The present invention relates to a washing machine and more particularly to a washing machine having nozzles for spraying water, discharged from a tub and circulating along a circulation pipe, into a drum.
Korean Patent Application Publication No. 10-2018-0131894 (hereinafter, referred to as a “related art”) discloses a washing machine having nozzles for spraying water, pumped by a pump, into a drum. The washing machine includes a plurality of nozzles disposed along an inner circumferential surface of the gasket interposed between a casing, forming an exterior appearance of the washing machine, and a tub. A plurality of port receiving pipes protruding from an outer circumferential surface of the gasket may respectively communicate with the plurality of nozzles.
There is provided a guide pipe guiding water (circulating water) pumped by the pump, and the guide pipe includes a plurality of outlet ports protruding from an annular flow path to be respectively inserted into the plurality of port receiving pipes.
Each of the port receiving pipes protrudes approximately radially outward from the outer circumferential surface of the gasket, and, in response, each of the outlet ports protrudes radially inward from the annular flow path.
The guide pipe includes a circulation pipe connection port protruding from the annular flow path to be connected to a circulation pipe, and the circulation pipe is connected to the pump. Water pumped by the pump is guided along the circulation pipe and introduced into the circulation pipe connection port.
Water discharged from the circulation pipe connection port is introduced into the annular flow path and hits an inner surface of the flow path to be divided into two ways. While moving upward along the flow path, the water is discharged through outlet ports, sequentially. In the course where the water discharged from the circulation pipe connection port hits the inner surface of the flow path, resistance occurs. This resistance causes noise and disturbs a water flow not to be evenly divided into the two ways.
In addition, since the outlet ports are inserted into the port receiving pipes in different directions, it is difficult to assembly two or more outlet ports into two or more port receiving pipes.
A first object of the present invention is to provide a washing machine, in which a distribution pipe guiding circulating water to nozzles is composed of a plurality of outlet ports branched from one transport conduit, while a plurality of port receiving pipes is formed in a gasket to correspond to the plurality of outlet port, thereby uniformly spraying water streams from the plurality of outlet ports.
A second object of the present invention is to provide a washing machine having an optimized position of a circulation pipe connecting the transport conduit and a pump.
A third object of the present invention is to provide a washing machine having a plurality of nozzles spraying washing water into a drum and provided at a gasket, wherein the gasket has a structure capable of being easily molded by an injection technique.
A fourth object of the present invention is to provide a washing machine having two or more nozzles on left and right sides of the gasket, and port receiving pipes formed integrally with the gasket to fix water supply ports supplying circulating water to the nozzles.
A firth object of the present invention is to provide a washing machine having the port receiving pipes disposed in parallel with each other.
A fourth object of the present invention is to provide a washing machine for easily assembling distribution pipes for supplying circulating water to the nozzles into the gasket.
Objects of the present invention should not be limited to the aforementioned objects and other unmentioned objects will be clearly understood by those skilled in the art from the following description.
In a washing machine of the present invention, a tub is provided in a casing having an entry hole formed in a front surface of the casing, a drum is rotatably provided in the tub, and a gasket is installed in the tub.
The gasket includes a gasket body forming a passage connecting the entry hole and an entrance hole of the tub, and first, second, third, and fourth nozzles provided on an inner circumferential surface of the gasket body.
When the gasket body is bilaterally divided into the first area and a second area, the first nozzle and the second nozzle are disposed in a first area sequentially in a bottom-to-top direction, and the second nozzle and the third nozzle are disposed in the second area sequentially in the bottom-top-top direction.
The gasket includes first, second, third, and fourth port receiving pipes respectively communicating with the first, second, third, and fourth nozzles. The first and second port receiving pipes protrude in the first area from an outer circumferential surface of the gasket body. The third and fourth port receiving pipes protrude in the second area from the outer circumferential surface of the gasket body.
There is provided at least one pump configured to pump water discharged from the tub. The water pumped by the pump is guided to the first, second, third, and fourth nozzles through a first distribution pipe and a second distribution pipe.
The first distribution pipe is coupled to the gasket in the first area. The first distribution pipe includes a first inlet port configured to receive some of the water pumped by the at least one pump, a first transport conduit upwardly guiding the water introduced through the first inlet port, and a first outlet port and a second outlet port, which are branched from the first transport conduit sequentially in the bottom-to-top direction to be respectively connected to the first port receiving pipe and the second port receiving pipe.
The second distribution pipe is coupled to the gasket in the second area. The second distribution pipe includes a second inlet port configured to receive some of the water pumped by the at least one pump, a second transport conduit upwardly guiding the water introduced through the second inlet port, and a third outlet port and a fourth outlet port, which are branched from the second transport conduit sequentially in the bottom-to-top direction to be respectively connected to the third port receiving pipe and the fourth port receiving pipe
When a first side and a second side is defined with respect to the first transport conduit, the first inlet port may be disposed in the opposite side of the first and second port receiving pipes with respect to the first transport conduit.
The first distribution pipe and the second distribution pipe may be bilaterally symmetrical.
The first and second outlet ports may extend in a direction toward a virtual vertical reference plane bisecting the passage, and the first inlet port may extend in a direction away from the reference plane.
The first transport conduit may include a first conduit part from which the first and second outlet ports protrude, and a second conduit part bent from a lower end of the first conduit part in a direction toward the outer circumferential surface of the gasket body to be connected to the first inlet port.
The second conduit part may be bent below the first outlet port. The second conduit part may be bent between the first inlet port and the first outlet port.
The first inlet port may extend from the second conduit part in a downward inclined direction. The first inlet port may be orthogonal to the second conduit part.
The first, second, third, and fourth port receiving pipes may extend in a horizontal direction from the outer surface of the gasket body. The first and second outlet ports may be parallel to each other, and the third and fourth outlet ports may be parallel to each other.
The at least one pump may be disposed below the gasket.
In another general aspect of the present invention, there is provided a washing machine including: a casing having an entry hole formed in a front surface of the casing; a tub provided in the casing to contain wash water, and having an entrance hole formed in a front surface thereof; a drum rotatably provided in the tub; a gasket, wherein the gasket comprises a gasket body forming a passage connecting the entry hole and an entrance hole of the tub, a first nozzle and a second nozzle provided on an inner circumferential surface of the gasket body, and a first port receiving pipe and a second port receiving pipe, wherein, when the gasket body is bilaterally divided into a first area and a second area, the first and second nozzles are disposed in the first area sequentially in a bottom-to-top direction, and wherein the first port receiving pipe and the second port receiving pipe protrude from an outer circumferential surface of the gasket body in the first area to respectively communicate with the first and second nozzles; a pump configured to pump water discharged from the tub; and a distribution pipe, the distribution pipe comprises an inlet port coupled to the gasket and introducing the water pumped by the pump, a transport conduit upwardly guiding the water introduced through the inlet port, and a first outlet port and a second outlet port branched from the transport conduit sequentially in the upward direction to be respectively connected to the first and second port receiving pipes.
When a first side and a second side is defined with reference to the transport conduit, the inlet port may be disposed on the opposite side of the first and second port receiving pipes with reference to the transport conduit.
The first and second outlet ports may extend in a direction toward a virtual vertical reference plane including a center of the passage and extending in a front-and-back direction, and the first inlet port may extend in a direction away from the reference plane.
The transport conduit may include a first conduit part from which the first and second outlet ports protrude, and a second conduit part bent from a lower end of the first conduit part in a direction toward the outer circumferential surface of the gasket to be connected to the inlet port.
The first and second outlet ports may be parallel to each other.
The washing machine according to the present invention may have one or more effects, as below.
The washing machine of the present invention may reduce water flow resistance in a transport conduit because circulating water introduced through an inlet port to a distribution pipe is distributed sequentially to a first outlet port and a second outlet port while moving along the transport conduit, and thus, there is an advantage of supplying a uniform amount of water to the first outlet port and the second outlet port.
Second, in the distribution pipe, an inlet port connected to a circulation pipe connected to a pump is disposed lower than the outlet ports, and thus, the circulation pipe can be installed in a space below the tub (especially, the left or right side below the tub).
Effects of the present invention should not be limited to the aforementioned effects and other unmentioned effects will be clearly understood by those skilled in the art from the claims.
The embodiments will be described in detail with reference to the following drawings in which like reference numerals refer to like elements wherein:
Advantages and features of the present disclosure and methods to achieve them will become apparent from the descriptions of exemplary embodiments herein below with reference to the accompanying drawings. However, the present disclosure is not limited to exemplary embodiments disclosed herein but may be implemented in various different ways. The exemplary embodiments are provided for making the disclosure of the present disclosure thorough and for fully conveying the scope of the present disclosure to those skilled in the art. It is to be noted that the scope of the present disclosure is defined only by the claims. Like reference numerals denote like elements throughout the descriptions.
Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.
Referring to
A front panel 11 having an entry hole 12 formed therein may be disposed on a front surface of the casing 10. A door 20 for opening and closing the entry hole 12 may be disposed on the front panel 11, and a dispenser 14 for introducing detergent may be installed at the front panel 11. A control panel 13 for receiving various control commands from a user to control operations of the washing machine may be provided above the front panel 11.
In addition, a water supply valve 15, a water supply pipe 16, and a water supply hose 17 may be installed in the casing 10. Upon a water supply, wash water having passed through the water supply valve 15 and the water supply pipe 16 may be mixed with detergent in the dispenser 14 and then supplied to the tub 30 through the water supply hose 17.
Meanwhile, a direct water supply pipe 18 may be connected to the water supply valve 15 so that wash water can be supplied directly to the tub 30 through the direct water supply pipe 18 without being mixed with detergent. A direct nozzle 19 for spraying the water, supplied through the direct water supply pipe 18, into the drum 40 may be provided.
At least one pump 70 for pumping water discharged from the tub 30 is provided. Water pumped by the at least one pump 70 is supplied to a first distribution pipe 80(1) and a second distribution pipe 80(2). Hereinafter, an example in which water is simultaneously supplied to the first and second distribution pipes 80(1) and 80(2) by one pump 70 is described, but aspects of the present invention are not limited thereto. Instead, a pump for supplying water to the first distribution pipe 80(1) and a pump for supplying water to the second distribution pipe 80(2) may be provided individually.
The pump 70 may be disposed below the gasket 60. Preferably, the pump 70 is disposed on any one of the left and right sides below the gasket 60.
Water guided through the first distribution pipe 80(1) and the second distribution pipe 80(2) is supplied to a plurality of nozzles 66a, 66b, 66c, and 66d provided in the gasket 60. Referring to
The plurality of nozzles 66a, 66b, 66c, and 66d includes two nozzles 66a/b and 66c/d receiving water through the same distribution pipe 80 and disposed at different heights. In the two nozzles 66a/b and 66c/d, one nozzle 66a or 66c at a lower position is referred to as a lower nozzle, and the other nozzle at a position higher than the lower nozzle 66a or 66c is referred to as an upper nozzle.
The distribution pipe 80 may be provided on both sides of the gasket 60. Hereinafter, a distribution pipe disposed on the left side of the gasket 60 is referred to as the first distribution pipe 80(1), and a distribution pipe disposed on the right side of the gasket 60 is referred to as the second distribution pipe 80(2). If the term “first” or “second” is not used, it may be understood that any one of the first distribution 80(1) and the second distribution pipe 80(2) is indicated.
The pump 70 and the tub 30 is connected via a discharge hose 72. The distribution pipe 80 and the pump 70 may be connected directly to each other or may be connected via a circulation pipe 86. In the latter case, a first circulation pipe 86(1) for connecting the first distribution pipe 80(1) to the pump 70 and a second circulation pipe 86(2) for connecting the second distribution pipe 80(2) to the pump 70 may be provided.
If the pump 70 operates, wash water contained in the tub 30 may be guided to the plurality of nozzles 66a, 66b, 66c, and 66d through the first distribution pipe 80(1) and the second distribution pipe 80(2) and then sprayed into the drum 40, thereby circulating the wash water. The pump 70 may be connected to a drain pipe 74 to thereby discharge wash water to the outside through the drain pipe 74.
The above-described pump 70 functions both a circulation pump for circulating wash water and as a drain pump for discharging wash water to the outside. On the contrary, a drain pump and a circulation pump may be installed individually. In this case, it is obvious that the drain pump is connected to the drain pipe 74 and the circulation pump is connected to the circulation pipe 86.
Meanwhile, the tub 30 may be formed as a single tub body or may be formed as a combination of a first tub body 30a and a second tub body 30b coupled thereto. In the embodiment of the present invention, an example in which the first tub body 30a and the second tub body 30b are coupled to form the tub 30 is described. Hereinafter, the first tub body 30a is referred to as a “tub” 30.
An entrance hole 32 is formed at a front surface 31 of the tub 30 to correspond to the entry hole 12 formed in the front panel 11. At least one balancer 90 may be fastened to the front surface 31 of the tub 30. A first balancer 90(1) may be disposed over the front surface 31, and a second balancer 90(2) may be disposed under the front surface 31.
The gasket 60 is disposed between an edge defining the entry hole 12 of the front panel 11 and an edge defining the entrance hole 32 of the tub 30. The gasket may be formed of a flexible substance such as rubber and have an approximate cylindrical shape to thereby form a passage 60P connecting the entry hole 12 and the entrance hole of the tub 30.
The front boundary of the gasket 60 is connected to the edge of the entry hole 12 of the front panel 11, and the rear boundary of the gasket 60 is connected to the edge of the entrance hole of the tub 30, thereby sealing a space between the tub 30 and the front panel 11. In a state in which the door 20 is closed, the door 20 and the front end of the gasket 60 are tightly brought into contact with each other and the space between the door 20 and the gasket 60 is sealed, and therefore, leakage of wash water is prevented.
Referring to
The circumference of the entry hole 12 in the front panel 12 may be rolled outward, and the casing coupling part 61 may be fitted in a concave area formed by the outward rolled portion. An annular groove 61r to be wound by a wire may be formed in the casing coupling part 61. After the wire is wound around the groove 61r, both ends of the wire are bound, and therefore, the casing coupling part 61 is tightly fixed to the circumference of the entry hole 12.
The circumference of the entrance hole of the tub 30 is rolled outward, and the tub coupling part 62 is fitted in a concave area formed by the outward rolled portion. An annular groove 62r to be wound by a wire may be formed in the tub coupling part 62. After the wire winds around the groove 62r, both ends of the wire are bound, and therefore, the tub coupling part 62 is tightly coupled to the entrance hole of the tub 30.
While the casing coupling part 61 is fixed to the front panel 11, the tub coupling part 62 is displaceable in accordance with movement of the tub 30. Accordingly, the gasket body 63 needs to be able to transform in accordance with the displacement of the tub coupling part 62. In order to allow the gasket body 63 to transform easily, the gasket 60 may include a folding part 63b between the casing coupling part 61 and the tub coupling part 62 (or the gasket body 63), and the folding part 63b is folded as the tub 30 moves in a direction of eccentricity (or a radial direction).
More particularly, an annular rim part 63a extending from the casing coupling part 61 toward the tub coupling part 62 (or toward the rear) is formed in the gasket body 63, and the folding part 63b may be formed between the rim part 63a and the tub coupling part 62.
The gasket 60 may include an outer door contact part 68 that bends outward from the front end of the rim part 63a to be brought into contact with a rear surface 20 of the door 20 in the outside of the entry hole 12 in a state in which the door 20 is closed. In the casing coupling part 61, the above-described groove 61r may be formed at a portion extending from the outer end of the outer door contact part 68.
The gasket 60 may further include an inner door contact part 66 that bends inward from the front end of the rim part 63a to be brought into contact with the rear surface (preferably the window 22) of the door 20 in the inside of the entry hole 12 in a state in which the door 20 is closed.
Meanwhile, during rotation, the drum 40 vibrates (which means that the rotation center line C of the drum 32 moves) and, in turn, the center line of the tub 30 (which is approximately identical to the rotation center line C of the drum 40) moves as well. In this case, a moving direction (hereinafter, referred to as an eccentric direction”) has a radial direction component.
The folding part 63b is folded or unfolded when the tub 30 moves in the eccentric direction. The folding part 63b may include an inner circumferential portion 631 bent from the rim part 63a toward the casing coupling part 61, and an outer circumferential portion 632 bent from the inner circumferential portion 631 toward the tub coupling part 32 to be thereby connected to the tub coupling part 62. When viewed from the front, the inner circumferential portion 631 is disposed in the inside surrounded by the outer circumferential portion 632. As shown in
If a portion of the folding part 63b is folded when the center of the tub 30 moves in the eccentric direction, a distance between the inner circumferential portion 631 and the outer circumferential portion 632 at the portion is reduced, whereas the folding part 62 is unfolded at a portion opposite to the folded portion and thereby a distance between the inner circumferential portion 631 and the outer circumferential portion 632 at the opposite portion is increased.
Meanwhile, the plurality of nozzles 66a, 66b, 66c, and 66d includes a first nozzle 66a, a second nozzle 66b, a third nozzle 66c, and a fourth nozzle 66d. If the gasket body 63 is bilaterally divided into a first area I and a second area II (see
Particularly, a first port receiving pipe 64a and a second port receiving pipe 64b protrude from an outer circumferential surface of the gasket body 63 in the first area I. The first and second port receiving pipes 64a and 64b communicate with the first and second nozzles 66a and 66b, respectively. The first and second port receiving pipes 64a and 64b may be parallel to each other.
A third port receiving pipe 63c and a fourth port receiving pipe 64d protrude from the outer circumferential surface of the gasket body 63 in the second area II. The third and fourth port receiving pipes 64c and 64d communicate with the third and fourth nozzles 66c and 66d, respectively. The third and fourth port receiving pipes 64c and 64d may be parallel to each other. The first distribution pipe 80(1) and the second distribution pipe 80(2) are installed at the gasket 60. Each of the distribution pipes 80(1) and 80(2) includes an inlet port 81 introducing water discharged from the pump 70, a transport conduit 82 guiding the water introduced through the inlet port, and a plurality of outlet ports 83 and 84 branched from the transport conduit 82.
The plurality of outlet ports 83 and 84 includes two outlet ports 83 and 84 formed at different heights. Hereinafter, a outlet port at a lower position in the two outlet ports 83 and 84 is referred to as a first outlet port 83 or a lower outlet port, and a outlet port disposed at a position higher than the first outlet port 83 is referred to as a second outlet port 84 or an upper outlet port. The first outlet port 83 and the second outlet port 84 may be provided in each of the first distribution pipe 80(1) and the second distribution pipe (2).
The transport conduit 82 is disposed external to the passage 60P defined by the gasket 60, and guides water, introduced through the inter port, in an upward direction. The transport conduit 82 forms a flow path communicating with the inlet port 81, and the flow path may bend in a shape approximately corresponding to the circumferential surface of the gasket 60 and extend in a vertical direction.
Specifically, the first distribution pipe 80(1) is coupled to the gasket 60 in the first area I. The first distribution pipe 80(1) includes: a first inlet port 1 introducing some of water pumped by the pump 70; a first transport conduit 82 upwardly guiding the water introduced through the first inlet port 81; and a first outlet port 83 and a second outlet port 84, which are branched from the first transport conduit 82 to be respectively connected to the first port receiving pipe 64a and the second port receiving pipe 64b.
In the first transport conduit 82, the second outlet port 84 is disposed higher than the first outlet port 83. Accordingly, some of water guided upwardly along the first transport conduit 82 is branched into the first outlet port 83 and the rest of the water is branched into the second outlet port 84.
Likewise, the second distribution pipe 80(2) is coupled to the gasket 60 in the second area II. The second distribution pipe 80(2) includes: a second inlet port 81 introducing the other (or the rest) of the water pumped by the pump 70; a second transport conduit 82 upwardly guiding the water introduced through the second inlet port; and a third outlet port 83 and a fourth outlet port 84, which are branched from the second transport conduit 82 to be respectively connected to the third port receiving pipe 64c and the fourth port receiving pipes 64d.
In the second transport conduit 82, the fourth outlet port 84 is disposed higher than the third outlet port 83. Accordingly, some of the water guided upwardly along the second transport conduit 82 is branched into the third outlet port 83 and the rest of the water is branched into the fourth outlet port 84.
Through the inlet port 81, water discharged from the pump 70 is introduced. The inlet port 81 may be connected to the pump 70 by the circulation pump 86(1) or 86(2). Circulation ports 71a and 71b may be provided in the pump 70, and the number of circulation ports 71a and 71b (see
Circulating water transported along the transport conduit 82 is discharged through the plurality of outlet ports 83 and 84. The plurality of outlet ports 83 and 84 is branched from the transport conduit 82 at the upper side of the inlet port 81. That is, entrance holes of the outlet ports 83 and 84 (that is, portions at which the outlet ports 83 and 84 are connected to the transport conduit 82) are disposed higher than an exit hole of the inlet port 81 (that is, a portion at which the inlet port 81 is connected to the transport conduit 82).
If the first distribution pipe 80(1) and/or the second distribution pipe 80(2) is divided into a first side and a second side with reference to the transport conduit 82, the inlet port 81(1) or 81(2) may be disposed on the first side with reference to the transport conduit 82(1) or 82(2), and the outlet ports 83a/b and 83c/d may be disposed on the second side. In other words, the inlet port 81(1) or 81(2) may be disposed in the opposite side of the outlet ports 83a/b and 83c/d with reference to the transport conduit 82(1) or 82(2). The port receiving pipes 64a/b and 64c/d of the gasket 60 are disposed on the same side of the outlet ports 83a/b or 83c/d with respect to the transport conduit 82(1) or 82(2), and the inlet port 81(1) or 81(2) is disposed in the opposite side to the port receiving pipes 64a/b, 64c/d with respect to the transport conduit 82(1) or 82(2).
If a virtual vertical reference plane OV (see
Reaction force by pressure of water discharged from the outlet ports 83a, 83b, 83c, ad 83d is applied in a direction in which the distribution pipe 80 becomes away from the gasket 60, but a water stream introduced to the transport conduit 82(1) or 82(2) through the inlet port 81(1) or 81(2) is applied in a direction in which the inlet port 81(1) or 81(2) is pushed toward the gasket 60. Accordingly, there is an effect of preventing separation of the distribution pipe 80 from the gasket 60.
In other words, the lower outlet port 83a or 83c and the upper outlet port 83b or 83d may be disposed on the first side of the transport conduit 82 (that is, any one of the left and right sides of the transport conduit 82 when viewed from the front). The lower outlet port 83a or 83c and the upper outlet port 83b or 83d may extend in parallel with each other. In addition, the inlet port 81 may be disposed in the second side of the transport conduit 82, which is opposite to the first side.
Water streams discharged through the lower/upper outlet ports 83a and 83c/83b and 83d are toward the first side from the transport conduit 82. Accordingly, pressure of injecting the water stream acts as a reaction force, and the transport conduit 82 is pushed toward the second side. Here, the second side indicates a direction in which the upper outlet ports 83b and 83d are separated from the upper port receiving pipes 64b and 64d.
On the contrary, the inlet port protrudes from the transport conduit 82 in a direction opposite to the direction in which the upper outlet ports 83 and 83d protrude. Accordingly, a water stream introduced through the inlet port 81 acts with a force of pushing the transport conduit 82 toward the first side, thereby preventing the upper outlet ports 83b and 83d from being separated from the upper port receiving pipes 64b and 64d.
Meanwhile, referring to
Since the first conduit part 82a and the second conduit part 82b are bent, water flow resistance occurs at the bent portions. That is, resistance occurs when a water stream is introduced from the second conduit part 82b to the first conduit part 82a. Thus, the water stream does not pass through the lower outlet port 82 but is reflected and refracted from an inner surface of the conduit part 82 to be guided to the lower outlet port 83. Accordingly, a sufficient amount of water can be discharged through the lower outlet port 83.
A surface on which an exit hole of the inlet port 81 (that is, a hole through which circulating water is discharged from the inlet port 81) is formed may include a portion 82c orthogonal to the inlet port 81. The orthogonal portion 82c may be substantially flat. The inlet port 81 may extend from the orthogonal portion 82c in the shape of a substantially straight line (or plane). At the orthogonal portion 82c, a flow path in the transport conduit 82 may extend in a direction substantially orthogonal to the inlet port 81.
While moving upwardly along the transport conduit 82, circulating water introduced through the inlet port is discharged through the lower outlet port 83a or 83c and the rest of the water is discharged through the upper outlet port 83b or 83d. In particular, while water is guided in one direction (the upward direction) along the transport conduit 82, the water is branched sequentially into the lower outlet port 82a or 83c and the upper outlet port 83b or 83d, and hence, water flow resistance in the transport conduit 82 is almost consistent. In order to ensure that a uniform amount of water is discharged from the lower outlet port 83a or 83c and from the upper outlet port 83b or 83d, if the outlet ports 83a, 83b, 83c, and 83d, the nozzle, and the transport conduit 82 are designed to have proper inner diameters, a uniform amount of circulating water may be sprayed from the lower outlet port 82a or 83c and the upper outlet port 83b or 83d.
Meanwhile, in the assumption that the inlet port 81 comes into contact with the transport conduit 82 between the lower outlet port 83a or 83c and the upper outlet port 83b or 83d, circulating water introduced through the inlet port 81 is branched vertically and discharged through the upper outlet port 83b or 83d and the lower outlet port 83a or 83c. In this case, in a section where the circulation water is branched vertically, excessive water flow resistance occurs, which causes interference of the water stream in the flow path, thereby supplying a non-uniform amount of water to the lower/upper outlet ports 83a and 83c/83b and 83d.
Meanwhile, the pump 70 may be a speed-variable pump capable of varying speed (or varying a discharge volume). In this case, if the inlet port 81 is disposed between the lower outlet port 83a or 83c and the upper outlet port 83b or 83d and the pump 70 rotates at a low speed (that is, a low discharge volume), the effect of gravity is greater compared to when the pump 70 rotates at a high speed. As a result, there are problems that an amount of water branched to the lower side is considerably larger an amount of water branched in the transport conduit 82 to the upper side, and that a less amount of water is discharged through the upper outlet port 83b or 83d, compared to the present invention.
The port receiving pipes 64a, 64b, 64c, and 64d may be formed on the outer circumferential surface 61 of the gasket 60 and protrude outward of the gasket 60 to correspond to the four outlet ports. Each of port receiving pipes 64a, 64b, 64c, and 64d is in an annular shape. One end of each of the port receiving pipes 64a, 64b, 64c, and 64d is connected to a corresponding nozzle in the nozzles 66a, 66b, 66c, and 66d, and the other end of each of the port receiving pipes 64a, 64b, 64c, and 64d is connected to a outlet port 83 or 84. Four outlet ports 83 or 84 may be inserted into and connected to the four port receiving pipes 64a, 64b, 64c, and 64d, respectively.
Four nozzles 66a, 66b, 66c, and 66d respectively communicating with the four port receiving pipes 64a, 64b, 64c, and 64d are provided in the inner circumferential surface 62 of the gasket 60. In one embodiment of the present invention, the nozzles 66a, 66b, 66c, and 66d are formed integrally with the gasket. On the contrary, nozzles may be formed as components separate from the gasket 60 and may be coupled to the gasket 60 or may be flow-path-connected to the port receiving pipes 64a, 64b, 64c, and 64d while separate from the gasket 60.
Meanwhile, the first balancer 90(1) is disposed at the front surface 31 of the tub 30. The first balancer 90(1) may include a spaced-apart space 91 that is horizontally spaced apart from the outer circumferential surface of the gasket 60 to define an assembly space AS between the spaced portion 91 and the outer circumferential surface.
The transport conduit 82 may include a portion 82d disposed in the assembly space AS. The second outlet port 84 protrudes from the portion 82d. The upper outlet port 83b or 83d is inserted into the upper port receiving pipe 64b or 64d within the assembly space AS.
Accordingly, even in the case where the upper outlet port 83b or 83d moves in a horizontal direction due to pressure of circulating water discharged from the upper outlet port 83b or 83d or due to vibration of the tub 30, movement of the upper outlet port 83b or 83d is limited because the portion 82d contacts (or is interfered with) the first balancer 90(1). Accordingly, it is possible to prevent separation of the upper outlet port 83b or 83d from the upper port receiving pipe 64b or 64d.
Meanwhile, the first distribution pipe 80(1) and the second distribution pipe 80(2) may be bilaterally symmetrical with respect to the gasket 60. In this case, the port receiving pipes 64a, 64b, 64c, and 64d in the gasket 60 may be bilaterally symmetrical. In addition, the first distribution pipe 80(1) and the second distribution pipe 80(2) have the substantially same structure, and may be used by inversing from left to right or vice versa depending on an installation position.
Although some embodiments have been described above, it should be understood that the present invention is not limited to these embodiments, and that various modifications, changes, alterations and variations can be made by those skilled in the art without departing from the spirit and scope of the invention. Therefore, it should be understood that the above embodiments are provided for illustration only and are not to be construed in any way as limiting the present invention.
Number | Date | Country | Kind |
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10-2018-0074393 | Jun 2018 | KR | national |
10-2019-0075429 | Jun 2019 | KR | national |
This application is a continuation of U.S. application Ser. No. 16/455,277, filed on Jun. 27, 2019, which claims the priority benefit of Korean Application No. 10-2019-0075429, filed on Jun. 25, 2019, and Korean Application No. 10-2018-0074393, filed on Jun. 27, 2018. The disclosures of the prior applications are incorporated by reference in their entirety.
Number | Date | Country | |
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Parent | 16455227 | Jun 2019 | US |
Child | 17692388 | US |