Patent Application
20160115642
Pursuant to 35 U.S.C. §119(a), this application claims the benefit of earlier filing date and right of priority to Korean Application No. 10-2014-0147565, filed on Oct. 28, 2014, the contents of which is incorporated by reference herein in its entirety.
1. Field
This specification relates to a clothes treating apparatus.
2. Background
A clothes treating apparatus (a laundry machine or a laundry treating apparatus) is a concept including an apparatus for washing or drying clothes, and an apparatus for simultaneously washing and drying clothes.
Clothes treating apparatuses which can dry clothes are configured to supply air of high temperature (hot air) to the clothes and may be classified into an exhaust type and a circulation type (condensing type) on the basis of an air flowing method.
The circulation type clothes treating apparatus is configured to circulate air of a clothes receiving unit storing clothes, in a manner of removing moisture (dehumidifying) from the air discharged from the clothes treating apparatus, heating the dehumidified air, and supplying the heated air back into the clothes receiving unit.
The exhaust type clothes treating apparatus is configured to supply heated air to a clothes receiving unit, in a manner of exhausting air discharged from the clothes receiving unit to outside of the clothes treating apparatus without circulation.
Meanwhile, a discharge passage provided in the related art clothes treating apparatus has a problem that condensed water generated in an evaporator may flow back into a heat exchanger due to negative pressure between the evaporator and a condenser, which causes odor and other problems due to the backflow from the discharge passage. The clothes treating apparatus of the present disclosure addresses these and other disadvantages.
The above references are incorporated by reference herein where appropriate for appropriate teachings of additional or alternative details, features and/or technical background.
The embodiments will be described in detail with reference to the following drawings in which like reference numerals refer to like elements wherein:
Description will now be given in detail of the preferred embodiments according to the present disclosure, with reference to the accompanying drawings. Meanwhile, a configuration or control method to be described hereinafter is merely illustrative and will not limit the rights of the present disclosure. For the sake of brief description with reference to the drawings, the same or equivalent components may be provided with the same or similar reference numbers, and description thereof will not be repeated.
The cabinet 1 includes an introduction opening 11 through which clothes is introduced therein, and a door 13 rotatably coupled to the cabinet 1 to open and close the introduction opening 11.
When the clothes treating apparatus 100 according to the present disclosure is merely configured as a drying machine which has a clothes drying function, the clothes receiving device 2 and 3 may include only a drum 3 rotatably disposed in the cabinet 1.
Also, when the clothes treating apparatus 100 is configured as an apparatus which has both functions of washing and drying clothes, the clothes treating apparatus 2 and 3 may include a tub 2 disposed in the cabinet 1 to store wash water therein, and a drum 3 rotatably disposed in the cabinet 2 to store the clothes therein.
The tub 2 may have a cylindrical shape with a hollow inner space and be fixed in the cabinet 1. The tub 2 includes a tub introduction opening 21 formed at a front surface of the tub 2 facing the introduction opening 11, such that the clothes or laundry can be introduced and removed through the tub introduction opening 21.
A gasket 23 may be provided between the tub introduction opening 11 and the introduction opening 11. The gasket 23 may prevent wash water stored in the tub 2 from being leaked out of the tub 2 and also may prevent vibration generated in the tub 2 during rotation of the drum 3 from being transferred to the cabinet 1. Therefore, the gasket 23 may be made of a vibration-insulating material, such as rubber.
The tub 2 may be arranged in parallel to the ground, or to be inclined from the ground by a predetermined angle. However, when the tub 2 is inclined from the ground by the predetermined angle, the inclined angle of the tub 2 is preferably smaller than 90°.
An air exhaust portion 27 through which internal air of the tub 2 is exhausted may be provided on an upper portion of a circumferential surface of the tub 2, and a water drain portion 25 through which the wash water stored in the tub 2 is discharged may be provided below the tub 2.
The air exhaust portion 27 may be provided on the upper surface of the tub 2, preferably, spaced apart from a straight line A, which passes through a center of the tub 2, by a predetermined distance L1 in a circumferential direction of the tub 2. This facilitates the internal air of the tub 2 to be discharged out of the tub 2 through the air exhaust portion 27 during the rotation of the drum 3.
The water drain portion 25 may include a first drain pipe 251 through which a drain pump 255 is connected to the tub 2, and a second drain pipe 253 that guides the wash water introduced into the drain pump 255 to the outside of the cabinet 1.
The tub 2 stores wash water that is supplied through a water supply pipe 151 which connects the tub 2 to a water supply source. Here, when a detergent supply unit 15 for supplying detergent is provided at the cabinet 1, the water supply pipe 151 may be configured to supply wash water to the detergent supply unit 15 therethrough. In this instance, the wash water supplied to the detergent supply unit 15 may then be supplied into the tub 2 through a detergent supply pipe 153.
The drum 3 may have a cylindrical shape with a hollow inner space, and be rotatably disposed in the tub 2. The drum 3 is rotatable by a driving unit provided outside of the tub 2. In this instance, the driving unit may include a stator 335 fixed to a rear surface of the tub 2 to generate a magnetic field, a rotor 331 rotated by the magnetic field, and a rotation shaft 333 penetrating through the rear surface of the tub 2 to connect a rear surface of the drum 3 to the rotor 331.
In the meantime, the drum 3 may include a drum introduction opening 31 formed at a front surface thereof, so as to communicate with the introduction opening 11 and the tub introduction opening 21. A user may thus put clothes or laundry into the drum 3 and take the clothes stored in the drum 3 out of the cabinet 1 through the introduction opening 11.
As illustrated in
The circulation passage may include a first connection duct 53 connected to the upper portion of the circumferential surface of the tub 2, a duct 51 connected to the first connection duct 53 and provided with the heat-exchanging device 59 therein, and a second connection duct 55 to guide air discharged from the duct 51 toward the front side of the tub 2.
The first connection duct 53 may be a passage connected to the air exhaust portion 27 located at the upper portion of the circumferential surface of the tub 2, and preferably formed as a vibration-insulating member (rubber, etc.). This is to prevent the vibration transferred to the tub 2 during the rotation of the drum from being carried to the heat-exchanging device 59 located in the duct 51 through the first connection duct 53. To more efficiently prevent the vibration generated in the tub 2 from being transferred to the duct 51 and the heat-exchanging device 59, the first connection duct 53 may be formed in a shape of a bellows.
The second connection duct 55 may be connected to any area of the tub 2 if the area is allowed to guide the air discharged through the duct 51 toward the front side of the tub 2.
The blower 57 may be provided at the second connection duct 55. The blower 57 may include an impeller (not illustrated) located in the second connection duct 55, and an impeller motor (not illustrated) to rotate the impeller.
As illustrated in
The heat-exchanging device 59 according to the present disclosure may be configured as a heat pump. Here, a first heat exchanger 591 (i.e., an evaporator) and a second heat exchanger 593 (i.e., a condenser) provided in the heat-exchanging device 59 may be fixed to the first mounting portion 515. A compressor 595 may be configured to compress a refrigerant discharged from the evaporator 591 and supply the compressed refrigerant to the condenser 593. The refrigerant supplied to the condenser 593 may be supplied back into the evaporator 591 via an expansion apparatus.
In the evaporator 591, the refrigerant is evaporated by absorbing heat from air introduced into the duct 51. Therefore, the evaporator 391 serves to remove moisture (dehumidify) contained in air by cooling the air.
The condenser 593 condenses the refrigerant. Since heat generated during the process of condensing the refrigerant is transferred to air passing through the condenser, the condenser 593 serves to heat the air passed through the evaporator 591.
Here, the condensed water is generated in the evaporator 591 while the refrigerant removes moisture (dehumidifies) from air introduced into the duct 51. Hence, a structure for discharging the condensed water is required.
The condensed water generated in the evaporator 591 is discharged out of the clothes treating apparatus along the discharge duct. Here, pressure gradients are generated to suck air through the air exhaust opening 27 provided at the tub 2 and discharged to the supply portion 29 provided at the tub 2.
During this, negative pressure is generated between the evaporator 591 and the condenser 593. As a result, the condensed water generated in the evaporator 591 may not be discharged out along the discharge duct, but may flow back into the duct 51 or allow gases from the drain to flow back into the duct 51 causing odors.
To prevent this problem, the condensed water discharge device 54 according to the present disclosure is provided with a back-flow preventing member. In one embodiment, the back-flow preventing member may be a discharge pipe 541.
The discharge pipe 541 may include an inclined portion 5411 (upper section) protruding from a lower surface of the duct 51 in an inclined manner, and a vertical portion 5413 (lower section) that extends from an end of the inclined portion 5411. The upper section may be inclined to extend downward at a prescribed angle. The vertical portion 5413 may extend vertically or perpendicular to the bottom surface of the condensed water discharge unit 54. Moreover, it should be appreciated that the vertical portion 5413 may be substantially vertical or sufficiently angled such that condensed water may easily flow down the discharge pipe 541.
The vertical portion 5413 may include a first portion 5433 having a first cross-section 5415, and a second portion 5473 having a second cross-section 5417. The first cross-section 5415 may be greater than the second cross-section 5417, and the first cross-section 5415 may be located above the second cross-section 5417. The vertical portion 5413 may be formed linear such that the first portion 5433 and second portion 5473 are also linear and may extend perpendicular to the condensed water discharge unit 54.
The vertical portion 5413 may include a bottleneck portion 5453 that is formed between the first portion 5433 and the second portion 5473 in a manner in which its cross-section gets narrower from the first portion to the second portion. That is, the width of the bottleneck portion 5453 may gradually decrease downward. Moreover, a width of the first portion 5433 and a width of the second portion 5473 in the vertical portion 5413 (lower section) of the discharge pipe may be configured such that condensed water is accumulated above the lower portion to prevent backflow of gas and condensed water into the circulation passage. The bottleneck portion 5453 may thus function as a reservoir in which the condensed water is stored or accumulated.
The shape of the vertical portion 5413 makes the condensed water seem to be stuck (stored or collected) in the reservoir, which may prevent the condensed water and odor from flowing back into the duct 51 through the discharge duct.
The bottleneck portion 5453 becomes gradually narrower from the first cross-section 5415 toward the second cross-section 5417. Here, a height h from the bottleneck portion 5453 to a point where the inclined portion 5411 is brought into contact with the duct 51 is preferably at least 120 mm or more.
Negative pressure is generated in the duct 51 due to rotation of the blower 57. Accordingly, the condensed water generated during drying is kept stored in the discharge duct.
Therefore, by virtue of the structure that the height from the bottleneck portion 5453 to the contact point between the inclined portion 5411 and the duct 51 is preferably at least 120 mm or more, the condensed water which is kept stored in the discharge duct can be prevented from flowing back into the duct 51.
However, the present disclosure may not be limited to the numeral value of 120 mm, and the numeral value may vary depending on a rotating speed of the blower 57, a size of the duct 51 and a size of the heat-exchanging device 59.
That is, when about 40 to 50 cc/min of condensed water is generated per minute, it may be preferable in a typical heat pump cycle that the height from the bottleneck portion 5453 to the contact point between the inclined portion 5411 and the duct 51 is at least 120 mm or more.
The U-shaped pipe 544 may have one end communicating with the first discharge pipe 542 and another end communicating with the second discharge pipe 543 and formed in a U-like shape. The U-shaped pipe 544 may allow the first discharge pipe 542 to be in communication with the second discharge pipe 543 and may be formed in the shape like an alphabet “U.”
Condensed water that flows down along the first discharge pipe 542 may be collected in the U-shaped pipe 544. Also, the another end of the second discharge pipe 543 is configured to communicate with external air such that air pressure and a weight of the condensed water are balanced, thereby preventing backflow of the condensed water and odors from the drain.
The check valve 545 is a device which allows a fluid or gas flowing therein to be transferred only in one direction. When the check valve 545 is provided between the first discharge pipe 542 and the second discharge pipe 543, the condensed water generated in the heat-exchanging device 59 is forced to flow from the first discharge pipe 542 only to the second discharge pipe 543. This may prevent the condensed water from flowing from the second discharge pipe 543 back to the first discharge pipe 542 or allow gases from the drain to flow backward causing odors.
The pump 546 is a type of a pump that is generally used in the clothes treating apparatus according to the present disclosure, and thus detailed description thereof will be omitted.
The pump 546 may be provided between the first discharge pipe 542 and the second discharge pipe 543 to communicate them with each other, so as to force the condensed water generated in the heat-exchanging device 59 to flow from the first discharge pipe 542 only to the second discharge pipe 543. Therefore, the condensed water or odors from the drain cannot flow back into the first discharge pipe 542 from the second discharge pipe 543.
As broadly described and embodied herein, one aspect of the detailed description is to provide a clothes treating apparatus capable of preventing condensed water generated in an evaporator and odors from a drain from flowing back into a heat exchanger.
To achieve these and other advantages and in accordance with the purpose of this specification, in one embodiment, a clothes treating apparatus may include a clothes receiving unit providing a space for receiving clothes therein, a circulation passage provided in the clothes receiving unit and providing a space for air to circulate, a heat-exchanging unit provided in the circulation passage and configured to dehumidify air introduced into the circulation passage, a blower provided in the circulation passage and configured to circulate air within the clothes receiving unit, and a condensed water discharge unit provided at one surface of the circulation passage and configured to discharge condensed water generated in the heat-exchanging unit, wherein the condensed water discharge unit has one end communicating with the one surface of the circulation passage and another end with a section getting narrow.
Also, the condensed water discharge unit may include an inclined portion communicating with one surface of the circulation passage and protruding from a lower surface of the circulation passage in an inclined manner, and a perpendicular portion having one end communicating with the inclined portion and another end protruding in a direction perpendicular to the lower surface of the circulation passage.
The perpendicular portion may include a first perpendicular portion with a first section, a second perpendicular portion having a second section narrower than the first section, and a bottleneck portion formed from the first perpendicular portion to the second perpendicular portion in a manner that a section thereof is getting narrow.
The bottleneck portion may have one end with the first section and another end with the second section getting narrow from the first section. A height from an upper surface of the bottleneck portion to a portion where the inclined portion is brought into contact with the circulation passage is 120 mm.
In one embodiment, a clothes treating apparatus may include a clothes receiving unit providing a space for receiving clothes therein, a circulation passage provided in the clothes receiving unit and providing a space for air to circulate, a heat-exchanging unit provided in the circulation passage and configured to dehumidify air introduced into the circulation passage, a blower provided in the circulation passage and configured to generate negative pressure within the heat-exchanging unit so as to transfer the dehumidified air in the heat-exchanging unit, and a condensed water discharge unit provided at one surface of the circulation passage and configured to discharge condensed water generated while in the heat-exchanging unit dehumidifies air, wherein the condensed water discharge unit includes a backflow-preventing member.
The backflow-preventing member may be a U-shaped pipe. The condensed water discharge unit may include a first discharge pipe having one end communicating with the circulation passage and another end communicating with the U-shaped pipe, a second discharge pipe having one end communicating with the U-shaped pipe, and the U-shaped pipe having one end communicating with the first discharge pipe and another end communicating with the second discharge pipe so as to prevent the backflow of the condensed water.
The backflow preventing member may be a check valve. The condensed water discharge unit may include a first discharge pipe having one end communicating with the circulation passage and another end communicating with the check valve, a second discharge pipe having one end communicating with the check valve, and the check valve having one end communicating with the first discharge pipe and another end communicating with the second discharge pipe, so as to prevent the backflow of the condensed water.
The backflow-preventing member may be a pump. The condensed water discharge unit may include a first discharge pipe having one end communicating with the circulation passage and another end communicating with the pump, a second discharge pipe having one end communicating with the pump, and the pump having one end communicating with the first discharge pipe and another end communicating with the second discharge pipe, so as to prevent the backflow of the condensed water.
Any reference in this specification to “one embodiment,” “an embodiment,” “example embodiment,” etc., means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the disclosure. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the purview of one skilled in the art to effect such feature, structure, or characteristic in connection with other ones of the embodiments.
Although embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2014-0147565 | Oct 2014 | KR | national |
