KR20090001518U - Oil damper for toilet bowl - Google Patents

Abstract

The present invention relates to an oil damper for toilet bowl, and more particularly, a rotation shaft formed with a first projection in a direction crossing the rotation axis; A housing having one side of the rotating shaft inserted therein to gradually rotate the rotating shaft and having a first coupling part formed at a side thereof; A groove having a first through hole through which the other side of the rotating shaft penetrates is formed in a center thereof, and a groove into which the first protrusion is inserted is formed at an outer circumference of the first through hole to rotate along the rotation of the rotating shaft, and is formed in the other direction of the rotating shaft. The first locking unit having a first protrusion; A second through hole through which the other side of the rotating shaft penetrates in the center, a second coupling part coupled to the first coupling part and supported by the housing, and the first protrusion is caught by the rotation of the first locking unit; A second locking unit having a second protrusion protruding in one direction of the rotation shaft to be supported; A third through hole through which the other side of the rotating shaft penetrates is formed, and a third coupling portion is formed on a side surface thereof to be coupled to the second coupling portion, and the first locking unit and the second locking unit are positioned between the housing. It includes a cover to let. Accordingly, the present invention is installed in the lid on the toilet bowl is the axis of rotation when the lid is rotated by the external pressure, the rotating shaft is rotated by the first locking unit and the second locking unit to maintain the state of the lid upright It provides an oil damper for toilet bowl to maintain the.

Description

Oil damper for toilet bowl {OIL DAMPER FOR TOILET BOWL}

The present invention relates to an oil damper for toilet bowl, and more particularly, the rotating shaft installed in the lid on the toilet bowl and rotated by the first locking unit and the second locking unit when the lid is rotated by external pressure It relates to an oil damper for toilet bowl to maintain the lid to maintain the upright state.

Originally, dampers are also referred to as oil dampers and shock absorbers, and are devices that absorb external pressure applied by using frictional resistance of oil and hydraulic pressure of oil.

In particular, recently, the oil damper is widely installed in the shaft part for rotating the left side of the toilet seat and the seat of the toilet seat, the shaft part for rotating the door, and the like. It is used.

In this case, when the toilet bowl, the lid of the toilet bowl is rotated downward by gravity, the user often can not see the toilet comfortably occurred. Therefore, since the lid must be upright, a damper for uprighting the lid of the toilet is required.

Therefore, the present invention has been devised to solve the above-mentioned problems, the rotating shaft is installed on the lid on the toilet bowl and rotated to become the axis when the lid is rotated by the external pressure by the first locking unit and the second locking unit It is an object of the present invention to provide an oil damper for a toilet to maintain a state in which the lid is upright.

The object is a rotation shaft formed with a first projection in a direction intersecting the rotation axis according to the present invention; A housing having one side of the rotating shaft inserted therein to gradually rotate the rotating shaft and having a first coupling part formed at a side thereof; A groove having a first through hole through which the other side of the rotating shaft penetrates is formed in a center thereof, and a groove into which the first protrusion is inserted is formed at an outer circumference of the first through hole to rotate along the rotation of the rotating shaft, and is formed in the other direction of the rotating shaft. The first locking unit having a first protrusion; A second through hole through which the other side of the rotating shaft penetrates in the center, a second coupling part coupled to the first coupling part and supported by the housing, and the first protrusion is caught by the rotation of the first locking unit; A second locking unit having a second protrusion protruding in one direction of the rotation shaft to be supported; A third through hole through which the other side of the rotating shaft penetrates is formed, and a third coupling portion is formed on a side surface thereof to be coupled to the second coupling portion, and the first locking unit and the second locking unit are positioned between the housing. It is achieved by the oil damper for toilet bowl, characterized in that it comprises a cover.

Here, the first catching unit and the second catching unit may be made of a spring steel material.

Here, the first protrusion and the first inclined surface; A third inclined surface having a second inclined surface having a steeper inclination angle than that of the first inclined surface, wherein the second protrusion is in contact with the first inclined surface by sliding in one direction of the first locking unit; The inclination angle is sharper than that of the third inclined surface, and the fourth inclined surface may have a fourth inclined surface that prevents rotation of the first locking unit in another direction when it is in contact with the second inclined surface.

Here, the rotating shaft includes a first orifice portion for gradually rotating the rotating shaft in the one direction from the first protrusion; A groove is formed between the first orifice portion and the first protrusion to protrude in a direction crossing the rotation axis and extends in the rotation axis direction so as to discharge air in the housing to the outside when inserted into the housing. A first closure formed in the; A first o-ring surrounding the outer circumference of the first closure part, the housing including: a first seal closed by the first closure part and filled with oil in a state where the first buffer part of the rotary shaft is inserted; It may include a first incremental unit is inserted into the first seal, the first orifice portion by the rotation of the rotary shaft is coupled to move and coupled to inhibit the flow of the oil to gradually rotate the rotary shaft.

Here, one side and the sub-rotation shaft formed with a second orifice portion for gradually rotating the one side; And a sub cover having a second closure portion having a groove formed on an outer circumference and a second o-ring surrounding the outer circumference of the second closure portion, wherein the rotation shaft has a center penetrating in the direction of the rotation shaft to penetrate one side of the sub rotation shaft. And a fourth through hole, wherein the housing divides an inner space so that one surface thereof forms the first seal facing the first closure portion, and a center penetrates and communicates with the fourth through hole of the rotating shaft. A partition having a fifth through hole through which one side of the rotating shaft penetrates; A second seal which is positioned between the other surface of the partition and the second closing portion and the second orifice portion of the sub-rotation shaft is filled with oil; It may further include a second incremental unit inserted into the second seal, the second orifice portion by the rotation of the rotary shaft is coupled to move and combine to suppress the flow of the oil to gradually rotate the sub-rotary shaft. .

Here, the sub-rotation shaft may further include a torsion preventing pin which is installed in the extension direction of the sub-rotation shaft inside the sub-rotation shaft.

By the above configuration, the present invention enables the rotating shaft rotated by the external pressure to maintain the rotated state by the first catching unit and the second catching unit, so that the lid of the toilet bowl, bidet, etc. can be kept in a standing state, so that the user There is an excellent effect to perform bowel movements in a more pleasant environment.

In addition, since the first catching unit and the second catching unit according to the present invention are made of a screw steel material, the first catching unit and the second catching unit are not easily worn by frequent lid rotation, so that the bidet can be used for a long time. do.

In addition, the present invention has an excellent effect that can be produced more simply by forming an air discharge gap when forming the first chamber and the second chamber filled with oil during the manufacturing process.

Prior to the description, the object to which the oil damper for toilet according to the present invention (hereinafter referred to as "damper 1") is applied is an example of a toilet and a bidet. Of course, dampers can be applied.

Therefore, the left side (Y) and the lid (Z) covering the left side of the toilet seat, bidet (W), such as shown in Figure 20 is seated around the rotation axis (X), the damper according to the present invention (1) is provided on the rotating shaft (X) can rotate the left side portion (Y) and the lid (Z). Accordingly, the lid Z is called a first object, and the left side portion Y is called a second object.

In addition, since the use of a recently developed bidet instead of a toilet is multi-reflective, the bidet in the present invention is to say that the word is a collective term for a mechanism for sitting toilets such as toilet and bidet.

Hereinafter, the damper 1 according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 to 3, the damper 1 according to the present invention is the rotary shaft 100, the cover 500, the housing 200, the sub-rotary shaft 600, the sub-cover 700, The first locking unit 300 and the second locking unit 400 are included.

As shown in FIGS. 3 and 4, the rotary shaft 100 includes a first protrusion 110, a first closure 130, a first O-ring 10, and a first orifice portion 120. An end portion 101 is formed on one side and rotates based on the rotation axis X to which the first object is to rotate.

The first protrusion 110 is formed to protrude in a direction crossing the rotation axis (X). The first protrusion 110 is inserted into the groove 320 of the first locking unit 300 to be described later.

The first closing portion 130 is formed to protrude in a direction crossing the rotation axis (X) and is formed with an O-ring groove 11 into which the first O-ring 10 can be inserted. Accordingly, the first closing part 130 is inserted into the housing 200 to be described later and positioned to face the partition wall 230 to form a first chamber A to be described later.

As shown in FIG. 4, the first orifice portion 120 protrudes from the rotary shaft 100 in a direction crossing the rotary shaft X, and provides a movement path of oil filled in the first seal A. FIG. The first recess 121 is formed. The first recess 121 is one end of the first orifice portion 120 is stepped.

Thus, the first orifice portion 120 is located inside the first chamber A. In addition, the oil filled with the first seal A together with the recess 221 and the penetrating portion 222 of the first incrementing unit 220 of the housing 200, which will be described later, by the first recess 121. The moving passage of the oil is formed, but the moving passage of the oil is opened / closed by the rotation of the rotary shaft 100. Here, the flow rate of the oil is reduced in the process of closing the moving passage of the oil which has been opened, which results in the gradual rotation of the rotary shaft stage (100). This will be described later.

As shown in FIG. 3 and FIG. 4, the first closing part 130 is provided with a groove 131 having the same extension direction as that of the rotation axis X.

As shown in FIG. 18, the groove 131 allows the first closure 130 of the rotation shaft 100 to be smoothly inserted into the housing 200. Here, although the shape of the first closure 130 and the housing 200 shown in FIG. 18 is different from that of the first closure 130 and the housing 200 shown in other drawings, this is the groove of the present invention. The first closure 130 and the housing 200 are briefly illustrated in order to facilitate understanding of the function of 131.

For example, when there is no groove 131, when forming the first seal A as shown in FIG. 18A, the first O-ring surrounded by the interior of the housing 200 and the first closure 130 is provided. Air is compressed by the (10) is not inserted smoothly is a lot of difficulties in the manufacturing process.

Therefore, if there is a groove 131, as shown in FIG. 18B, the first closure 130 may be inserted into the housing 200 while inserting the rod 12 into the groove 131. Here, the diameter of the rod 12 is provided to be smaller than the diameter of the groove 131.

Then, as illustrated in FIGS. 18C and 19, the rod 131 presses the first O-ring 10 surrounded by the first closure 130 to maintain the groove 131. Here, the air discharge gap 13 is formed by the groove 131 and the rod 12. As the first closure 130 is inserted into the housing 200, air is discharged to the outside through the air discharge gap 13. Then, when the first closing portion 130 of the rotary shaft 100 is inserted, the rod 12 is removed as shown in FIG. Then, since the pressurization of the first O-ring 10 by the rod 12 is released and the air discharge gap 13 is closed, the first seal A filled with the oil F can be formed.

In addition, as shown in Figure 3, the rotating shaft 100 according to the present invention has a fourth through hole 140. The fourth through hole 140 means that the center of the rotating shaft 100 is penetrated along the rotating shaft (X). Here, the fourth through hole 140 is provided to rotate the second object through the sub rotating shaft 600 to be described later.

As shown in FIGS. 2, 3, 5, and 6, the housing 200 may include a first coupling part 210, a partition wall 230, a first seal A, a second seal B, and a first seal. It includes a progressive unit 220 and the second progressive unit 240.

The first coupling portion 210 has a second coupling portion 420 of the second locking unit 400 to be described later, the third coupling portion 520 of the cover 500 and the fourth coupling portion of the sub-cover 700 ( 720 is screwed. Accordingly, the second locking unit 400, the cover 500, and the sub cover 700 are fixed to the housing 200 without rotating along the rotation of the first object or the second object.

The partition wall 230 is for distinguishing the first chamber A for gradually rotating the rotation shaft 100 of the present invention and the second chamber B for gradually rotating the sub-rotary shaft 600. Prepared.

The partition wall 230 has a fifth through hole 231 communicating with the fourth through hole 140 of the rotation shaft 100. Therefore, the sub rotating shaft 600 may be coupled to the second object through the fifth through hole 231 and the fourth through hole 140.

As shown in FIG. 2, the first seal A is formed by the first closing portion 130 and the partition wall 230 of the rotation shaft 100, and the first orifice portion 120 and the first gradation are formed therein. It means a space in which the unit 220 is inserted.

As shown in FIG. 2, the second seal B is formed by the second closing portion 710 of the subcover 700 and the partition wall 230 of the housing 200, and has a second orifice portion therein. 610 and the space where the second incremental unit 240 is inserted.

Oil is filled inside the first chamber A and the second chamber B. FIG.

The oil filled in the first seal A is not leaked by the first O-ring 10 and the third O-ring 30 shown in FIGS. 2 and 3.

Here, the fixed protrusions 221 and 241 are formed on the inner surface of the housing 200 as shown in FIGS. 5, 6 and 8. The fixed protrusions 221 and 241 support the side surfaces of the rotating shaft 100 so that each of the first first and second incremental units 200 and 240 is positioned one by one, the first seal A and the second. The inside of the yarn B is distinguished. 8 and 9, the oil protrusion 221a is formed in the fixed protrusion 221. The oil groove 221a allows only a small amount of oil to flow between the internal spaces of the first seal A separated by the fixed protrusion 221. Of course, an oil groove (not shown) is formed in the fixed protrusion 241 to perform the same function as the oil groove 221a.

As shown in FIG. 7, the first incremental unit 220 has a depression 221 and a through part 222. The second incremental unit 240 has the same shape as the first incremental unit 220 shown in FIG. 7.

Therefore, as shown in FIG. 8, when the rotating shaft 100 rotates in the counterclockwise direction in the drawing due to the rotation of the first object, the first orifice portion 120 opens the inside of the semi-circular first seal A. FIG. Move along.

At this time, the oil flows through the moving passage of the oil formed by the first recess 121 of the first orifice portion 120, the depression 221 and the penetrating portion 222 of the first progressive unit 220. (P)

However, the diameter of the oil passage is gradually reduced in the process of almost closing the oil passage as the movement of the first orifice portion 120 continues, thereby decreasing the amount of oil flowing therethrough. .

This decreases the moving speed of the first orifice portion 120, which in turn causes the rotation speed of the rotation shaft 100 to be reduced, thereby gradually rotating the rotation shaft 100.

As a result, as shown in FIG. 9, as the oil passage is closed, the oil cannot flow (Q). Here, a small amount of oil must be discharged in order for the movement passage of the oil to be closed. This is solved by discharging a small amount of oil through the oil groove 221a formed in the fixed protrusion 221 shown in FIG. 9 to the lower portion of the drawing of the first seal A divided by the fixed protrusions 221 and 241.

In conclusion, the process results in the rotational speed of the rotating shaft 100 is reduced to gradually rotate.

  The second orifice part 610 also includes a second recessed part 611, and the above process is performed by the second gradation unit 240 inserted into the second chamber B. As a result, the rotation speed of the sub rotating shaft 600 is reduced to gradually rotate.

As shown in FIGS. 10 and 11, the first locking unit 300 has a first through hole 310. The first through hole 310 penetrates the other side of the rotation shaft 100. A groove 320 is formed on the outer circumference of the first through hole 310. The groove 320 is provided to insert the first protrusion 110 of the rotation shaft 100. Thus, as the rotary shaft 100 rotates, the first locking unit 300 also rotates.

The first locking unit 300 has a first protrusion 330 is formed. The first protrusion 330 is provided to be in contact with the second protrusion 430 of the second locking unit 400 to be described later. As shown in FIGS. 10 and 11, a first inclined surface 331 and a second inclined surface 332 are formed on the first protrusion 330.

As shown in FIG. 11, the inclination angle of the second inclined surface 332 is sharper than that of the first inclined surface 331.

12 and 13, the second locking unit 400 has a second through hole 410. The other side of the rotation shaft penetrates the second through hole 410. In addition, a second coupling part 420 is formed on the side of the second locking unit 400 to be coupled to the first coupling part 210 of the housing 200. Thus, when the housing 200 is fixed, the second locking unit 400 is also fixed.

 The second locking unit 400 has a second protrusion 430 protruding toward one side of the rotating shaft 100 when it is coupled to the housing 200. Accordingly, the first protrusion 330 and the second protrusion 430 protrude in opposite directions.

 12 and 13, a third inclined surface 431 and a fourth inclined surface 432 are formed in the second protrusion 430.

The third inclined surface 431 slides in contact with the first inclined surface 331 of the first protrusion 330 of the first locking unit 300 which rotates in one direction along the rotation shaft 100.

The fourth inclined surface 432 has a steeper slope than the third inclined surface 431. Thus, after the first inclined surface 331 of the first protrusion 330 rotated in one direction is released from the third inclined surface 431, and then rotated in another direction by external pressure, the second inclined surface 332 of the first protrusion 330. ) Contacts the fourth inclined surface 432 of the second protrusion 430. At this time, both the second inclined surface 332 and the fourth inclined surface 432 have a steeper slope than the first inclined surface 331 and the third inclined surface 431. Accordingly, when the second inclined surface 332 contacts the fourth inclined surface 432 while rotating in the other direction, the first inclined surface 331 slides the third inclined surface 431. Even if external pressure is applied, the first protrusion 330 does not rotate in the other direction.

That is, as an example, it is assumed that the bidet W and the lid Z are rotated as shown in FIG. 20 by the rotation shaft 100. When rotating in one direction to open the lid (Z), the first inclined surface 331 of the first protrusion 330 is in sliding contact with the third inclined surface 431 of the second protrusion 430. In addition, the opened lid Z is rotated in the other direction by gravity, which is the aforementioned external pressure, to be closed, but the second inclined surface 332 of the first protrusion 330 is the fourth inclined surface of the second protrusion 430 ( In contact with 432 the lid Z remains open without being closed.

Here, when the user presses the rotating shaft 100 to rotate in the other direction to close the lid, the first catching unit 300 is bent in a direction opposite to the direction in which the first protrusion 330 protrudes by the user's pressing. The second locking unit 400 and the second inclined surface 332 are released from the fourth inclined surface 432.

Here, the first catching unit 300 and the second catching unit 400 may be made of a spring steel material. Accordingly, since the first locking unit 300 and the second locking unit 400 have elasticity, the first locking unit 300 may be easily bent in a direction opposite to the direction in which the first protrusion 330 protrudes. The second locking unit 400 may be easily bent in a direction opposite to the direction in which the second protrusion 430 protrudes. As a result, contact / release of the contact between the first inclined surface 331 and the third inclined surface 431 and contact / disengagement between the second inclined surface 332 and the fourth inclined surface 432 may be easier.

In addition, when the first catching unit 300 and the second catching unit 400 are provided with a spring steel material, the first catching unit 300 and the second catching unit 400 may be easily bent by elastic deformation. , The first inclined surface 331 and the second inclined surface by contact / disengagement between the first inclined surface 331 and the third inclined surface 431 and contact / disengagement between the second inclined surface 332 and the fourth inclined surface 432. The 332, the third inclined surface 431, and the fourth inclined surface 432 are not easily worn.

As shown in FIG. 14, the cover 500 has a third through hole 510 through which the other side of the rotating shaft 100 penetrates in the center thereof, and the first coupling part 210 of the housing 200 is formed at both sides thereof. ) And a third coupling part 520 which is screwed with the second coupling part 420 of the second locking unit 400.

Thus, the first locking unit 300 and the second locking unit 400 are positioned between the cover 500 and the housing 200.

In addition, the damper 1 according to the present invention may further include a sub-rotation shaft 600 and a sub-cover 700 that can rotate the first object and the second object with one rotation axis (X).

As shown in FIG. 15, a second orifice portion 610 is formed at one side of the sub-rotation shaft 600 and inserted into the second seal B of the housing 200. In addition, the other side of the sub rotating shaft 600 passes through the fourth through hole 140 of the rotating shaft and the fifth through hole 231 of the partition wall 230 of the housing 200. In addition, a step portion 601 is formed at one side of the sub rotating shaft 600 to be coupled to the second object. In addition, an O-ring groove 41 to which the fourth O-ring 40 is coupled to prevent the oil of the second seal B from leaking is formed.

In addition, as shown in FIG. 16, the sub rotating shaft 600 may further include a torsion preventing pin 602. The torsion preventing pin 602 is inserted into the extension direction of the sub-rotary shaft 600 inside the sub-rotary shaft 600. The torsion preventing pin 602 may be provided as a square pin, a hexagonal pin, an octagonal pin, or a pin with a knurl formed on the surface thereof. Accordingly, the torsion preventing pin 602 provides rigidity against the torsion to the sub-rotation shaft 600, so that the second orifice portion 610 is rotated by the stepped portion 601 of the sub-rotation shaft 600 rotates. When the sub-rotation shaft 600 is damaged by the torsional force applied to the sub-rotation shaft 600 can be prevented.

A configuration in which the second orifice portion 610 gradually rotates the sub-rotation shaft 600 together with the second progressive unit 240 in the second chamber B may include the first orifice portion 120 in the first chamber A. FIG. ) Is the same as the configuration to gradually rotate by the first incremental unit 220, description thereof will be omitted.

As shown in FIG. 17, the subcover 700 includes a second closure portion 710 and a fourth coupling portion 720.

The second closing part 710 is inserted into the housing 200 and forms a second seal B together with the partition wall 230 of the housing 200, and an O-ring groove 21 is formed on the outer circumference thereof to form a second O-ring ( 20) is inserted.

As shown in FIG. 2, the second O-ring 20, together with the fourth O-ring 40 inserted into the O-ring groove 41, prevents oil in the second seal B from leaking.

Grooves 711 are formed in the second closure portion 710.

The groove 711 of the second closure part 710 may include the subcover 700 so that the groove 711a and the groove 711a formed on the outer circumference of the second closure part 710 extend to the outer surface of the subcover 700. It is provided with a groove 711b formed in the body.

The groove 711 is the same as the function of the groove 131 formed in the first closing portion 130 of the rotating shaft 100, the description thereof will be omitted.

The fourth coupling part 720 is screwed to the first coupling part 210 of the housing 200. Thus, the second orifice portion 610 formed on one side of the sub-rotation shaft 600 is located in the second chamber (B).

Accordingly, when the damper 1 according to the present invention is used for the lid Z of the bidet W, the user rotates the lid Z and rotates the rotary shaft by rotating the lid Z when viewing the toilet. The table 100 may maintain a state in which the table 100 is rotated by the first locking unit 300 and the second locking unit 400. Thus, conventionally, the lid (Z) is often lowered by gravity to prevent the user's bowel movements to prevent the bowel movements in a more comfortable environment.

In addition, the present invention is because the first locking unit 300 and the second locking unit 400 is provided with a screw steel material, the first locking unit 300 and the second locking unit 400 by frequent lid (Z) rotation. ) Does not wear easily, allowing the bidet (W) to be used for a long time.

 In addition, the present invention forms an air discharge gap 13 when forming the first chamber (A) and the second chamber (B) filled with oil during the manufacturing process, the damper (1) according to the present invention more simply ) Has an excellent effect of manufacturing.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that the present invention may be modified without departing from the spirit or principles of the present invention. . The scope of the invention will be defined by the appended claims and their equivalents.

1 is a perspective view of an oil damper for a toilet according to the present invention,

2 is a cross-sectional view of the oil damper for toilet according to the present invention,

3 is an exploded perspective view of an oil damper for a toilet according to the present invention,

Figure 4 is a side view of the rotary shaft of the oil damper for toilet according to the present invention,

5 is a front view of the housing of the oil damper for toilet according to the present invention,

Figure 6 is a rear perspective view of the housing of the oil damper for toilet according to the present invention,

7 is a perspective view of a first incremental unit of the oil damper for toilet according to the present invention,

8 and 9 are views showing a state in which the rotary shaft of the oil damper for the toilet according to the present invention is gradually rotated,

10 is a plan view of the first locking unit of the oil damper for toilet according to the present invention,

11 is a side view of the first locking unit of the oil damper for toilet according to the present invention,

12 is a plan view of the second locking unit of the oil damper for toilet according to the present invention,

13 is a side view of the second locking unit of the oil damper for toilet according to the present invention,

14 is a perspective view of a cover of an oil damper for a toilet according to the present invention;

15 is a side view of the sub-rotation shaft of the oil damper for toilet according to the present invention,

16 is a cross-sectional view of FIG. 15,

17 is a perspective view of a sub cover of an oil damper for a toilet according to the present invention;

18 (A) to (D) is a view showing the formation of the air discharge gap when manufacturing the toilet oil damper according to the present invention,

19 is a view showing the formation of an air discharge gap in FIG.

20 is a perspective view of a toilet equipped with an oil damper for toilet according to the present invention.

<Description of Major Numbers in Drawing>

1: Oil damper for toilet bowl 100: Rotating shaft

200: housing 220: first incremental unit

240: second incremental unit 300: first locking unit

400: second locking unit 500: cover

600: sub rotating shaft 700: sub cover

Claims (6)

A rotation shaft formed with a first protrusion in a direction crossing the rotation shaft; A housing having one side of the rotating shaft inserted therein to gradually rotate the rotating shaft and having a first coupling part formed at a side thereof; A groove having a first through hole through which the other side of the rotating shaft penetrates is formed in a center thereof, and a groove into which the first protrusion is inserted is formed at an outer circumference of the first through hole to rotate along the rotation of the rotating shaft, and is formed in the other direction of the rotating shaft. The first locking unit having a first protrusion; A second through hole through which the other side of the rotating shaft penetrates in the center, a second coupling part coupled to the first coupling part and supported by the housing, and the first protrusion is caught by the rotation of the first locking unit; A second locking unit having a second protrusion protruding in one direction of the rotation shaft to be supported; A third through hole through which the other side of the rotating shaft penetrates is formed, and a third coupling portion is formed on a side surface thereof to be coupled to the second coupling portion, and the first locking unit and the second locking unit are positioned between the housing. Oil damper for toilet bowl, characterized in that it comprises a cover. The method of claim 1, The first locking unit and the second locking unit is an oil damper for a toilet, characterized in that provided with a metallic material having elasticity. The method of claim 2, The first protrusion is A first inclined surface; The second inclined surface has a steeper angle of inclination than the first inclined surface, The second protrusion is A third inclined surface sliding in contact with the first inclined surface by one direction rotation of the first locking unit; An oil damper for a toilet according to claim 3, wherein the inclination angle is sharper than that of the third inclined surface, and the fourth inclined surface prevents rotation of the first locking unit in another direction when the inclined angle is in contact with the second inclined surface. The method according to any one of claims 1 to 3, The rotating shaft is A first orifice portion for gradually rotating the rotation shaft in the one direction from the first protrusion; A groove is formed between the first orifice portion and the first protrusion to protrude in a direction crossing the rotation axis and extends in the rotation axis direction so as to discharge air in the housing to the outside when inserted into the housing. A first closed portion formed in the; A first o-ring surrounding the outer periphery of the first closure, The housing is A first seal which is closed by the first closing part in a state where the first buffer part of the rotary shaft is inserted and filled with oil therein; And a first gradation unit inserted into the first seal, the first orifice portion being moved and coupled by the rotation of the rotary shaft to suppress the flow of the oil to gradually rotate the rotary shaft. Oil damper for toilet bowl. The method of claim 4, wherein A sub-rotation shaft having a second orifice portion formed on one side to gradually rotate the one side; And a subcover having a second closure formed with a groove in the outer circumference and a second O-ring surrounding the outer circumference of the second closure. The rotating shaft is A center penetrating in the direction of the rotation axis and including a fourth through hole through which one side of the sub-rotation shaft passes; The housing is The fifth through-hole is formed by dividing the inner space to form the first seal facing the first closure portion, the center penetrates and communicates with the fourth through-hole of the rotating shaft to penetrate one side of the sub-rotary shaft. A partition wall; A second seal which is positioned between the other surface of the partition and the second closing portion and the second orifice portion of the sub-rotation shaft is filled with oil; And a second gradation unit inserted into the second seal, the second orifice portion being moved and coupled by the rotation of the rotary shaft to suppress the flow of the oil to gradually rotate the sub-rotary shaft. Toilet damper for toilet. The method of claim 5, The sub rotating shaft The oil damper further comprises a torsion preventing pin installed in the extension direction of the sub-rotary shaft in the sub-rotary shaft.

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