing ring with a built-in leaf spring for reducing a tolerance range. The sealing ring seals the gap between a shaft and a housing while being inserted into a ring groove of the shaft passing through a shaft passage provided in the housing. The sealing ring comprises: a seal body including a body portion in close contact with a seal support surface in the ring groove, and a lip portion integral with the body portion and in contact with the inner circumferential surface of the shaft passage; and a leaf spring which is accommodated inside the body portion to maintain a state parallel to the seal support surface, and uses a part of the body portion interposed between the seal support surface and the leaf spring as a tolerance thickness portion. In the sealing ring with the built-in leaf spring for reducing the tolerance range according to the present invention, a support ring which maintains a predetermined diameter is formed inside the seal body to minimize tolerance when manufacturing the seal ring, thereby facilitating tolerance management and improving packing performance after assembling.

Description

Sealing ring with leaf spring for tolerance range reduction

The present invention relates to a seal ring, and more particularly, to a seal ring with a built-in plate spring for reducing the tolerance range by minimizing the tolerance range irrespective of the diameter of the seal ring.

Transmission machinery as well as various power equipment used in industrial sites are equipped with transmissions that change speed while passing rotational torque output from a power source. As a typical transmission, there is a gearbox, and a plurality of gears are enclosed with oil in a meshed state inside the housing of the gearbox. The oil is for lubricating the inside of the gearbox, and serves to relieve friction due to rotation of the gear, cool heat, and wash away foreign substances.

However, the oil may leak out of the casing through a gap between the housing and the shaft. The shaft is a transmission shaft that transmits the rotational force of the gear to the outside. Therefore, a sealing ring is necessarily installed between the shaft and the housing to prevent leakage of oil and to block foreign substances from penetrating into the housing.

When the mounted sealing ring does not exhibit its natural performance, the oil inside the casing leaks to the outside, or external fine dust or foreign matter flows into the casing and contaminates the oil. Oil leaking from the casing, for example, flows into the drive and causes electrical and mechanical failure.

1 is a view for explaining the configuration and problems of the conventional sealing ring 15.

As shown, the shaft 13 is mounted in the shaft passage 11 provided in the housing 10, and the sealing ring 15 is fitted in the ring groove 13a of the shaft 13. The ring groove 13a is a groove formed to install the sealing ring 15. In addition, the shaft 13 maintains a state in which its outer circumferential surface 13c is as close as possible to the inner circumferential surface 11a of the shaft passage 11, and is capable of linear movement in the axial direction (arrow a direction).

The sealing ring 15 is molded and manufactured of rubber, and has a packing lip 15a and a clearance groove 15b. In the drawing, the packing lip 15a is a part that separates the upper and lower spaces of the sealing ring 15 to block the movement of, for example, oil or foreign substances, and the target surface, that is, the inner circumferential surface of the shaft passage 11 Pressurize elasticity.

The clearance groove (15b) is a groove formed in the rear of the packing lip (15a) with respect to the inner circumferential surface of the shaft passage (11), it is designed and applied to enable the elastic movement of the packing lip (15a). For example, when the packing lip 15a receives a force in the direction of the arrow F, the packing lip 15a is provided with room for fine movement (while maintaining the packing lip 15a in close contact with the shaft passage 11).

On the other hand, in order for the various shape features applied to the sealing ring 15 to exhibit the best function, the size of the sealing ring itself is more important than anything else. In other words, the sealing ring 15 must have a size capable of tightening the outer peripheral surface of the shaft 13 with an appropriate force.

If the diameter of the sealing ring 15 is larger than the designed dimension, the shaft cannot be stably tightened and the sealing ring may roll out. In addition, on the contrary, when the diameter is too small, the sealing ring 15 itself is easily cut, and the contact area with the inner circumferential surface 11a is small, and the sealing ability is deteriorated.

For this reason, there is a certain allowable tolerance when manufacturing the sealing ring. For example, as shown in Fig. 1, the inner diameter of the sealing ring 15 is slightly reduced to give a tolerance of A.

However, since the tolerance is proportional to the diameter of the sealing ring, the larger the diameter of the sealing ring, the larger the tolerance. In other words, as the diameter increases, the absolute value A shown in FIG. 1 also increases. As the value of A increases, the volume of the sealing ring also increases. Therefore, for example, when the diameter of the seal ring is large and the cross-sectional area in the circumferential direction must be small, sufficient tolerance cannot be added, and it is difficult to secure performance through tolerance management.

Domestic Registration Utility Model Publication No. 20-0419730 (Oil seal for automobile engine) Domestic Patent Publication No. 10-0499798 (Oil Seal)

The present invention was created to solve the above problems, and it is possible to minimize the tolerance during the manufacture of the seal ring so that tolerance management is easy, and the packing performance after assembly is also good to provide a seal ring with a built-in leaf spring for reducing the tolerance range. There is a purpose.

The sealing ring with a leaf spring for reducing the tolerance range of the present invention as a means of solving the problems to achieve the above object is fitted in the ring groove of the shaft passing through the shaft passage provided in the housing, the gap between the shaft and the housing A body part that is in close contact with the sealing support surface in the ring groove, and a lip part which is integral with the body part and has a lip part that contacts the inner circumferential surface of the shaft passage; And a plate spring accommodated in the body portion and maintaining a state parallel to the sealing support surface, and using a part of the body portion interposed between the sealing support surface as a tolerance thickness portion.

In addition, the leaf spring is processed into a ring shape by bending a belt-shaped member having a predetermined width and thickness, and both ends of the leaf spring are in contact with each other inside the body portion.

In addition, a receiving support portion is formed at one end of the leaf spring, and a fitting fixing portion fitted to the receiving support portion is provided at the other end.

In addition, the leaf spring has an uneven portion formed by repeatedly corrugating in the circumferential direction.

In the sealing ring with a plate spring for reducing the tolerance range of the present invention made as described above, a plate spring having a certain size is built into the inside of the sealing body, so that tolerance can be minimized when manufacturing the seal ring, so tolerance management is possible. It is easy and the packing performance is good.

1 is a cross-sectional view showing the structure of a conventional sealing ring.
2 is a view for explaining the configuration of a seal ring with a built-in leaf spring for reducing the tolerance range according to an embodiment of the present invention.
FIG. 3 is a partially cut-away plan sectional view of the sealing ring showing the internal structure of the sealing ring shown in FIG. 2.
FIG. 4 is a diagram separately showing the leaf spring shown in FIG. 3.
5 is a plan view showing another example of a leaf spring that can be applied to a sealing according to an embodiment of the present invention.
6 is a plan view showing another example of a leaf spring that can be applied to a sealing according to an embodiment of the present invention.

Hereinafter, an embodiment according to the present invention will be described in more detail with reference to the accompanying drawings.

Basically, the sealing ring with a leaf spring for reducing the tolerance range of the present invention has a structure in which a ring-shaped leaf spring is embedded in order to reduce the tolerance of the sealing ring itself. The leaf spring is accommodated in the starting body by an insert injection method.

The leaf spring is a rigid body with no compressibility in the thickness direction, has a certain diameter within the starting body, and maintains a fixed spacing with respect to the outer peripheral surface of the surrounding shaft, so only the thickness tolerance of a portion of the starting body surrounding the leaf spring is considered. Because it can be done, tolerance management is simple, and tolerance range can be reduced.

The sealing ring of the present invention includes: a body part in close contact with the sealing support surface in the ring groove, and a starting body having a lip part integrally with the body part and in contact with the inner circumferential surface of the shaft passage; It has a configuration including a leaf spring that is accommodated in the body part and maintains a state parallel to the sealing support surface, and makes a part of the body part interposed between the sealing support surface as a tolerance thickness part.

2 is a view for explaining the configuration of a sealing ring 30 with a built-in leaf spring for reducing the tolerance range according to an embodiment of the present invention.

As shown, the sealing ring 30 according to the present embodiment is composed of a ring-shaped shimpan body 31 molded from rubber and a leaf spring 33 accommodated in the shimpan body 31. The sealing ring 30 is in contact with the inner circumferential surface 11a of the shaft passage (11 in Fig. 1) while being filled in the ring groove 13a separately formed in the shaft 13.

The body part 31 has a body part 31a and a lip part 31b. The lip portion 31b is exposed to the outside of the ring groove 13a and has a packing lip 31c in contact with the inner peripheral surface 11a of the shaft passage. It goes without saying that the packing action is achieved by the packing lip 31c in elastic contact with the inner circumferential surface 11a.

In addition, the body portion 31a contains a leaf spring 33 to be described later, and elastically adheres to the seal support surface 13b, which is the bottom surface of the ring groove 13a. The force to clamp the sealing support surface 13b does not come from the leaf spring 33, but comes from the elasticity of the packing lip 31c itself. The leaf spring 33 only serves as a structure that maintains a constant diameter within the body portion 31a and maintains a gap with respect to the sealing support surface 13b.

In the body portion 31a, a portion interposed between the leaf spring 33 and the sealing support surface 13b is a tolerance thickness portion 31e. The tolerance thickness part 31e is a part whose thickness z is adjusted for tolerance management of the sealing ring 30.

However, as mentioned above, the leaf spring 33 maintains the designed diameter, and the tolerance thickness part 31e only needs to be able to elastically tighten the sealing support surface 13b, so that the tolerance thickness part 31e is thickened. There is no need to design. That is to say, since it only needs to have a thickness enough to wrap the plate spring 33, the thickness of the tolerance thickness portion 31e can be applied as thin as possible. When the thickness z of the tolerance thickness part 31e is thin, it means that the control range of the tolerance is narrow.

For example, when the thickness of the tolerance thickness part 31e is 100mm and 1mm, it is natural that the tolerance width to be adjusted is narrower with 1mm. This is because the smaller the thickness of the tolerance thickness part 31e, the smaller the tolerance range to be adjusted.

In other words, the tolerance range of the sealing ring 30 varies depending on the thickness of the tolerance thickness part 31e interposed between the leaf spring 33 and the sealing support surface 13b, and the thickness of the tolerance thickness part 31e Since can be thin enough, it is possible to reduce the tolerance range.

FIG. 3 is a partially cut-out plan sectional view showing the internal structure of the sealing ring 30 shown in FIG. 2, and FIG. 4 is a view showing the leaf spring 33 shown in FIG. 3 separately.

As shown, the leaf spring 33 is formed by bending a band-shaped member having a certain width and thickness to form a ring, and includes a receiving support part 33b at one end and a fitting fixing part 33a at the other end. Have. It goes without saying that the fitting fixing part 33a is inserted into the receiving support part 33b. The fitting fixing portion 33a maintains a state fitted to the receiving support portion 33b without applying an external force.

The metal member constituting the leaf spring 33 has elasticity. Therefore, when the fitting fixing part 33a is pulled to the outside of the receiving support part 33b for some time, the plate spring 33 is elastically deformed and its diameter is expanded. That is, when a tensile force in the circumferential direction is applied to the sealing ring 30, the fitting fixing portion 33a comes out from the receiving support portion 33b for some time. In addition, when the applied tensile force is removed, the fitting fixing part 33a is elastically restored to the inside of the receiving support part 33b.

The leaf spring 33 having the above configuration is accommodated in the body portion 31a by insert injection method in a state in which the fitting fixing portion 33a is maximally inserted into the receiving support portion 33b.

5 is a plan view showing another example of a leaf spring 33 applicable to a sealing according to an embodiment of the present invention.

The plate spring 33 shown in FIG. 5 is formed in a ring shape by rolling a metal member having a predetermined thickness and width, and the thickness surfaces of the end portions 33c of the plate spring 33 face each other. The end portion 33c maintains a butted state in a state where no external force is applied, and may be spread by applying an external force. The leaf spring 33 having such a structure is also accommodated in the body portion 31a through an insert injection method.

6 is a plan view showing another example of a leaf spring that can be applied to a sealing according to an embodiment of the present invention.

The leaf spring 33 shown in FIG. 6 takes the form of a closed loop and has an uneven portion 33e repeated in the circumferential direction. The uneven portion 33e takes the shape of a wave pattern, so to speak. In addition, the uneven portion 33e is unfolded when a tensile force in the circumferential direction is applied to the plate spring 33 and allows the diameter of the plate spring 33 to be expanded. Of course, when the external force is removed, it is elastically restored to its original state.

The leaf spring 33 of this type is accommodated in the body portion 31a in an insert-injection manner during the manufacture of the starting body 31.

In the above, the present invention has been described in detail through specific embodiments, but the present invention is not limited to the above embodiments, and various modifications are possible by those of ordinary skill in the art within the scope of the technical idea of the present invention.

10: housing 11: shaft passage
11a: Inner peripheral surface 13: axis
13a: ring groove 13b: sealing surface
13c: outer peripheral surface 15: sealing
15a: packing lip 15b: free groove
30: Sealing 31: Poetry Japanese body
31a: body part 31b: lip part
31c: packing lip 31e: tolerance thickness
33: leaf spring 33a: fitting fixing part
33b: receiving support portion 33c: end portion
33e: irregularities

Claims (4)

Sealing the gap between the shaft and the housing while being inserted into the ring groove of the shaft passing through the shaft passage provided in the housing,
A starting body including a body portion in close contact with the sealing surface in the ring groove, and a lip portion integrally with the body portion and in contact with the inner circumferential surface of the shaft passage;
A plate spring is built-in to reduce the tolerance range including a leaf spring that is accommodated inside the body part and maintains a state parallel to the sealing support surface and uses a part of the body part interposed between the sealing support surface as a tolerance thickness part. Sealing. The method of claim 1,
The leaf spring,
A seal ring that is processed into a ring shape by bending a band-shaped member having a certain width and thickness, and the both ends of which have a built-in leaf spring for reducing the tolerance range mutually in contact with the body part. The method of claim 2,
A receiving support part is formed at one end of the leaf spring,
A seal ring with a built-in plate spring for reducing the tolerance range provided with a fitting fixing part fitted to the receiving support part at the other end. The method of claim 2,
The leaf spring,
A seal ring with a built-in leaf spring for reducing the tolerance range with irregularities formed by repeatedly corrugating in the circumferential direction.

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