KR101638427B1 - Ultra water saving closet - Google Patents

Abstract

The present invention comprises: a toilet bowl main body unit (1100) having a bowl (1110), a connection pipe (1120), and a cover unit (1130); a branch unit (1200) falling inside the cover unit (1130); a corrugated pipe (1300) which can be bent; a connection unit (1410) of which one side end part is connected to the corrugated pipe (1300); a waste water discharge unit (1400) composed of a discharge unit (1420) having a U-shaped flow passage and a storage unit (1430); and an elastic unit (1500) having an elastic force.

Description

{ULTRA WATER SAVING CLOSET}

[0001] The present invention relates to a super-clean water toilet. More particularly, the present invention relates to a super-clean water toilet with a delay time of being stored in a bowl when a direct water for washing is put into a toilet, Thereby reducing the waste of the washing water.

Generally, the principle of siphon is used to store a certain amount of water in the toilet bowl to smoothly wash the odor or manure coming from the outlet of the manure.

This siphon principle is that when the water level in the inverted U-tube and the water level in the toilet are in equilibrium, the water is stagnant while when the water level in the toilet bowl suddenly increases, the pressure in the toilet bowl is accompanied, And the water in the toilet bowl is discharged by the pressure difference of the toilet bowl.

A conventional toilet bowl comprises a bowl 2 for draining a predetermined amount of water as shown in Fig. 1, and a bowl 2 for storing water for a predetermined amount at a position higher than the bowl 2, And a water storage tank 1 connected to the water storage tank 2 through a supply passage 2a closed by a water supply port packing 5. The operation of the water discharge lever 3 provided in the water storage tank 1 causes the water discharge lever The water supply port packing 5 connected to the water supply port 3 opens the water supply port 10 so that the water in the water storage tank 1 is rapidly supplied to the bowl 2 through the supply path 2a, (2b) by the siphon effect produced by the water drained along the drainage passage (2b) of the bowl by the water pressure generated in the bowl (2) and the water pressure thereof in accordance with the increase in the water level in the bowl 2c to the drain port 2d.

However, the conventional toilet bowl as described above must always maintain a water level higher than the level of the drain trap 2c to prevent reverse flow of odor and the like in the bowl, and also to maintain the water level of the drain trap 2c There has been a problem that the consumption of water is large because water must be used.

Further, since the existing toilet bowl should have a diameter of 45 mm or more, which is normally set to 45 to 55 mm, which is determined by the KS standard or the like, for discharging the dirt of the bowl discharge tube, it is necessary to generate a siphon phenomenon in order to clean the dirt in the bowl. In order to generate such a siphon phenomenon, at least 60 mm of water must be supplied to the inside of the bowl at a time. Therefore, in order to solve this problem, a conventional toilet is provided with a water tank and a certain amount of water is stored in the water tank. The siphon phenomenon occurs and water is supplied to the inside of the bowl through the water channel which communicates with the water tank and the bowl.

Therefore, even if water is supplied to the inside of the bowl, the diameter of the bowl discharge pipe is usually 45 to 55 mm, so that the siphon phenomenon can not be generated, and the bowl is discharged through the bowl discharge pipe. Can not be cleaned.

In the case of the male urinal, the automatic urinal can not be generalized because the dirty water can not be cleaned by the direct connection of the water pipe for the above-mentioned reason, although the automatic urinal cleaning is generalized by the detector using the water direct connection.

In addition, since the existing toilet has to have the function of the water tank, it can be cleaned. Therefore, there are space limitations because the design can not be reduced due to the design limitation and the water tank. In addition, when making a pottery (a so-called "one piece type toilet)" with a tank and a seat integrally formed, the defective rate is high and the yield of production is decreased,

In addition, even if water leakage occurs due to a failure of the water supply pipe installed in the water tank, it is difficult for the user to easily detect the water leakage. In addition, in the case of a public toilet, such as a public toilet, a so-called flash toilet, there is no water tank, so a separate 25 mm (1 in) diameter pipe is provided separately from the water pipe As the equipment must be installed, enormous equipment cost is added. In case of lever operation, it is a phenomenon called "water hammer" and it is accompanied by severe noise and can not be used for general residential use.

In order to solve some of such problems, Korean Patent Registration No. 10-1131810 entitled " Variable Double Line Tubular Water Saving Toilet Seat " filed by the present applicant has been disclosed.

However, since the variable double-rectilinear tube can operate in a conventional water supply channel and a bowl rim, when the water level in the bowl rises when the water is supplied to the water, the variable rectilinear pipe is downward, It is impossible to use the water pressure as a result, and there is a problem in washing the inside of the bowl, and it is difficult to control the downward delay time of the variable linear tube when discharging the dirt, Backflow occurs occasionally.

Therefore, in the case of supplying the water supply directly to the toilet without using the water tub described in the above-mentioned patent, the above-described problem is accompanied. Therefore, in order to solve the above-mentioned problem, a water tank must be provided. As described above, since the water tank is provided, the manufacturing cost is increased, and the space occupied by the water tank is not utilized.

In addition, if the length of the variable double-rectilinear tube is long, rotation of the variable double-rectilinear tube by weight may be performed to discharge the dirt. As the length of the variable double rectilinear tube becomes longer, the radius of rotation of the variable double rectilinear tube becomes larger, and the space of the cover portion accommodating the variable double rectilinear tube becomes larger. As a result, the toilet becomes bigger and the installation becomes difficult in a narrow space .

In addition, since the variable double-rectilinear tube is required to store a low water content inside the bowl by maintaining an angle of about 45 degrees when the dirt is discharged, that is, in the air, the elastic force of the constant tension spring You must keep it. In addition, the elastic force of the tension spring must be further increased to restore the original state of the variable double-rectilinear tube rotated at 45 degrees or more during the dirt washing. Therefore, if the washing water is not used more than the proper amount to have a larger weight than the elastic force of the tension spring, the restoring force of the tension spring becomes strong and the variable double linear tube does not rotate over a certain angle for discharging the dirt. There is a problem of backflow.

In addition, one side of the tension spring coupled with the variable dual straight tube is fixed to the bracket, which is attached to the pottery. In order to attach the bracket to a bowl made of ceramics, it is attached using screws or the like. However, since it is difficult to attach the bracket due to the nature of ceramics, there is a problem in productivity and stable quality control.

In order to solve such a problem, Korean Patent No. 10-1453013 filed by the present applicant and registered as a direct water-saving toilet bowl has been disclosed, which is shown in FIGS. 2 to 4.

The direct water-taking water-saving toilet seat is installed on a floor or a wall, and a direct-milk-water receiving portion (101a) in which a direct water-feeding inlet (50) A bowl 101 for storing a predetermined amount of water and a connection pipe 110 for discharging waste water to be stored in the bowl 101. The bowl 101 covers the rear of the bowl 101, A toilet bowl body 100 having a cover portion 102 for guiding exhausted dirt to a bottom pipe 103 for discharging exhausted water to the outside of the toilet bowl; A corrugated pipe 200 connected to the connection pipe 110 and forming a flow path of wastewater drained from the bowl 101 and capable of being bent; When the wastewater flowing from the corrugated pipe 200 has a predetermined amount, the wastewater flows elastically along the downward direction to discharge the wastewater to the outside through the main discharge channel. In addition, A waste water discharge pipe 400 for storing a predetermined amount of water and discharging the waste water to the outside through the auxiliary discharge flow path to delay the discharge time of the waste water discharged through the main discharge flow path; And elastically connecting the connection pipe 110 and the wastewater discharge pipe 400. When the amount of wastewater flowing from the wrinkle pipe 200 becomes less than a predetermined amount, (500); The elastic part 500 is fixed to the connection pipe 110 and is connected to the connection pipe 110 at a right angle to the direction of flow of the connection pipe 110 outside the connection pipe 110. A pair of first squeezing members 510 protruding from both sides of the sewage pipe 400 and provided with projections 511 formed with first hook holes 511a, A pair of second stretching members 520 on which the hooking holes 521 are formed and a pair of second hooking members 520 having one end connected to the first hooking hole 511a And a pair of elastic members (530).

The wastewater discharge pipe 400 includes a cylindrical main discharge pipe 410 connected to an end of the bell pipe 200 on the discharge side of the wastewater pipe 200 and a portion of the main discharge pipe 410 The main discharge pipe 410 and the auxiliary discharge pipe 420 are communicated with each other so that the main discharge pipe 410 and the auxiliary discharge pipe 420 are connected to each other through the corrugated pipe 200 A drainage hole 411 for discharging the wastewater flowing into the auxiliary discharge pipe 420 is formed at an end of the auxiliary discharge pipe 420 on the discharge side of the discharge pipe 420, And an auxiliary discharge hole 421 for discharging the auxiliary discharge hole 421 to the outside is formed.

2 and 3, the wastewater stored in the bowl 101 flows into the connection pipe 110 and the corrugated pipe (not shown) The wastewater flowing into the main discharge pipe 410 flows into the main discharge pipe 410 through the auxiliary discharge pipe 420 contacting the auxiliary discharge pipe 420 surrounding the main discharge pipe 410, (420) connected to the lower end of the main discharge pipe (410) through a pair of discharge holes (411) formed on both sides of the main discharge pipe (410) located on both ends of the main discharge pipe ). ≪ / RTI > When a predetermined amount of wastewater is stored in the auxiliary discharge pipe 420, the entire wastewater discharge pipe 400 is rotated to be horizontal (90 degrees or more) as shown in FIG. 4, and discharged to the auxiliary discharge pipe 420 The stored wastewater is discharged to the outside through the auxiliary discharge hole 421 formed at the rear end of the auxiliary discharge pipe 420, that is, at the waste water discharge side end, and is discharged downward.

The water stored in the bowl 101 is discharged into the auxiliary discharge pipe 420 and a certain amount of wastewater is stored in the auxiliary discharge pipe 420 so that the waste water discharge pipe 400 is discharged downward and discharged , And an operation delay time.

In addition, even when water is manually introduced into the bowl 101 for washing the bowl 101, a certain amount of wastewater is discharged into the auxiliary discharge pipe 420 and stored in the auxiliary discharge pipe 420, 400 are dropped downward and the water stored in the bowl 101 is discharged. In the case of such a malfunction, there is no water left in the bowl 101, so that there is a problem in that the operation for introducing the direct water into the bowl 101 must be performed again.

Even if the bowl 101 is continuously filled with direct water for cleaning the bowl 101, the sewage is discharged into the auxiliary discharge pipe 420 and a certain amount of wastewater is stored in the auxiliary discharge pipe 420, 400 are dropped downward and the water stored in the bowl 101 is discharged. In the case of such a malfunction, there is no water left in the bowl 101, so that there is a problem in that the operation for introducing the direct water into the bowl 101 must be performed again.

In order to wash the sewage in the bowl 101, a direct water is injected into the bowl 101 by operating a button or a lever. When the amount of water injected into the bowl 101 becomes a predetermined amount or more, 411 to the inside of the auxiliary discharge pipe 420 and the sewage discharge pipe 400 is rotated downward by its own weight when the predetermined amount of wastewater stored in the auxiliary discharge pipe 420 is stored to discharge the sewage in the bowl 101 . At this time, when discharged from the main discharge pipe 410 to the auxiliary discharge pipe 420, the wastewater is discharged into the auxiliary discharge pipe 420 and has a delay time until a certain amount is stored.

The delay time until the wastewater in the bowl 101 is discharged to the inside of the auxiliary discharge pipe 420 and stored in a certain amount causes the phenomenon that the wastewater in the bowl 101 gradually becomes mixed with the charged water. When the sewage in the bowl 101 gradually increases with the input water, the dirt is scattered not only in the bowl 101 but also inside the toilet. This scattered dirt contains a large amount of germs, and even if the bowl 101 is washed, the germs are left on the upper part of the bowl 101, and the germs are attached to a toothbrush provided on a sink or the like. Accumulation of these germs due to frequent use will adversely affect the cleanliness of the bowl 101 and the toilet.

When the wastewater in the bowl 101 is gradually increased in accordance with the delayed time, the water that has been introduced into the bowl 101 is discharged from the main discharge pipe 410 through the discharge hole 411 to the auxiliary discharge pipe 420, and the amount of the water flowing into the bowl 101 is much larger than the amount of the water discharged into the auxiliary discharge pipe 420 and stored therein. At this time, the water injected into the bowl 101 does not largely participate in the washing, and is mainly discharged and stored in the auxiliary discharge pipe 420. As described above, the entering water into the bowl 101 does not greatly contribute to the washing, and rather the dirt increases in the bowl, thus wasting washing water.

[0001] The present invention relates to a super-clean water toilet. More particularly, the present invention relates to a super-clean water toilet with a delay time of being stored in a bowl when a direct water for washing is put into a toilet, Thereby reducing the waste of the washing water.

It is another object of the present invention to provide a low-water toilet which can prevent wastewater from being washed out and scattered by preventing wastewater from entering into the toilet when the wastewater is poured into the bowl.

Still another object of the present invention is to provide a sewage disposal apparatus and a sewage disposal facility which can reduce the length of the sewage discharge pipe and can minimize the size (length) of the toilet water as a result of shortening the discharge port of the sewage discharge outlet, .

A toilet water closet according to an embodiment of the present invention is provided on a floor or a wall and includes a direct water inflow path 1150 through which the direct water flows from the outside to the outer periphery of which the upper part is opened and opened, A bowl 1110 and a connection pipe 1120 for discharging the waste water stored in the bowl 1110. The bowl 1110 covers the rear of the bowl 1110 and discharges dirt discharged through the connection pipe 1120, A toilet bowl body 1100 having a cover 1130 to be guided to a bottom pipe 1140 to be discharged to the outside; A branching part 1200 installed inside the direct-path inflow path 1150 and parting direct water from the direct-path inflow path 1150 when the water flows into the bowl 1110 and falling into the cover part 1130, ; A bellows pipe 1300 connected to the connection pipe 1120 and forming a flow path of wastewater drained from the bowl 1110 and capable of being bent; A communicating part 1410 which is located in the cover part 1130 and has one end connected to the corrugated pipe 1300 and through which the sewage flows from the bowl 1110 through the corrugated pipe 1300, Shaped flow path together with the communication portion 1410 so that the wastewater introduced from the communication portion 1410 is discharged to the lower portion of the communication portion 1410 in a direction opposite to the inflow direction of the wastewater flowing in from the communication portion 1410 And a storage part 1430 for storing the direct water dropped by the branching part 1200. The directing water branched by the branching part 1200 is stored in the storage part 1420, A wastewater discharging part 1400 which is rotated by its own weight to discharge wastewater to the outside through the communicating part 1410 and the discharging part 1420; The connection pipe 1120 and the wastewater discharging unit 1400 are elastically connected to each other so that the wastewater discharging unit 1400 is in an upright position after discharging the wastewater, An elastic part 1500 having an elastic force for preventing the elastic part 1500 from being discharged to the discharge part 1400; And a control unit.

The storage section 1430 of the waste water discharging section 1400 may be opened in a range of 5 to 30 degrees so that a direct water dropped by the branching section 1200 can be flowed back and stored in the bowl 1110. [ And has a slope of.

Further, the discharge cross-sectional area of the discharge portion 1420 of the wastewater discharge portion 1400 is larger than the discharge cross-sectional area of the communication portion 1410.

A valve plate 1410 is disposed on the inner end of the communication portion 1410 of the waste water discharging portion 1400 so as to close the communication portion 1410 and to be rotated when the waste water is discharged to open the communication portion 1410. [ 1440) are further provided.

The lower end of the discharge portion 1420 is provided with a latching portion 1421 for reducing the cross-sectional area of the discharge side in order to raise the discharge pressure of the waste water discharged by the communication portion 1410 .

The communication portion 1410 of the waste water discharge portion 1400 may have a circular tube shape and the discharge portion 1420 may have a rectangular pipe shape surrounding the communication portion 1410.

The branched portion 1200 is inserted into the direct water inflow passage 1150 and the end portion located inside the direct water inflow passage 1150 is inserted into the direct water inflow passage 1150, The step portion 1210 is formed higher than the bottom of the direct-current inflow path 1150 so that a portion of the direct water from the direct-path inflow path 1150 can be prevented from being branched by the branch portion 1200.

When the direct water flows through the direct water inflow passage 1150 by the branch portion 1200, the lower portion of the branch portion 1200 is closed. When the direct water does not flow, the cover portion 1130 (Not shown) for the branch portion 1200 to prevent the odor from flowing back into the direct-running inflow path 1150 from the inside thereof.

According to another embodiment of the present invention, a deep water toilet is provided with a water tank 500; A bowl 1110 is installed at the bottom of the water tank 500 and is installed on a floor or a wall and a predetermined amount of wastewater is stored from the water tank 500 through a water inlet / And a bottom pipe 1140 covering the rear of the bowl 1110 and discharging the dirt discharged through the connection pipe 1120 to the outside of the toilet bowl A toilet body portion 1100 provided with a cover portion 1130; A branching part 1200 provided inside the water supply inflow path 1160 and allowing a part of water to flow from the water supply inflow path 1160 to the inside of the cover part 1130 when water is supplied to the bowl 1110; A bellows pipe 1300 connected to the connection pipe 1120 and forming a flow path of wastewater drained from the bowl 1110 and capable of being bent; A communicating part 1410 which is located in the cover part 1130 and has one end connected to the corrugated pipe 1300 and through which the sewage flows from the bowl 1110 through the corrugated pipe 1300, Shaped flow path together with the communication portion 1410 so that the wastewater introduced from the communication portion 1410 is discharged to the lower portion of the communication portion 1410 in a direction opposite to the inflow direction of the wastewater flowing in from the communication portion 1410 And a storage part 1430 for storing the water which is branched by the branching part 1200 and stored in the upper part. The water branched by the branching part 1200 is stored in the storage part A wastewater discharging part 1400 which is rotated by its own weight to discharge wastewater to the outside through the communicating part 1410 and the discharging part 1420; The connection pipe 1120 and the wastewater discharging unit 1400 are elastically connected to each other so that the wastewater discharging unit 1400 is in an upright position after discharging the wastewater, An elastic part 1500 having an elastic force for preventing the elastic part 1500 from being discharged to the discharge part 1400; And a control unit.

The storage section 1430 of the waste water discharging section 1400 may be opened in a range of 5 to 30 degrees so that a direct water dropped by the branching section 1200 can be flowed back and stored in the bowl 1110. [ And has a slope of.

In addition, the discharge cross-sectional area of the discharge portion 1420 of the wastewater discharge portion 1400 is larger than the discharge cross-sectional area of the communication portion 1410.

A valve plate 1410 is provided on the inner end of the communicating portion 1410 of the waste water discharging portion 1400 so as to close the communicating portion 1410 and to be rotated when the waste water is discharged to open the communicating portion 1410 1440) are further provided.

In addition, a latching part 1421 is provided on the lower end of the discharge part 1420 for reducing the cross-sectional area of the discharge side in order to raise the discharge pressure of the discharge water by the communication part 1410 .

The communication portion 1410 of the waste water discharge portion 1400 may have a circular tube shape and the discharge portion 1420 may have a rectangular pipe shape surrounding the communication portion 1410.

The branched portion 1200 is vertically inserted into the water inlet inflow passage 1160 and the end portion located inside the water inlet inflow passage 1160 is connected to the water inlet inflow passage 1160 at a predetermined water level The step portion 1210 is formed to be higher than the bottom surface of the water supply inlet path 1160 so that a part of the water from the water supply inlet path 1160 can be prevented from being branched by the branching portion 1200 .

The lower part of the branching part 1200 is opened when water flows through the water supply inflow path 1160 by the branching part 1200 and is closed when the water does not flow so that the cover part 1130 (1160) to prevent the odor from flowing back to the water supply inflow path (1160).

In the present invention, part of the direct water is directly supplied to the waste water discharge part rotated by its own weight when a direct water for washing is stored in a bowl without passing through the bowl, and the waste water is immediately discharged, The delay time can be reduced.

Since a part of the direct water is directly supplied to the waste water discharge part without going through the bowl, when the direct water for washing is inputted into the toilet water as the washing delay time is reduced, most of the washing water is involved in the washing so that waste water of the washing water can be drastically reduced do.

In addition, since the delay time stored in the waste water discharging portion can be reduced, it is prevented that the direct water for washing is filled with the waste water in the bowl when the toilet water is introduced into the toilet, so that the waste water can be prevented from scattering.

In addition, since scattering of dirt is prevented, cleanliness of the bowl and the toilet can be maintained.

In addition, when the water stored in the running water or the water tank is not supplied, the waste discharge unit can not operate. Therefore, a large amount of water is artificially introduced into the recess to clean the recess, or the waste discharge unit malfunctions even when the user keeps pressing the lever There is no effect.

In addition, since the discharge length of the dirt discharge part is short, the size (length) of the toilet can be reduced to the utmost, so that space utilization of the toilet is easy and various designs can be realized.

1 is a view showing a configuration of a conventional toilet bowl.
2 to 4 are views showing a conventional water-saving type water-saving toilet bowl.
FIGS. 5 and 6 are views showing a state in which sewage is discharged from a hypodermicidal toilet according to an embodiment of the present invention.
FIGS. 7 and 8 are views showing a state in which sewage is discharged from a hypodermicidal toilet according to an embodiment of the present invention.
FIG. 9 and FIG. 10 are exploded perspective views illustrating a connection state between the discharge portion of the toilet seat and the elastic portion according to the present invention.
11 is a view illustrating a hypotonic water toilet according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a hypotonic water toilet according to the present invention will be described with reference to the accompanying drawings.

The artificial scalpel of the present invention can be distinguished as a direct-drinking toilet seat to be cleaned with direct water and a water-saving toilet seat to be cleaned with water stored in the water tank.

The direct water-containing toilet bowl which is cleaned using direct water as a low-water toilet bowl according to an embodiment of the present invention will be described as follows.

FIGS. 5 and 6 are views showing a state in which sewage is discharged from a hypodermicidal water closet according to an embodiment of the present invention. FIGS. 7 and 8 are views showing a state in which the sewage in a hypodermicidal water closet according to an embodiment of the present invention is discharged And FIGS. 9 and 10 are exploded perspective views showing a connection state between the discharge portion of the toilet seat and the elastic portion of the toilet seat of the present invention.

5 to 8, the artificial scalpel of the present invention mainly includes a toilet body part 1100, a branching part 1200, a corrugated pipe 1300, a wastewater discharging part 1400, an elastic part 1500 ).

The urinal body portion 1100 and the corrugated tube 1300 and the elastic portion 1500 are the same as those disclosed in Korean Patent No. 10-1453013 filed by the present applicant and filed by the present applicant .

The toilet flap body 1100 according to the present invention is installed on the floor or wall of the toilet. The figure shows the state of being installed on the floor of the toilet. Since the toilet according to the present invention does not need to include a water tank, the weight of the toilet can be light and the length of the waste water discharging part 1400 can be shortened, so that the toilet can be downsized, so that the toilet can be installed on the wall of the toilet.

The toilet bowl body 1100 includes a bowl 1110 storing a predetermined amount of wastewater, a connection pipe 1120 discharging sewage water from the bowl 1110, and a cover portion 1130 covering the rear of the bowl 1110 .

The bowl 1110 is formed with a direct water inflow path 1150 through which the direct water flows from the outside to the outer periphery of which the upper part is opened and opened and a certain amount of direct water flowing through the direct water inflow path 1150 is stored. The bowl 1110 has the same shape as that applied to a general toilet seat, but in the case of a direct-intake toilet seat according to the present invention, the water supply passage typically has a diameter of 60 mm or more because the toilet seat is supplied with water at a general toilet seat. The direct intake passage 1150 of the bowl 1130 is approximately 20 mm in diameter, and the direct intake passage of the normal left-hand side formed in the outer periphery of the bowl is generally 30 mm or more in diameter. The direct water inflow path 1150 formed in the opened outer periphery has to be about 15 mm so that the direct water pressure can be used as it is.

The connection pipe 1120 discharges wastewater stored in the bowl 1110 to the cover part 1130 and protrudes toward the rear of the bowl 1110.

The cover 1130 is guided to the bottom pipe 1140 which covers the rear of the bowl 1110 and discharges the dirt discharged through the connection pipe 1120 to the outside of the toilet bowl.

The corrugated pipe 1300 according to the present invention forms a flow path of the wastewater discharged from the bowl 1110 and is connected to the connection pipe 1120. That is, one end of the bellows pipe 1300 is connected to the end of the connection pipe 1120.

One end of the corrugated pipe 1300 may be fixed to the connection pipe 1120, or may be screwed and screwed.

The corrugated pipe 1300 is flexible and can be bent by an external force.

And an odor prevention part 1600 installed inside the corrugated pipe 1300 and opened by the flow of the wastewater when the wastewater flows and closed when the wastewater does not flow.

5 to 8, the odor prevention part 1600 according to the present invention is installed inside the bell pipe 1300, and when the wastewater flows, it is opened by the flow of the wastewater, If not, it is closed.

The malodor prevention part 1600 is also the same as the one disclosed in Korean Patent No. 10-1453013 filed by the present applicant and filed by the present applicant.

The malodor prevention part 1600 includes a malodor prevention member 1610 disposed inside the corrugated pipe 1300 and formed in a hollow shape and formed of flexible vinyl or thin rubber.

The malodor-preventing member 1610 may be formed of a flexible or flexible vinyl or rubber.

One end of the malodor-preventing member 1610 is fixed to one end of the bellows pipe 1300 on the inflow side. The fixing method may be performed using an adhesive.

The other end of the malodor-preventing member 1610 is disposed at a free end along the waste water discharge side of the bellows pipe 1300. That is, the other end of the malodor-preventing member 1610 is not fixed inside the corrugated pipe 1300.

When the wastewater stored in the bowl 1110 flows into the corrugated pipe 1300 through the connection pipe 1120, the flowing wastewater flows into the hollow of the odor prevention member 1610 and flows into the odor prevention member 1610, Can be opened.

At this time. The periphery of the odor preventing member 1610 can be brought into close contact with the inner periphery of the bellows pipe 1300.

When the flow of the wastewater through the corrugated pipe 1300 is completed, the other end of the malodor-preventing member 1610 disposed at the free end is changed in appearance so as to be in close contact with each other.

That is, after all the wastewater is discharged, the other end of the malodor-preventing member 1610 is in close contact with each other and closed.

Accordingly, the other end of the odor prevention member 1610 is closed to some extent, and thus, the odor from the side from which the sewage is discharged can be minimized to flow back toward the bowl 1110 side.

5 and 7, the branching unit 1200 according to the present invention is installed inside the direct-running water inflow passage 1150, and when the direct water is introduced into the bowl 1110, So that it falls into the cover part 1130. [0052] As shown in FIG.

The waste discharge unit 1400 is located in the cover unit 1130 and includes a communication unit 1410, a discharge unit 1420, and a storage unit 1430.

One end of the communicating part 1410 is connected to the corrugated pipe 1300 and is connected to the corrugated pipe 1300 through the bowl 1110.

The discharge portion 1420 is disposed in the lower portion of the communication portion 1410 such that the wastewater introduced from the communication portion 1410 is discharged in a direction opposite to the inflow direction of the wastewater flowing in from the communication portion 1410. [ (1410) together with a U-shaped flow path.

The storage unit 1430 serves to store the directing water that is branched and dropped by the branching unit 1200 at the upper part.

The wastewater discharging unit 1400 is configured such that a direct water branching by the branching unit 1200 flows into the storage unit 1430 and is stored in the storage unit 1430, And the waste water is discharged to the outside through the discharge portion 1420.

The elastic part 1500 elastically connects the connection pipe 1120 and the waste water discharge part 1400 as shown in FIGS. 6, 8 and 9 to 10, 6, when the wastewater discharged from the bowl 1110 flows into the waste discharge pipe 1310 of the waste discharge unit 1400, the wastewater discharge unit 1400 is in an upright state, As shown in Fig.

The elastic part 1500 is the same as the elastic part described in the Korean Registered Patent No. 10-1453013 filed by the present applicant and filed by the present applicant.

The elastic part 1500 is fixed to the connection pipe 1120 and is connected to the outside of the connection pipe 1120 so that the connection part of the connection pipe 1120 A pair of first squeezing members 1510 protruding from both sides of the outer side of the connection pipe 1120 at right angles to the first squeezing pipe 1511 and having protrusions 1511 formed with first squeeze holes 1511a, A pair of second stretch members 1520 provided outside the first and second hooking members 1310 and 1310 and each having a second hooking hole 1521 are connected to the pair of second stretching members 1520, And a pair of elastic members 1530 connected to the first hooking hole 1511a.

The first engaging members 1511a of the first engaging member 1510 are spaced apart from the protruding portions 1511 of the first engaging member 1510.

The first strapping member 1510 may be fastened to the connection pipe 1120 by bolts and inserted into the connection pipe 1120. Since the toilet bowl is mostly made of ceramics, the connecting pipe 1120 of the toilet bowl may be damaged in the case of the bolt fastening method when the first strapping member 1510 is fastened.

In the case of the fixed fitting type, a coupling pipe coupling part 1512 is further provided to be fitted to the coupling pipe 1120 by fitting the coupling pipe 1120 into the first stretching member 1510. The coupling tube coupling portion 1512 is a ring-shaped pipe.

The pair of second stretching members 1520 are formed in a plate-like shape and protrude outward from the waste water discharge pipe 1310, respectively.

It is preferable that the second hooking holes 1521 are provided at a plurality of intervals in the vertical or horizontal direction in each of the pair of second stretching members 1520.

A plurality of first engaging holes 1511a of the first engaging member 1510 and a second engaging hole 1521 of the second engaging member 1520 are provided to adjust the elastic force of the elastic member 1530 to be. The adjustment of the elastic force of the elastic member 1530 is related to the rotation due to the self weight of the waste water discharge part 1400 according to the inflow amount of the direct water to the storage part 1430. If the elastic force of the elastic member 1530 is increased, the waste water can be discharged by allowing the waste water discharge unit 1400 to rotate due to its own weight when the amount of direct water flowing in the storage unit 1430 is large. When the elastic force of the member 1530 is reduced, even if the direct-flowing amount of the direct water in the storage part 1430 is small, the waste water can be pumped by self-weight of the waste water discharger 1400 so that waste water can be discharged. However, in order to smoothly discharge the wastewater, it is desirable that the elastic force of the elastic member 1530 is appropriately maintained.

The pair of second stagger members 1520 may be arranged at a right angle to the inflow direction of the wastewater discharge pipe 1310 so as to be close to the upper portion of the connection pipe 1120 on the wastewater inflow side end portion of the wastewater discharge pipe 1310. [ So as to protrude outwardly of the waste water discharge pipe 1310.

The pair of second squeezing members 1520 may be disposed at a position orthogonal to the inflow direction of the waste water in the waste water discharge pipe 1310 so as to be close to the upper portion of the connection pipe 1120 on the waste water inflow side end portion of the waste water discharge pipe 1310. [ The sewage discharge unit 1400 can be smoothly rotated upright after the discharge of the waste water. If the pair of second squeezing members 1520 are provided far from the upper portion of the connection pipe 1120 on the sewage inlet side end of the sewage discharge pipe 1310, the sewage discharge unit 1400 It can be rotated down without being rotated upward. In this case, even if the direct water is supplied into the bowl 1110 after the discharge of the waste water, the waste water is completely discharged through the waste water discharge pipe 1310, so that the waste water is not stored in the bowl 1110. Therefore, in order to prevent such a malfunction, the pair of second squeezing members 1520 may be connected to the waste water discharge pipe 1310 so as to be close to the upper portion of the connection pipe 1120 on the waste water inflow side end portion of the waste water discharge pipe 1310, So that the sewage discharge unit 1400 can be rotated upright after the discharge of the waste water.

Referring to FIG. 5 and FIG. 6, when the direct water does not flow into the direct water inflow path 1150, the wastewater discharge unit 1400 is maintained in an upright state . The connection pipe 1120 is perpendicular to the corrugated pipe 1300 and the waste water discharge pipe 1310 so that the water contained in the bowl 1110 is not discharged.

When the direct water flows into the direct water inflow path 1150 for washing the bowl 1110, some direct water is branched into the branch part 1200 installed inside the direct water inflow path 1150, And then stored in the storage unit 1430. [0064] When the direct water stored in the storage unit 1430 is set to a predetermined amount, the waste water discharge unit 1400 is rotated downward by its own weight (see FIGS. 7 and 8).

The connection pipe 1120 is horizontal with the corrugated pipe 1300 and the waste water discharge pipe 1310 and the dirt contained in the bowl 1110 flows into the corrugated pipe 1300 And the waste water discharge pipe 1310, as shown in FIG.

At this time, the direct water stored in the storage unit 1430 is discharged to the outside of the storage unit 1430 when the waste water in the bowl 1110 is discharged in a state where the waste water discharge unit 1400 is rotated downward.

When the direct water stored in the storage unit 1430 is discharged to the outside of the storage unit 1430 through the discharge port 1431 discharged to the outside of the storage unit 1430, The wastewater discharging part 1400 is returned to its original position by the elastic force of the bowl 1500 to maintain the upright state as shown in Figure 6 and the direct water stored in the bowl 1110 after washing the bowl 1110 is returned to the bowl 1110 to the outside.

When the direct water stored in the storage part 1430 is discharged through the discharge port 1431, the waste water discharging part 1400 is returned to the original position in the upright state by the elastic force of the elastic part 1500, .

As described above, unlike the conventional method, in which the direct water for washing is put into the toilet bowl through the bowl and stored in the waste water discharge unit, a delay time is generated in the toilet bowl of the present invention, 1200 to directly supply a part of the direct water to the wastewater discharging part 1400 rotated by its own weight, there is an effect that the delay time to be stored and rotated can be reduced.

Since the portion of the direct water is directly supplied to the wastewater discharging portion 1400 without passing through the bowl 1110, the delay time stored in the wastewater discharging portion 1400 is reduced, and when the direct water for washing is put into the toilet, Most of the water is involved in the washing, so that waste of the washing water can be drastically reduced.

In addition, since the delay time stored in the waste water discharging portion can be reduced, it is prevented that the direct water for washing is filled with the waste water in the bowl when the toilet water is introduced into the toilet, so that the waste water can be prevented from scattering. In addition, since scattering of dirt is prevented, cleanliness of the bowl and the toilet can be maintained.

The direct water dropped through the branching part 1200 is stored in the storage part 1430 of the wastewater discharging part 1400 and discharged in the bowl 1110 in a state where the wastewater discharging part 1400 is rotated downward The direct water stored in the storage unit 1430 is discharged through the discharge port 1431 to the outside of the storage unit 1430 and the direct water is discharged to the storage unit 1430, The water discharged from the bowl 1110 is not discharged because the waste water discharger 1400 is rotated upright in its original state when the weight of the water stored in the bowl 1110 is reduced.

The storage portion 1430 of the waste water discharge portion 1400 is slanted by about 10 degrees so that a direct water dropped by the branching portion 1200 and flowing downwardly can be stored in the backward direction of the bowl 1110 .

If the slope of the storage portion 1430 of the waste water discharge portion 1400 is too small, a direct water dropped by the branch portion 1200 flows downward in the backward direction of the bowl 1110, Or the number of branches that are branched and dropped by the branching unit 1200 is not stored in the storage unit 1430 but flows out of the storage unit 1430 and is not stored in the storage unit 1430. [

If the slope of the storage portion 1430 of the waste water discharge portion 1400 is too large, a direct water dropped by the branch portion 1200 flows downward in the backward direction of the bowl 1110 However, since the height of the waste water discharging part 1400 is increased in order to secure the storage space of the storage part 1430, it is impossible to downsize the waste water.

Therefore, it is preferable that the slope of the storage portion 1430 of the waste water discharge portion 1400 is appropriately sized.

The discharge cross-sectional area of the discharge portion 1420 of the waste water discharge portion 1400 is preferably larger than the discharge cross-sectional area of the communication portion 1410.

When the discharge cross-sectional area of the discharge portion 1420 of the waste water discharge portion 1400 is larger than the discharge cross-sectional area of the communication portion 1410, the wastewater introduced from the communication portion 1410 flows together with the communication portion 1410 So that it can be smoothly discharged to the discharge portion 1420 that forms the groove-shaped flow path.

In this case, the communication portion 1410 of the wastewater discharge portion 1400 is formed in the same circular tube shape as the bellows 1300, and the discharge portion 1420 is formed in a rectangular pipe shape surrounding the communication portion 1410 Do.

The direct water flowing into the direct water inflow path 1150 is partially branched by the branching unit 1200. In order to allow direct water for washing into the bowl 1110 to flow into the bowl 1110, The direct water is dropped by the branching unit 1200.

However, when the bowl 1110 is cleaned after the bowl 1110 is cleaned, the water level of the direct water inflow path 1150 is gradually lowered. However, when the bowl 1110 is cleaned by the direct water inflow path 1150, The water discharge portion 1400 is maintained in an upright state and remains in the direct water inflow path 1150 only when the direct water is prevented from falling by the branch portion 1200 at the time of the end of the bowl 1110 whose water level is lowered The directing water flowing into the bowl 1110 is stored.

When the water level of the direct water inflow path 1150 is lowered at a time when the bowl 1110 is cleaned and the level of the direct water inflow path 1150 becomes lower than a predetermined water level, the branching unit 1200 may prevent the direct water branched by the branching unit 1200 from falling. It is preferable that a stepped portion 1210 is formed above the bottom of the direct-current inflow path 1150 on an end portion of the direct-current inflow path 1150 located inside the direct-

In addition, since the branching unit 1200 is vertically inserted into the direct-path inflow path 1150, the stepped portion 1210 branches a part of the direct path that is branched from the direct-path inflow path 1150 and falls, And also facilitates branching to the base 1200.

The communication portion 1410 is closed at the inner end portion of the communication portion 1410, that is, at the discharge side end portion for discharging the sewage to the discharge portion 1420. The communication portion 1410 is rotated And a plate 1440 to which one side is fixed. The valve 1440 is made of an elastic material such as rubber. When the wastewater discharging part 1400 is rotated by the branching water in the upright state, the wastewater can be discharged at the discharge of the wastewater through the communication part 1410 .

The valve 1440 may be configured such that when the waste water discharging part 1400 is in an upright state, the odor is discharged from the inside of the cover part 1130 through the discharge part 1420 of the waste water discharging part 1400, 1410 to the inside of the bowl 1110.

When the direct water flows through the direct water inflow passage 1150 by the branch portion 1200, the lower portion of the branch portion 1200 is closed. When the direct water does not flow, the cover portion 1130 (Not shown) for preventing a malodor from flowing back to the direct-path inflow path 1150 from the maldistribution path (not shown).

It is preferable that a latching part 1421 is provided on the lower end of the discharge part 1420 for reducing the cross-sectional area of the discharge side in order to raise the discharge pressure of the discharge water by the communication part 1410.

When the waste water discharge part 1400 is rotated by its own weight due to the supply of branched water, the waste water is discharged from the communication part 1410 to the discharge part 1420. As described above, the communication part 1410 Since the discharge area of the discharge portion 1420 is larger than the discharge area of the discharge portion 1420, the flow rate of the wastewater is slowed and a pressure drop occurs. Therefore, if the engagement portion 1421 is provided to increase the discharge pressure of the discharge portion 1420, the discharge pressure of the discharge portion 1420 can be increased, and the discharge from the discharge portion 1420 can be increased. So that it can be smoothly performed.

In addition, it is preferable that the latching portion 1421 is streamlined so as to smooth discharge of wastewater.

The odor prevention part (not shown) for the branched part 1200 prevents the odor from flowing back from the inside of the cover part 1130 to the direct water inflow path 1150, It is possible to block the odor which may flow into the bowl 1110 through the direct water inflow path 1150 and diffuse into the toilet. The structure of the odor prevention part (not shown) for the branched part 1200 is the same as the structure of the odor prevention part 1600 described above.

Meanwhile, it is preferable that the toilet bowl of the present invention has an index valve (not shown) capable of supplying and shutting the water directly to the front end of the position where the direct water heater 1200 is installed. The above-mentioned exponential valve may be provided mechanically or electronically, and a well-known one that controls the opening and closing time is used. As an example of the mechanical type, there is a check valve type which is operated to open and close the ball that is opened and closed by the push switch and to restore the ball to a closed state after a certain time due to the elastic force of the spring. As an example of an electronic type, there is a solenoid valve type which can be time-controlled by a push switch. In addition, a conventional valve can be used. However, the water saving effect can be obtained by providing the exponent valve on the direct water inflow path 1150, and the water level of the wastewater can be maintained constantly in the bowl 1110.

Therefore, the embodiment according to the present invention can make it possible to drain the desalinated water into the bowl 1110 of the toilet without the water tank by using the direct water directly supplied from the water pipe.

A water toilet for washing a toilet using a water stored in a water tank is described as follows, according to another embodiment of the present invention.

11 is a view illustrating a hypotonic water toilet according to another embodiment of the present invention.

Referring to FIG. 11, the underground water toilet of the present invention mainly includes a water tank 500, a toilet body portion 1100, a branch portion 1200, a corrugated pipe 1300, a waste water discharge portion 1400, (1500).

The water tank 500 stores wash water for supplying wash water to the bowl 1110, and is a component of a general toilet.

The remaining toilet bowl body portion 1100, the bellows pipe 1300, the waste water discharging portion 1400 and the elastic portion 1500 are the same as or similar to the configuration of the hypolithic water toilet according to the embodiment of the present invention, Explain only the other parts.

The bowl 1110 of the toilet bowl body 1100 is the same as the structure of a general water tank type toilet bowl in which a predetermined amount of wastewater is stored from the water tub 500 through the water inflow path 1160.

The branching part 1200 is installed inside the water supply inflow path 1160 and a part of water is branched from the water supply inflow path 1160 when the water is supplied to the bowl 1110 to be dropped into the cover part 1130 It plays a role.

The branching part 1200 is the same as the low-water toilet in the embodiment of the present invention, which is installed in the direct-running inflow path 1150, and which can be directly connected to the water supply.

The branching part 1200 is vertically inserted into the water supply inflow path 1160 and vertically inserted into the water inflow path 1160 and inserted into the water inflow path 1160 The water supply inlet path 1160 is positioned such that a part of water from the water supply inlet path 1160 is prevented from being branched by the branching section 1200 when the water supply inlet path 1160 is below a predetermined water level, The stepped portion 1210 is formed to be higher than the bottom surface of the stepped portion 1210.

The rest of the configuration is the same as that of the low-water toilet in which the water can be directly used according to the embodiment of the present invention described above.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

500: water tank 1100: toilet body portion
1110: Bowl 1120: Connector
1130: cover part 1140: floor pipe
1150: direct water inlet line 1300: corrugated pipe
1400: Wastewater discharge part 1500: Elastic part
1510: first stretching member 1511:
1511a: first hanging hole 1520: second hanging member
1521: second hanging hole 1530: elastic member
1600: odor preventing member 1610: odor preventing member

Claims (16)

delete The bowl 1110 is provided with a direct water inflow path 1150 through which the direct water flows from the outside and a predetermined amount of wastewater is stored in the outer periphery of the bottom and the wall. A connection pipe 1120 for discharging waste water to be stored and a bottom pipe 1140 for covering the rear of the bowl 1110 and discharging the dirt discharged through the connection pipe 1120 to the outside of the toilet bowl A toilet body portion 1100 provided with a cover portion 1130 for covering the body portion 1130;
A branching part 1200 installed inside the direct-path inflow path 1150 and parting direct water from the direct-path inflow path 1150 when the water flows into the bowl 1110 and falling into the cover part 1130, ;
A bellows pipe 1300 connected to the connection pipe 1120 and forming a flow path of wastewater drained from the bowl 1110 and capable of being bent;
And is located in the cover portion 1130,
A communicating part 1410 having one end connected to and communicating with the corrugated pipe 1300 and receiving sewage from the bowl 1110 through the corrugated pipe 1300,
The U-shaped portion 1410 is formed in the lower portion of the communication portion 1410 so that the wastewater introduced from the communication portion 1410 is discharged in the direction opposite to the inflow direction of the wastewater flowing in from the communication portion 1410. [ A discharge portion 1420 for forming a flow path,
And a storage unit (1430) for storing the direct water dropped by the branching unit (1200)
When the directivity branching by the branching section 1200 is stored in the storage section 1430 and is set to a predetermined amount, the directivity branching section 1400 is rotated downward by its own weight and is discharged through the communication section 1410 and the discharge section 1420, A waste water discharging part 1400 for discharging the waste water to the outside; And
The connection pipe 1120 and the wastewater discharging unit 1400 are elastically connected to each other so that the wastewater discharging unit 1400 is in an upright position after discharging the wastewater, An elastic part 1500 having an elastic force for preventing the elastic part 1500 from being discharged to the outside; And,
The storage portion 1430 of the waste water discharge portion 1400 is slidably provided at a slope of 5 to 30 degrees so that a direct water dropped by the branch portion 1200 and flowing downwardly can be stored in the backward direction of the bowl 1110. [ And an outlet for the toilet bowl. 3. The method of claim 2,
Wherein the discharge cross-sectional area of the discharge portion (1420) of the waste discharge portion (1400) is larger than the discharge cross-sectional area of the communication portion (1410). The method of claim 3,
A valve 1440 is provided on the inner end of the communicating part 1410 of the waste water discharging part 1400 so as to close the communicating part 1410 and to be rotated when the waste water is discharged to open the communicating part 1410, Wherein the second water level sensor is further provided with a second water level sensor. 5. The method of claim 4,
And a latching part 1421 for reducing the cross-sectional area of the discharge side is provided on the lower end of the discharge part 1420 in order to raise the discharge pressure of the discharge water discharged by the communication part 1410. [ A toilet. 6. The method of claim 5,
Wherein the communication part (1410) of the waste water discharge part (1400) has a circular tube shape and the discharge part (1420) has a rectangular pipe shape surrounding the communication part (1410). 7. The compound according to any one of claims 2 to 6,
The branch portion 1200 is inserted into the direct water inflow path 1150. When the end portion located inside the direct water inflow path 1150 reaches a certain water level of the direct water inflow path 1150, Wherein a stepped portion (1210) is formed higher than the bottom of the direct-current inflow path (1150) so that a part of the direct water from the path (1150) can be prevented from being branched by the branch portion (1200).
8. The apparatus according to claim 7, wherein a lower portion of the branch portion (1200)
When the direct water flows through the direct water inflow path 1150 by the branching unit 1200 and is closed when the direct water does not flow and the odor is sent from the cover part 1130 to the direct water inflow path 1150 And a malodor-preventing part for preventing the backflow of the branched portion. delete A water tank 500;
And is installed at the bottom of the water tank 500,
A bowl 1110 in which a predetermined amount of wastewater is stored from the water tank 500 through a water inlet and an inlet path 1160 and a connection pipe 1120 for discharging waste water stored in the bowl 1110, A toilet bowl body portion 1100 having a cover portion 1130 which covers the rear of the toilet bowl 1110 and is guided to a bottom tube 1140 for discharging the dirt discharged through the connection tube 1120 to the outside of the toilet bowl;
A branching part 1200 provided inside the water supply inflow path 1160 and allowing a part of water to flow from the water supply inflow path 1160 to the inside of the cover part 1130 when water is supplied to the bowl 1110;
A bellows pipe 1300 connected to the connection pipe 1120 and forming a flow path of wastewater drained from the bowl 1110 and capable of being bent;
And is located in the cover portion 1130,
A communicating part 1410 having one end connected to and communicating with the corrugated pipe 1300 and receiving sewage from the bowl 1110 through the corrugated pipe 1300,
The U-shaped portion 1410 is formed in the lower portion of the communication portion 1410 so that the wastewater introduced from the communication portion 1410 is discharged in the direction opposite to the inflow direction of the wastewater flowing in from the communication portion 1410. [ A discharge portion 1420 for forming a flow path,
And a storage unit 1430 for storing the water branched by the branching unit 1200 and stored in the upper part,
The water branched by the branching unit 1200 flows into the storage unit 1430 and is stored in the storage unit 1430 to be poured down through the communication unit 1410 and the discharge unit 1420, A waste water discharging part 1400 for discharging the waste water to the outside; And
The connection pipe 1120 and the wastewater discharging unit 1400 are elastically connected to each other so that the wastewater discharging unit 1400 is in an upright position after discharging the wastewater, An elastic part 1500 having an elastic force for preventing the elastic part 1500 from being discharged to the outside; And,
The storage portion 1430 of the waste water discharge portion 1400 is slidably provided at a slope of 5 to 30 degrees so that a direct water dropped by the branch portion 1200 and flowing downwardly can be stored in the backward direction of the bowl 1110. [ And an outlet for the toilet bowl.
11. The method of claim 10,
Wherein the discharge cross-sectional area of the discharge portion (1420) of the waste discharge portion (1400) is larger than the discharge cross-sectional area of the communication portion (1410). 12. The method of claim 11,
A valve 1440 is provided on the inner end of the communicating part 1410 of the waste water discharging part 1400 so as to close the communicating part 1410 and to be rotated when the waste water is discharged to open the communicating part 1410, Wherein the second water level sensor is further provided with a second water level sensor. 13. The method of claim 12,
And a latching part 1421 for reducing the cross-sectional area of the discharge side is provided on the lower end of the discharge part 1420 in order to raise the discharge pressure of the discharge water discharged by the communication part 1410. [ A toilet. 14. The method of claim 13,
Wherein the communication part (1410) of the waste water discharge part (1400) has a circular tube shape and the discharge part (1420) has a rectangular pipe shape surrounding the communication part (1410).
The method according to any one of claims 10 to 14, wherein the branching section (1200)
The end portion of the water inflow path 1160 is inserted into the water inflow path 1160 vertically so that the end portion of the water inflow path 1160 is connected to the water inflow path 1160 through the water inflow path 1160 when the water inflow path 1160 reaches a certain water level. Wherein a stepped portion (1210) is formed higher than a bottom surface of the water supply inflow path (1160) so that a portion thereof can be prevented from being branched by the branch portion (1200). 16. The apparatus according to claim 15, wherein a lower portion of the branch portion (1200)
And is opened when the water flows through the water supply inlet passage 1160 by the branching section 1200 and is blocked when the water does not flow so that the odor is sent from the cover section 1130 to the water supply inflow passage 1160 And a malodor-preventing part for preventing the backflow of the branched portion.

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