KR20190002965U - Assembling structure of drainage basin for sink - Google Patents

Abstract

The present invention, when coupling the sink drain to the sink outlet, can be installed (or separated) on the bottom of the bucket quickly and easily while maintaining the direction of the drain overflow inlet pipe in the same direction as the overflow outlet of the sink A drainage container fastening structure for a sink, comprising: a drainage tank disposed below the sump, a fastening ring coupled to the sump through the drainage port above the sump, and a packing ring for maintaining a watertight between the sump and the sump. And a packing ring support part configured to receive and support the packing ring upwardly from an upper end thereof in the drain container, and form a third inner diameter surface inside the packing ring support part, and a third portion below the third inner diameter surface. A second inner diameter surface connected by an inner diameter jaw, and a lower portion of the second inner diameter surface connected by a first inner diameter jaw A first inner diameter surface is formed, and on the second inner diameter surface, a first annular protrusion wall is formed to protrude inwardly in succession to the second inner diameter jaw, and the first annular protrusion wall is vertically open in a direction facing each other. A first opening and a second opening are formed, and on one side of the first opening, a first annular projection wall forms a stop wall extending to the first inner diameter jaw in a vertical direction, and the fastening ring has a bottom end of the drain container. A first outer diameter surface having a diameter larger than the first inner diameter surface and smaller than the second inner diameter surface, and a second outer diameter surface having a diameter smaller than the third inner diameter surface of the sump and having a diameter larger than the first outer diameter surface, When the packing ring is pressed upward, the stop wall is guided by the rotation of the water container in the state entered downward through the first opening and the second opening of the first annular projection wall of the water container. First guide protrusion and second A guide protrusion is formed.

Description

ASSEMBLING STRUCTURE OF DRAINAGE BASIN FOR SINK}

The present invention relates to a sink drainage structure for the sink, and more particularly, in coupling the sink drain to the sink outlet, while maintaining the direction of the drain overflow pipe in the same direction as the overflow outlet of the sink The present invention relates to a sink drainage structure for a sink that can be quickly and easily installed (or detached) at the bottom of a sink.

Conventionally, a sink for a sink is disclosed in JP-A No. 20-2013-0005822.

The sink drain is attached to the lower part of the outlet of the sink basin bottom plate and has a trapping net inside, which not only discharges the water to the sewage pipe through the lower drain pipe, but also overflows the overflow water from the overflow outlet at the top of the sink. After receiving and discharging through the flow inlet pipe, the food waste mixed in the dog water is filtered by the grid and temporarily accommodated until it is removed by the user.

As disclosed in No. 20-2013-0005822, the drain is formed in the lower drain pipe is connected to the drain hose, the overflow inlet is formed in the middle portion is connected to the overflow hose. In installing the drain box in the sink, a female screw is formed on the inner circumferential surface of the tip of the drain box installed under the sink bottom plate, and the female screw and the male screw fastening ring fastened at the top of the sink bottom plate of the sink are separately used. When assembling the sump and male thread fastening ring, the operator first inserts the male thread fastening ring downward from the top of the sink bottom plate through the outlet port. Rotate to engage.

However, such a conventional sink drainage fastening structure has the following problems.

First, when tightening the male threading ring and the sump, a packing is inserted between them to prevent leakage.When the seal is completely sealed to match the sink overflow outlet and the overflow inlet pipe of the sump in the same direction. As a result of stopping the water tank without turning it, there is a problem that water leaks from the sink bottom plate outlet. On the other hand, when tightening the sump by turning the packing until the seal is completely sealed, the overflow direction of the sink overflow outlet and the sump of inflow pipe of the sump is changed, and as a result, when the distance between them becomes large, There is a problem that cannot be used.

In addition, since the male screw fastening ring and the drain container are disposed at the top and the bottom of the sink bottom plate, and the drain box must be screwed together, the assembly time is not only time-consuming but also has a disadvantage in that the operation is difficult.

Korea Utility Model Publication No. 20-2013-0005822 (October 08, 2013)

The present invention is made in order to solve the problems of the conventional sink sink drainage structure described above, the first problem to be solved by the present invention is to direct the direction of the drain overflow pipe in the direction coinciding with the overflow outlet of the sink The present invention provides a sink drainage structure for a sink that can prevent leakage due to a poor packing seal by assembling the packing of the sink outlet tightly while maintaining it.

The second problem to be solved by the present invention is to provide a sink drainage fastening structure that can quickly and easily assemble or separate the sink drain to the sink outlet.

The objects of the present invention described above are composed of a drain container disposed below the water tank, a fastening ring coupled to the water tank through the drain hole above the water tank, and a packing ring for maintaining the watertight between the water tank and the water tank. And a packing ring support part configured to receive and support the packing ring upwardly from an upper end thereof in the drain container, and form a third inner diameter surface inside the packing ring support part, and a second inner diameter below the third inner diameter surface. Forming a second inner diameter surface connected by the jaw, and forming a first inner diameter surface connected to the lower portion of the second inner diameter surface by a first inner diameter jaw, and continuously forming the second inner diameter surface on the second inner diameter surface. A first annular protrusion wall is formed to protrude inward, and the first annular protrusion wall forms a first opening and a second opening, which are open in a vertical direction in a direction facing each other, and a first ring on one side of the first opening. An upper protrusion wall forms a stop wall extending to the first inner diameter jaw in a vertical direction, and the fastening ring has a first outer diameter surface having a diameter larger than a first inner diameter surface of the drain container and smaller than a second inner diameter surface from a lower end thereof. And a second outer diameter surface having a diameter smaller than the third inner diameter surface of the sump and having a diameter larger than the first outer diameter surface, wherein the first ring has a first annular shape when the packing ring is pressed upward. The sink is formed by guiding the rotation of the sump in the state entered downward through the first opening and the second opening of the protruding wall, and then forming a first guide protrusion and a second guide protrusion on the stop wall. It can be solved by the drainage fastening structure.

The above-described problems of the present invention, the second annular projection wall is formed on the third inner diameter surface of the sump, the second annular projection wall is disposed in a direction facing each other at right angles with the first opening and the second opening A third opening and a fourth opening are formed in the up and down direction, and when the packing ring is pressed upward in the second outer diameter surface of the fastening ring, it enters downward through the third opening and the fourth opening. It can be solved more effectively by forming a third guide protrusion and a fourth guide protrusion for guiding the rotation of the sump.

According to the present invention, the packing ring is inserted to protrude upward from the packing ring supporting part of the sump, and the overflow inlet pipe of the fastening ring and the sump is directed to the overflow outlet of the sump (when there are two overflow outlets) or the Adjust it so that it faces in the opposite direction (if there is one overflow outlet), first insert the fastening ring downward through the outlet of the bottom plate of the water bottle, and then hold the water bottle and the guide protrusion of the fastening ring The packing ring is pressed while pushing upward through the formed opening, and while the packing ring is compressed, the drain container is rotated until the first guide protrusion or the second guide protrusion of the fastening ring is caught by the stop wall of the bottle. . The stop wall of the sump is fixed to the first guide projection or the second guide projection of the fastening ring when the sump is rotated approximately 180 degrees, so that the stop wall of the drain tub is the first guide projection or the second guide of the fastening ring. When assembled until the projections are in place, the overflow outlet tube always faces the overflow outlet of the sump when assembled. In addition, the drain box installer only needs to first align the fastening ring and the sump with the overflow inlet pipe toward the uberflow outlet of the sump, and then turn the packing ring into a crimped state. It can be done easily.

Figure 1 is an exploded perspective view showing the disassembled drain and the packing ring and the fastening ring according to the present invention from above.
Figure 2 is an exploded perspective view showing the drain and the packing ring and fastening ring according to the present invention from the bottom.
3 is a plan view of a drain container according to the present invention.
Figure 4 is a bottom view of the fastening ring according to the present invention.
5 is a partially exploded perspective view showing the packing ring coupled to the sump in FIG.
Figure 6 is a partially exploded perspective view showing the lower side of the fastening ring in FIG.
FIG. 7 is a partially exploded perspective view showing the inside of the sump in FIG. 6.
FIG. 8 is a partially exploded perspective view showing the water container and the fastening ring turned 30 degrees counterclockwise in FIG. 5.
FIG. 9 is a partially exploded perspective view showing the water container and the fastening ring turned 90 degrees counterclockwise in FIG. 6.
FIG. 10 is a partially exploded perspective view showing the inside of the sump and the lower portion of the fastening ring in FIG. 9.
11 to 14 is a process chart showing the assembly method of the drain and the fastening ring according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a specific embodiment of the sink for drainage fastening structure according to the present invention.

First, as can be seen with reference to Figure 11, the present invention, the drain through the drain can be disposed below the canister 100, and the top of the canister 100 through the drain in the drain 21 The coupling ring 1 is coupled to, and the packing ring 19 for maintaining the watertight between the sump 21 and the sump.

1 and 11, the water container 21 is formed with a packing ring support 43 for receiving and supporting the packing ring 19 protruding upward from the top. The bottom of the packing ring 19 is recessed in the packing ring insertion groove 45 of the packing ring support 43 and the top of the packing ring 19 is not recessed in the packing ring insertion groove 45. Therefore, when the packing ring 19 is compressed to the bottom surface of the water container 100 in a state in which the packing ring 19 is installed in the water container 21, the packing ring 19 contracts and exerts a repulsive force. A third inner diameter surface 31 is formed inside the packing ring support 43, and a second inner diameter surface 27 is formed below the third inner diameter surface 31 by a second inner diameter jaw 29. The first inner diameter surface 23 is formed below the second inner diameter surface 27 by the first inner diameter jaw 25.

As shown in FIG. 3, the diameter of the third inner diameter surface 31 is larger than the diameter of the second inner diameter surface 27, and the diameter of the second inner diameter surface 27 is larger than the first inner diameter surface 23.

1 and 11, a second inner diameter jaw 29 is formed between the third inner diameter surface 31 and the second inner diameter surface 27, and the second inner diameter surface 27 and the first inner diameter are formed. The first inner diameter 25 is formed between the surfaces 23. First annular projection walls 33a and 33b are formed on the second inner diameter surface 27 to protrude inwardly from the second inner diameter projection 29. The upper surfaces of the first image protrusion walls 33a and 33b may be formed to coincide with the horizontal surface of the second inner diameter jaw 29. Therefore, an annular channel is formed between the first annular projection walls 33a and 33b and the first inner diameter jaw 25. The first annular projection walls 33a and 33b are formed with a first opening 37a and a second opening 37b which are open in the vertical direction in a direction facing each other. The continuity of the first annular projection walls 33a and 33b temporarily disappears at the first opening 37a and the second opening 37b. As a result, the first opening 37a and the second opening 37b are connected to an annular channel formed between the first annular projection walls 33a and 33b and the first inner diameter jaw 25. On one side of the first opening 37a, the first annular projection walls 33a and 33b form a stop wall 35 extending to the first inner diameter jaw 25 in the vertical direction. By the stop wall 35, the annular channel formed between the first annular projection walls 33a and 33b and the first inner bore 25 is blocked. The first opening 37a and the second opening 37b are preferably arranged in the same direction as the overflow inlet pipes 47a and 47b or in a right angle direction.

As shown in FIGS. 2 and 11, the fastening ring 1 has a diameter larger than the first inner diameter surface 23 of the drain container 21 and smaller than the second inner diameter surface 27 from the lower end thereof. A first outer diameter surface 3 and a second outer diameter surface 11 having a diameter smaller than that of the third inner diameter surface 31 of the sump 21 and larger than the first outer diameter surface 3 are formed. Between the first outer diameter surface 3 and the second outer diameter surface 11, a third outer diameter surface 7 larger in diameter than the diameter of the first outer diameter surface 3 and smaller than the diameter of the second outer diameter surface 11 is further added. Can be formed. At this time, a first outer diameter jaw 5 is formed between the first outer diameter surface 3 and the third outer diameter surface 7, and a second outer diameter is between the third outer diameter surface 7 and the second outer diameter surface 11. The jaw 9 is formed.

2 and 4, the first outer diameter surface 3 of the first annular projection wall (33a, 33b) of the sump (21) when the packing ring 19 is pressed upward The first guide protrusion 13a and the first hooking portion which are caught by the stop wall 35 after guiding the rotation of the drain container 21 in a state of entering downward through the first opening 37a and the second opening 37b. The two guide protrusion 13b is formed. The first guide protrusion 13a and the second guide protrusion 13b are disposed to face each other with respect to the center of the fastening ring 1. As shown in the figure, it is preferable that the lower surfaces of the first guide protrusion 13a and the second guide protrusion 13b be formed to coincide with the lower end of the first outer diameter surface 3.

5 to 8, in the structure of the drain container 21 and the fastening ring 1, the first guide protrusion 13a and the second guide protrusion 13b of the fastening ring 1 are drained. After entering the first opening 37a and the second opening 37b of the first annular projection walls 33a and 33b of the cylinder 21, rotating the drain container 21 in one direction (clockwise in Fig. 6). In the other direction (counterclockwise in Fig. 6), the first guide protrusion 13a is caught by the stop wall 35 and does not rotate. In addition, when the water tank 21 is rotated about 180 degrees in one direction, the second guide protrusion 13b is caught by the stop wall 35 and no longer rotates.

As illustrated in FIGS. 1 and 3, second annular protrusion walls 39a and 39b may be formed on the third inner diameter surface 31 of the sump 21. The second annular projection walls 39a and 39b are formed at regular intervals from the second inner jaw 29 and the first annular projection walls 33a and 33b. Thus, another channel is formed between the second annular projection walls 39a and 39b and the second inner bore 29 or the first annular projection walls 33a and 33b. The third annular projection walls 39a and 39b are arranged in a direction facing each other at right angles to the first opening 37a and the second opening 37b, and are open in the vertical direction and open in the vertical direction. The opening 41b is formed.

As shown in FIGS. 2 and 4, when the packing ring 19 is pressed upward in the first outer diameter surface 11 of the fastening ring 1, the third opening 41a and the fourth opening ( A third guide protrusion 15a and a fourth guide protrusion 15b are formed to guide the rotation of the water container 21 in a state of entering downward through 41b). The interval between the first guide protrusion 13a and the second guide protrusion 13b of the fastening ring 1 and the third guide protrusion 15a and the fourth guide protrusion 15b is the The distance between the first opening 37a and the second opening 37b and the third opening 41a and the fourth opening 41b is the same.

The opening widths of the third openings 41a and the opening widths of the fourth openings 41b may be different from the widths of the third guide protrusions 15a and the fourth guide protrusions 15b passing through the openings. Although the figure shows the case where two overflow inflow pipes 47a and 47b are formed, when one overflow inflow pipe is formed, the opening width of the 3rd opening 41a, and the 4th opening 41b of By varying the opening width and the width of the third guide protrusion 15a and the fourth guide protrusion 15b, it is possible to direct the direction of the uber flow inlet pipe in a certain direction during installation.

9 to 14 show a coupling method of the fastening ring 1 and the drain container 21 when the overflow outlet of the water tank is disposed in the front-back direction.

When the overflow outlet of the water tank is arranged in the front-rear direction, as shown in FIGS. 9 and 10, the overflow inlet pipe (before or after assembling the fastening ring 1 and the drain container 21) 14a, 14b) should also be arranged in the front-rear direction. However, the first overflow inlet pipe 14a, which faces the front side before assembly, faces the rear side after assembly, and the second overflow inflow tube 14b, which faces the rear side before assembly, faces the front side after assembly.

Hereinafter, a method of fastening the sink for the sink according to the present invention will be described with reference to FIGS. 11 to 14.

As shown in FIG. 11, the fastening ring 1 is inserted into the drain hole of the water tank 100 downwardly from the top of the water outlet 100, and the water tank 21 in the direction of the fastening ring 1 from the bottom of the water tank 100. Push it up. At this time, the direction of the overflow inlet pipe (14a, 14b) of the sump (21) is made to match the direction of the overflow outlet of the sump (100), the first guide projection (13a) and the second of the fastening ring (1) The guide protrusion 13b is directed at right angles to the overflow inlet pipes 14a and 14b of the drain container 21.

As shown in FIG. 12, in a state in which the drain container 21 enters the outside of the fastening ring 1, the packing ring 19 is not pressed against the bottom surface of the water bottle 100. The first guide protrusion 13a and the second guide protrusion 13b respectively enter the first opening 37a and the second opening 37b of the drain container 21, respectively, and the first annular projection walls 33a, 33b) You can't go down to the bottom. Therefore, in this state, since the 1st guide protrusion 13a and the 2nd guide protrusion 13b do not escape the 1st opening 37a and the 2nd opening 37b, the drain container 21 cannot be rotated.

As shown in FIG. 13, when the drain container 21 is further pushed upward to compress the packing ring 19, the first guide protrusion 13a and the second guide protrusion 13b proceed further downward to form a first. The first guide protrusion 13a and the second guide protrusion 13b are separated from the first opening 37a and the second opening 37b, and the first annular projection walls 33a and 33b and the first inner diameter projection 25 are formed. It is located in the channel between. At this time, while pressing against the drain container 21 and turning clockwise, the drain guide 21 is guided by the first guide protrusion 13a and the second guide protrusion 13b of the fastening ring 1. Will rotate.

As shown in FIG. 14, the rotation of the sump 21 is made and stopped until the stop wall 35 of the sump 21 is caught by the second guide protrusion 13b of the fastening ring 1. At the point where the stop wall 35 of the sump 21 is caught by the second guide projection 13b of the fastening ring 1, the direction of the overflow inflow pipes 47a and 47b again points in the direction of the overflow outlet of the sump. Done. In addition, the packing ring 19 acts to push the drain container 21 downward while maintaining the compression state, thereby maintaining a solid assembly state and a watertight state.

In connection with this process, the third guide protrusion 15a and the fourth guide protrusion 15b of the fastening ring 1 are also connected to the third opening 41a and the fourth opening 41b of the drain container 21, respectively. It enters and stops after rotating along the channel between the second annular projection walls 39a and 39b and the first annular projection walls 33a and 33b.

As such, according to the present invention, the packing ring 19 is inserted into the packing ring support 43 of the drain container 21 so as to protrude upward, and the third opening 41a and the fourth opening of the fastening ring 1 are inserted. (41b) and the overflow inlet pipes (41a, 41b) of the sump 21 is directed toward the overflow outlet of the sump, firstly tightening the fastening ring (1) through the outlet of the bottom plate of the sump (100) After the insertion, the drain container 21 is held and the guide protrusions 13a, 13b (15a, 15b) of the fastening ring 1 are connected to the annular projection walls 33a, 33b (39a, 39b) of the drain container 21. The packing ring 19 is pressed while being pushed upwardly to enter through the formed openings 37a and 37b and 41a and 41b, and the drain ring 21 is fastened to the fastening ring 1 in a state where the packing ring 19 is pressed. When the first guide projection 13a or the second guide projection 13b of the rotary container is caught until the stop wall 35 of the drain container 21, the stop wall 35 of the drain container 21 becomes a drain container ( The first guide protrusion 13a of the fastening ring 1 when the 21 is rotated approximately 180 degrees. Or the second guide protrusion 13b is fixed, so that the stop wall 35 of the drain container 21 is caught by the first guide protrusion 13a or the second guide protrusion 13b of the fastening ring 1. If only assembly is performed, the overflow inlet pipes 45a and 45b of the sump 21 always face the overflow outlet direction of the sump in the assembled state. In addition, the drain container installer first aligns the packing ring 19 after the guide projection of the fastening ring 1 and the direction of the overflow inlet pipes 45a and 45b of the drain container 21 are directed toward the uber flow outlet direction of the water tank. By simply turning in the crimped state, the overflow inlet pipes 45a and 45b are automatically aligned with the Uberflow outlet direction, so that the sump assembly can be completed very quickly and easily.

1: Fastening ring
3: first outer mirror surface
5: first outer jaw
7: third outer mirror surface
9: second outer jaw
11: second outer surface
13a, 13b: Guide protrusion
15a, 15b: Guide protrusion
17: flange
19: packing ring
21: drain bottle
23: first inner mirror surface
25: first inner jaw
27: second inner mirror surface
29: second inner chin
31: third inner mirror surface
33a, 33b: annular projection wall
35: stop wall
37a, 37b: opening
39a, 39b: annular projection wall
41a, 41b: opening
43: packing ring support
45: Packing ring insert groove
47a, 47b: overflow inflow pipe
49: discharge pipe

Claims (2)

Drainage 21 disposed below the sump 100, a fastening ring 1 coupled to the sump 21 through a drainage port from above the sump, and between the sump 21 and the sump It consists of a packing ring (19) to hold the watertight,
The water container 21 is provided with a packing support 43 for receiving and supporting the packing ring 19 protruding upward from the upper end, and a third inner diameter surface 31 inside the packing ring support 43. And a second inner diameter surface 27 connected to the bottom of the third inner diameter surface 31 by a second inner diameter surface 29, and a first inner diameter surface below the second inner diameter surface 27. A first annular projection wall 33a which is formed by a first inner diameter surface 23 connected by the second inner diameter surface 23 and protrudes inwardly in succession to the second inner diameter jaw 29 on the second inner diameter surface 27; 33b) are formed, but the first annular projection walls 33a and 33b are formed with the first opening 37a and the second opening 37b open in the vertical direction facing each other and one side of the first opening 37a. The first annular projection wall (33a, 33b) in the vertical direction to form a stop wall (35) extending to the first inner jaw 25,
The fastening ring 1 has a first outer diameter surface 3 having a diameter larger than a first inner diameter surface 23 of the drain container 21 and smaller than a second inner diameter surface 27 from a lower end thereof, and the drain container. A second outer diameter surface 11 having a diameter smaller than the third inner diameter surface 31 of (21) and larger than the first outer diameter surface (3) is formed, and the packing ring is formed on the first outer diameter surface (3). When 19 is pressed upwards, the drainage in the state entered downward through the first opening 37a and the second opening 37b of the first annular projection walls 33a, 33b of the drain container 21; The first guide protrusion (13a) and the second guide protrusion (13b) formed on the stop wall 35 after guiding the rotation of the cylinder 21, sink sink structure for the sink characterized in that it is formed.
The method of claim 1,
Second annular projection walls 39a and 39b may be formed on the third inner diameter surface 31 of the sump 21, and the first opening 37a and the second opening may be formed on the second annular projection walls 39a and 39b. Forming a third opening 41a and a fourth opening 41b, which are arranged in a direction facing each other at right angles to 37b and open in the vertical direction;
The packing ring 19 is pressed downwardly through the third opening 41a and the fourth opening 41b in the first outer diameter surface 11 of the fastening ring 1 when the packing ring 19 is pressed upward. A sink connecting structure for sinks, characterized in that the third guide protrusion (15a) and the fourth guide protrusion (15b) for guiding the rotation of the water container 21 is formed.

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