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. 10-2016-0001193, filed on Jan. 5, 2016, the contents of which is incorporated by reference herein in its entirety.
A garment processing apparatus that prevents fluid from flowing back through a condensed water discharge pipe is disclosed herein.
A garment processing apparatus may remove contamination from laundry by putting clothes, bedding, etc. (hereinafter referred to as laundry) into a drum. The garment processing apparatus may perform processes such as washing, rinsing, dehydration, and drying. The garment processing apparatus may be classified as a top loading type or a front loading type based on a method of loading laundry into the drum. The front loading type washing machine may be generally called a drum washing machine. The garment processing apparatus may generally include a cabinet forming an outer appearance, a tub received in the cabinet, a drum rotatably mounted inside the tub and to receive laundry, and a detergent supply device to supply detergent into the drum.
A garment processing apparatus may have a drying function in addition to a washing function. When washing is completed, it may be possible to evaporate the moisture of the laundry by supplying hot air into the drum. For this, a duct, or a passage through which air is circulated, a heat exchanger installed inside the duct, and a fan motor generating the flow of air may be located at an upper end of the drum in the garment processing apparatus.
As air flows through in the duct, after condensed water is generated from the air passing through the heat exchanger and is collected in the condensed water discharge part, the condensed water may be discharged along the condensed water discharge pipe through a discharge part located at the lower end of the drum. Although there is a description for a conventional apparatus in which condensed water is generated from a heat exchanger in a garment processing apparatus, as for a disclosure relating to a configuration for separately collecting and extracting condensed water as described above, since a condensed water discharge part and a drain part are connected to discharge condensed water generated inside a duct and a fan motor part has a lower pressure than the drain part due to the drive of a fan motor in order for the air flow inside the duct, there may be an issue that air flows backward toward the condensed water discharge part in the drain part.
When air flows backward toward the condensed water discharge part, since air the flows toward the heat exchanger, the efficiency of the heat exchanger may drop. Therefore, unnecessary energy consumption may occur and due to this, vibration, noise and the like may additionally be generated. 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:
Referring to
Referring to the
A refrigerant passing through the evaporator 21 may absorb heat from the surrounding air. Accordingly, since a surrounding temperature becomes low, moisture in the air passing through the evaporator 21 may be condensed. Therefore, the condensed water 90 may be generated. The condensed water 90 may be collected in a condensed water discharge part or tray 40 located at a relatively lower height than the heat exchange 20 and flow through the condensed water discharge pipe 100 connecting the condensed water discharge part 40 at an upper end and a drain part (or drain) 50 at a lower end.
When the fan motor 30 is driven to circulate air in the duct 10, a portion where the fan motor 30 is driven may generate a relatively low pressure, or negative pressure. As the negative pressure is generated, since the drain part 50 has a relatively higher pressure than the condensed water discharge part 40, a fluid backflow phenomenon that fluid flows along the condensed water discharge pipe 100 from the drain part 50 toward the condensed water discharge part 40 may occur. Herein, fluid may mean air or water and generally means air.
When air flows back toward the condensed water discharge part 40, since the air flows into the heat exchanger 20 located at a portion of the condensed water discharge part 40, this may deteriorate the performance of the heat exchanger 20. Specifically, the air flowing toward the condenser 22 through the condensed water discharge pipe 100 does not pass through the evaporator 21 and thus may have a high humidity state and a relatively high temperature. Thus, this may deteriorate the condensation efficiency of a refrigerant passing through the condenser 22. Accordingly, by preventing the air backflow, the efficiency of the heat exchanger 20 may be maintained and unnecessary power consumption may be prevented.
In
As shown in
Additionally, since washing water used in the drum 60 of the garment processing apparatus is collected in the drain pump room 51, both the washing water and the condensed water 90 may be received in the drain pump room 51. Since the washing water and the condensed water 90 are received in the drain pump room 51, air may be prevented from flowing toward the condensed water discharge pipe 100 connecting the condensed water discharge part 40 and the drain pump room 51. By The condensed water 90 received in the condensed water discharge part 40 and the washing water 91 and the condensed water 90 received in the drain pump room 51, air may be prevented from flowing back toward the duct 10 through the condensed water discharge pipe 100.
Referring to
Referring to
The air passing through the evaporator 21 may be condensed as a temperature becomes lower by a refrigerant flowing inside the evaporator 21, so that the condensed water 90 is generated. The condensed water 90 may be collected in the condensed water discharge part 40 having a relatively low height at the lower part of the duct 10 and provided at the bottom surface of the duct 10 and then flow toward the drain part 50 along the condensed water discharge pipe 100.
Referring to
Referring to
The condensed water discharge pipe 100 may connect the condensed water discharge part 40 at the upper end and the drain part 50 at the lower end to provide a passage through which the condensed water 90 flows. The condensed water discharge pipe 100 may be connected to the drain pump room 51 of the drain part 50. The drain part 50 may include the drain pump room 51, the drain pump 52, the drain hose 53, and the drain part connection pipe 54.
Washing water 91 discharged from the drum and the condensed water 90 flowing through the condensed water discharge pipe 100 may be stored in the drain pump room 51. The washing water 91 and the condensed water 90 may be stored in the drain pump room 51 and one end of the condensed water discharge pipe 100 may be connected to the drain pump room 51. Therefore, the backflow of air toward a duct through the condensed water discharge pipe 100 may be limited.
The drain part connection pipe 54 may allow the washing water 91 and the condensed water 90 stored in the drain pump room 51 to flow toward the drain hose 53. The drain part connection pipe 54 may be connected to the upper part of the drain pump room 51. This may allow the washing water 91 and the condensed water 90 to flow toward the drain hose 53 only when power is provided from the drain pump 52.
The drain pump 52 may be installed at the drain pump room 51 and may provide power to allow the washing water 91 and the condensed water 90 stored in the drain pump room 51 to flow toward the drain part connection pipe 54. The shape and structure of the drain pump 52 are not particularly limited. The drain hose 53 may be connected to the drain part connection pipe 54 in order to discharge the washing water 91 and the condensed water 90 to the outside.
Referring to
In order to allow the condensed water 90 to be collected in the condensed water discharge part 40, the condensed water discharge pipe 100 may adjust the amount of the condensed water 90 flowing from the condensed water discharge part 40 toward the condensed water discharge pipe 100 by adjusting the diameter of the condensed water discharge pipe 100. The diameter of the condensed water discharge pipe 100 may be determined through experimentation, and is not limited to a specific value. The diameter of the condensed water discharge pipe 100 may be determined by considering the amount of condensed water 90 receivable in the condensed water discharge part 40 but also considering a value 50 that the height of the condensed water 90 does not increase continuously in the duct 10.
The condensed water 90 may be prevented from flowing back from the drain part 50 to the condensed water discharge part 40 through the condensed water discharge pipe 100 by a pressure difference generated from the drive of the fan motor 30. In
As shown in
Additionally, since washing water used in the drum 60 of the garment processing apparatus may be collected in the drain pump room 51, both the washing water and the condensed water 90 may be received in the drain pump room 51. Since the washing water and the condensed water 90 may be received in the drain pump room 51, air flowing along the condensed water discharge pipe 100 connecting the condensed water discharge part 40 and the drain pump room 51 may be limited.
Unlike in
The garment processing apparatus may drive the fan motor 30 to circulate air and although a pressure of the condensed water discharge part 40 may be relatively lower than that of the drain part 50 due to the drive of the fan motor 30, since the flow of air is limited by the condensed water 90 stored in the condensed water storage part 110, air may not flow along the condensed water discharge pipe 100. With this principle, the backflow of air from the drain part 50 to the condensed water discharge part 40 may be prevented.
As shown in
Referring to
The first part 111 and the third part 113 may extend in a parallel direction and in order to allow the condensed water 90 flowing along the condensed water discharge pipe 100 to fill the second part 112, the second part 112 may be arranged at a lower height than the first part 111 and the third part 113. When the condensed water 90 is required to be filled to a height higher than a height at which the second part 112 is provided, the backflow of air along the condensed water discharge pipe 100 may be prevented. In relation to the condensed water storage part 110, at least a portion of the second part 112, the first part 111, and the third part 113 may be filled with the condensed water 90.
A connection part of the condensed water discharge pipe 100 may include a first connection part or portion 114 and a second connection part or portion 115. The first connection part 114 may connect the condensed water discharge part 40 and the first part 111 and may extend from the first part 111 toward the condensed water discharge part 40.
The second connection part 115 may connect the third part 113 and the drain part 50 and may be bent at a portion and formed to extend toward the drain part 50. The second connection part 115 may be connected to the third part 113 extending toward the upper part of the condensed water discharge pipe 100 and may be bent at a portion to allow the condensed water 90 to be stored in the condensed water storage part 110.
The first connection part 114 and the second connection part 115 of the condensed water discharge pipe 100 and the condensed water storage part 110 may be formed of different materials. Since the condensed water storage part 110 is required to maintain a U-shaped bending form in order to store the condensed water 90, the condensed water storage part 110 and the condensed water discharge pipe 100 except for the condensed water storage part 110 may be formed of different materials. In general, the condensed water discharge pipe 100 through which the condensed water 90 flows may be formed of a rubber material and the condensed water storage part 110 may be formed of a metallic material in order to maintain the bent form. Additionally, the condensed water storage part 110 formed of a metallic material may be fixed at the inner side surface of the main body or one side of the drum 60.
Referring to
Referring to
The condensed water discharge pipe support member 120 may have a form corresponding to the condensed water storage part 110 or may have a form that surrounds the entirety of the condensed water storage part 110, or surrounds only a portion between the first part 111 and the second part 112 of the condensed water storage part 110 and a portion between the second part 112 and the third part 113 of the condensed water storage part 110. Since the condensed water discharge pipe support member 120 is required to fix the condensed water storage part 110, it may be formed of a plastic or metallic material. The condensed water discharge pipe support member 120 may be formed integrally or may be formed of several coupled components. The condensed water discharge pipe support number 120 may include a first support part (or portion) 121, a second support part (or portion) 122 and third support part (or portion) 123. The condensed water discharge pipe support member 120 may be fixed at the inside of the main body through a bracket or a hook or may be fixed at one side of the drum 60 through a bracket or a hook.
Referring to
Referring to
Referring to
As condensed water is stored in a condensed water discharge part, the backflow of air along the condensed water discharge part may be limited. As a condensed water discharge pipe is connected to one end of a drain pump room for receiving washing water and condensed water, the backflow of air along the condensed water discharge pipe is prevented.
As a condensed water storage part is formed at a condensed water discharge pipe, the backflow of air through the condensed water discharge pipe may be limited. Since the backflow of air toward a heat exchanger may be prevented, the efficiency of the heat exchanger may be improved. As a result, unnecessary energy consumption may be reduced.
A garment processing apparatus may include: a duct disposed at an upper part of a drum, configured to form a flow passage passing through a heat exchanger installed at the inside, and having an inclined bottom surface; a fan motor installed at the duct to move air inside the duct; a condensed water discharge part disposed at a bottom surface of the duct, wherein condensed water generated from air passing through the heat exchanger is collected in the condensed water discharge part; a drain part installed at a lower part of the drum and configured to discharge the condensed water collected in the condensed water discharge part to the outside; and a condensed water discharge pipe connecting the condensed water discharge part and the drain part to allow the condensed water to flow, wherein the condensed water collected in the condensed water discharge part prevents a backflow of fluid from the drain part to the condensed water discharge part through the condensed water discharge pipe by a pressure difference generated by a drive of the fan motor. The condensed water discharge part may be disposed at one end of the inclined bottom surface of the duct to collect the condensed water.
The condensed water discharge part may be inclined toward the condensed water discharge pipe in order to discharge the condensed water. The condensed water discharge pipe may have a diameter value set to adjust an amount of the condensed water flowing from the condensed water discharge part to the condensed water discharge pipe to collect the condensed water in the condensed water discharge part.
The drain part may include: a drain pump room configured to store washing water and the condensed water discharged from the drum; a discharge part connection pipe connected to an upper part of the drain pump room to move the washing water and the condensed water; and a drain hose connected to the drain part connection pipe to discharge the washing water and the condensed water to the outside, wherein a backflow of air from the drain part to the condensed water discharge part is prevented by the washing water and the condensed water stored in the drain pump room. The garment processing may further include a drain pump installed at the drain pump room and configured to provide power for moving the washing water and the condensed water stored in the drain pump room to the drain part connection pipe.
A garment processing apparatus may include a duct disposed at an upper part of a drum, configured to form a flow passage passing through a heat exchanger installed at the inside, and having an inclined bottom surface; a fan motor installed at the duct to move air inside the duct; a condensed water discharge part disposed at a bottom surface of the duct, wherein condensed water generated from air passing through the heat exchanger is collected in the condensed water discharge part; a drain part installed at a lower part of the drum and configured to discharge the condensed water collected in the condensed water discharge part to the outside; and a condensed water discharge pipe connecting the condensed water discharge part and the drain part to allow the condensed water to flow, wherein the condensed water discharge pipe includes a condensed water storage part bent from at least a portion to collect a condensed water in order to prevent air from flowing back from the drain part to the condensed water discharge part by a pressure difference generated by a drive of the fan motor. The condensed water storage part may include: a first part extending downwardly from an upper part of the condensed water discharge pipe; a second part bent to be connected to the first part and extending in a direction intersecting the first part; and a third part bent to be connected to the second part and extending toward the upper part of the condensed water discharge pipe.
The condensed water discharge pipe may further include: a first connection part connecting the condensed water discharge part and the first part; and a second connection part connecting the third part and the drain part, wherein the second connection part may be bent from at least a portion to extend toward the drain part. The first part and the third part may extend in parallel in different directions along a gravity direction.
The condensed water may be filled at a position higher than a position of the second part. The condensed water storage part may be provided at a plurality of places along a length direction of the condensed water discharge pipe.
The garment processing apparatus may further include a condensed water discharge pipe support member having a form corresponding to the condensed water storage part and formed to surround at least a portion of the condensed water storage part. The condensed water discharge pipe support member may be fixed to the inside of the main body or at least one side of a drum.
The condensed water discharge pipe support member may include: a first support part surrounding the outside of the first part in a form corresponding to the first part; a second support part surrounding the outside of the second part in a form corresponding to the second part; and a third part surrounding the outside of the third part in a form corresponding to the third part. The first connection part and the second connection part of the condensed water discharge pipe and the condensed water storage part may be formed of different materials.
The condensed water storage part may be fixed at an inner side surface of the main body. The condensed water storage part may be formed in a U-shaped form. A check valve for limiting air to flow from the drain part toward the heat exchanger may be disposed at one side of the condensed water discharge pipe. The garment processing apparatus may further include a condensed water discharge adjustment member installed inside the condensed water discharge pipe, having a tapered form whose section is reduced as it progressively goes in one direction, and having one end part with a smaller section opened toward a flow direction of fluid.
Further scope of applicability of the present application will become more apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the disclosure, are given by way of illustration only, since various changes and modifications within the spirit and scope of the disclosure will become apparent to those skilled in the art from the detailed description.
In this specification, even in different embodiments, like reference numerals refer to like elements and the description thereof is replaced with the first description. The singular expressions include the plural expressions unless the context clearly dictates otherwise.
As the present features may be embodied in several forms without departing from the characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, unless otherwise specified, but rather should be construed broadly within its scope as defined in the appended claims, and therefore all changes and modifications that fall within the metes and bounds of the claims, or equivalents of such metes and bounds are therefore intended to be embraced by the appended claims.
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 invention. 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.
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