Patent Description:
When a heat pump dryer works, a condensed fluid in a liquid guide groove flows back to an air duct due to the negative pressure in the air duct, which affects the drying efficiency. Therefore, how to prevent the condensed fluid from flowing back into the air duct is a technical problem that needs to be solved by those skilled in the art. <CIT> relates generally to a base of a heat pump system and a heat pump system for a drier or a washer-drier. <CIT> relates generally to a heat pump laundry dryer, wherein the drying efficiency is increased and generation of undesired bad odors is prevented by facilitating the discharge of the condensate water.

In the following, each of the described methods, apparatuses, embodiments, examples, and aspects, which do not fully correspond to the invention as defined in the claims is thus not according to the invention and is, as well as the whole following description, present for illustration purposes only or to highlight specific aspects or features of the claims. Embodiments not falling under the scope of the claims should be interpreted as examples useful for understanding the invention. The present disclosure is intended to solve at least one of the technical problems existing in the related art. Therefore, the present invention provides a liquid-discharging partition for a dryer. When negative pressure is generated in an air duct, a condensed fluid flowing back to an outlet of a liquid guide groove can flow to the liquid guide groove and a diffluent groove respectively. Therefore, on one hand, a diffluent effect can be achieved to reduce a hydraulic pressure, and on the other hand, a path for a back flow of the condensed fluid is increased, which is beneficial to preventing the condensed fluid from flowing back into the air duct.

The present disclosure also proposes a dryer having the liquid-discharging partition for the dryer.

According to the liquid-discharging partition for the dryer disclosed by the present invention, the liquid-discharging partition has a liquid guide groove, the liquid guide groove has an inlet and an outlet, the inlet and the outlet are defined at two ends of the liquid guide groove in a length direction of the liquid guide groove, respectively. The liquid-discharging partition further has a diffluent groove defined on at least one side of the liquid guide groove in a width direction of the liquid guide groove. The diffluent groove is in communication with the liquid guide groove through at least one liquid passing opening.

According to the liquid-discharging partition for the dryer disclosed by the present invention, the liquid guide groove and the diffluent groove are in communication with each other. In this way, when a negative pressure is generated in an air duct, a condensed fluid flowing back to the outlet of the liquid guide groove can flow to the liquid guide groove and the diffluent groove respectively. Therefore, on one hand, a diffluent effect can be achieved to reduce a hydraulic pressure, and on the other hand, a path for a back flow of the condensed fluid is increased, which is beneficial to preventing the condensed fluid from flowing back into the air duct.

In some embodiments of the present disclosure, the at least one liquid passing opening includes at least two liquid passing openings. One of the at least two liquid passing openings is formed as an inlet of the diffluent groove, and another one of the at least two liquid passing openings is formed as an outlet of the diffluent groove.

In some embodiments of the present disclosure, the at least one liquid passing opening includes a plurality of liquid passing openings spaced apart from one another in the length direction of the liquid guide groove. Each of the plurality of liquid passing openings is in communication with the diffluent groove.

The liquid-discharging partition includes: a plate body, a liquid guide portion, and a diffluent portion. The liquid guide portion is arranged on a side surface of the plate body. The liquid guide groove is defined between the liquid guide portion and the plate body. The diffluent portion is arranged on a side surface of the plate body. The diffluent groove is defined by the plate body and the diffluent portion, and/or the diffluent groove is defined by the plate body, the liquid guide portion, and the diffluent portion.

The liquid-discharging partition further includes at least one first liquid retaining rib arranged on the plate body and located within the diffluent groove. The at least one first liquid retaining rib is spaced apart from the liquid guide portion.

The liquid-discharging partition further includes a second liquid retaining rib arranged on the plate body and located within the diffluent groove. The second liquid retaining rib is spaced apart from the liquid guide portion and connected to the at least one first liquid retaining rib. On a plane parallel to the plate body, an extending direction of the second liquid retaining rib is not parallel to an extending direction of each of the at least one first liquid retaining rib.

In some embodiments of the present disclosure, the at least one first liquid retaining rib includes a plurality of first liquid retaining ribs spaced apart from one another. Two adjacent first liquid retaining ribs of the plurality of first liquid retaining ribs are connected to each other by the second liquid retaining rib.

In some embodiments of the present disclosure, on the plane parallel to the plate body, at least one of an extending direction of each of the at least one first liquid retaining rib or an extending direction of the second liquid retaining rib is not parallel to the length direction of the liquid guide groove.

In some embodiments of the present disclosure, the liquid-discharging partition further includes a third liquid retaining rib arranged on the plate body and located within the diffluent groove. The third liquid retaining rib is parallel to the plurality of first liquid retaining ribs. The third liquid retaining rib is located between two adjacent first liquid retaining ribs of the plurality of first liquid retaining ribs and spaced apart from the second liquid retaining rib.

In some embodiments of the present disclosure, the liquid guide groove has a first side wall and a second side wall that are opposite to each other. At least one of the first side wall or the second side wall has at least one liquid guide rib provided on an inner surface thereof. The at least one liquid guide rib on either one of the first side wall and the second side wall extends obliquely towards another one of the first side wall and the second side wall.

In some embodiments of the present disclosure, the at least one liquid guide rib extends obliquely towards the outlet of the liquid guide groove from outside to inside in the width direction of the liquid guide groove.

In some embodiments of the present disclosure, the at least one liquid guide rib includes a plurality of liquid guide ribs spaced apart from each other in the length direction of the liquid guide groove.

In some embodiments of the present disclosure, the at least one liquid guide rib includes at least one first liquid guide rib and at least one second liquid guide rib. The at least one first liquid guide rib each has an end connected to the first side wall, and another end extending obliquely towards the outlet of the liquid guide groove and spaced apart from the second side wall. The at least one second liquid guide rib each has an end connected to the second side wall, and another end extending obliquely towards the outlet of the liquid guide groove and spaced apart from the first side wall.

In some embodiments of the present disclosure, the at least one first liquid guide rib includes a plurality of first liquid guide ribs. The at least one second liquid guide rib includes a plurality of second liquid guide ribs. The plurality of first liquid guide ribs and the plurality of second liquid guide ribs are arranged alternately and spaced apart from each other in the length direction of the liquid guide groove.

In some embodiments of the present disclosure, the at least one liquid passing opening is defined in one of the first side wall and the second side wall closer to the diffluent portion.

In some embodiments of the present disclosure, each of the liquid guide portion and the diffluent portion is a flexible member.

According to embodiments of the present disclosure, a dryer includes an air duct housing having a chamber where an evaporator and a condenser are mounted; and the above-mentioned liquid-discharging partition for the dryer. The liquid-discharging partition is located within the chamber. A liquid-discharging channel for a condensed fluid is defined between an inner bottom wall of the chamber and each of the liquid guide groove and the diffluent groove.

According to the dryer disclosed by the embodiments of the present disclosure, through the provision of the liquid-discharging partition for the dryer, when the negative pressure is generated in the air duct, the condensed fluid flowing back to the outlet of the liquid guide groove can flow into the liquid guide groove and the diffluent groove respectively. Therefore, on one hand, a diffluent effect can be achieved to reduce a hydraulic pressure, and on the other hand, a path for a back flow of the condensed fluid is increased, which is beneficial to preventing the condensed fluid from flowing back into the air duct.

Additional aspects and advantages of the present disclosure will be provided at least in part in the following description, or will become apparent at least in part from the following description, or can be learned from practicing of the present disclosure.

The above and/or additional aspects and advantages of the present disclosure will become apparent and understandable from the following description of embodiments in conjunction with the accompanying drawings, in which:.

Embodiments of the present disclosure are described below in detail, examples of the embodiments are illustrated in accompanying drawings, and throughout the description, the same or similar reference signs represent the same or similar components or the components having the same or similar functions. The embodiments described below with reference to the accompanying drawings are exemplary and merely used to explain the present disclosure, rather than being construed as limitation on the present disclosure.

Various embodiments or examples for implementing different structures of the present disclosure are provided below. In order to simplify the description of the present disclosure, components and arrangements of specific examples are described herein. Of course, these specific examples are merely for the purpose of illustration, and they are not intended to limit the present disclosure. Furthermore, the same reference numerals and/or reference letters may appear in different examples of the present disclosure for the purpose of simplicity and clarity, instead of indicating a relationship between different discussed embodiments and/or arrangements. In addition, the present disclosure provides examples of various specific processes and materials. However, applications of other processes and/or the use of other materials are conceivable for those skilled in the art.

A liquid-discharging partition <NUM> for a dryer <NUM> and the dryer <NUM> according to embodiments of the present disclosure are described below with reference to the drawings. For example, the dryer <NUM> may be a heat pump dryer.

As illustrated in <FIG> and <FIG>, according to the liquid-discharging partition <NUM> of the dryer <NUM>, the liquid-discharging partition <NUM> has a liquid guide groove <NUM>. The liquid guide groove <NUM> has an inlet <NUM> and an outlet <NUM>. The inlet <NUM> and the outlet <NUM> are located at two ends of the liquid guide groove <NUM> in a length direction (referring to a direction F1 illustrated in <FIG>) of the liquid guide groove <NUM>, respectively. It should be noted that, as illustrated in <FIG>, the inlet <NUM> of the liquid guide groove <NUM> is in communication with an air duct of the dryer <NUM>. An evaporator <NUM> of the dryer <NUM> is located within the air duct. A condensed fluid on the evaporator <NUM> can flow into the liquid guide groove <NUM> through the inlet <NUM> of the liquid guide groove <NUM>, and is finally discharged through the outlet <NUM> of the liquid guide groove <NUM>. For example, the outlet <NUM> of the liquid guide groove <NUM> is in communication with a water storage portion <NUM> of the dryer <NUM>. The water storage portion <NUM> is configured to store the condensed liquid flowing to the water storage portion <NUM> from the liquid guide groove <NUM>.

The liquid-discharging partition <NUM> further has a diffluent groove <NUM> defined on at least one side of the liquid guide groove <NUM> in a width direction of the liquid guide groove <NUM> (refer to a direction F2 illustrated in <FIG>). In other words, the diffluent groove <NUM> may be located on one side of the liquid guide groove <NUM> in the width direction of the liquid guide groove <NUM>, or the diffluent groove <NUM> may be located on each of two sides of the liquid guide groove <NUM> in the width direction of the liquid guide groove <NUM>. The diffluent groove <NUM> is in communication with the liquid guide groove <NUM> through liquid passing openings <NUM>. For example, as illustrated in <FIG>, the diffluent groove <NUM> may be formed in a trapezoidal shape.

It should be noted that the inventor found in actual researches that in the related art, the heat pump dryer has the liquid-discharging partition provided on a base thereof. The liquid-discharging partition separates an air duct and a water channel at a condenser and an evaporator. However, when a negative pressure is generated in the air duct, that is, an external air pressure is greater than an air pressure inside the air duct, the condensed fluid collected in the water storage portion of the dryer will flow back to the air duct along the water channel through the inlet of the liquid guide groove, affecting a drying efficiency of the dryer.

In the present disclosure, when the negative pressure is generated in the air duct, the condensed fluid flowing back from the water storage portion <NUM> flows to the outlet of the liquid guide groove <NUM>, and flows into the liquid guide groove <NUM> and the diffluent groove <NUM> respectively after passing through the outlet of the liquid guide groove <NUM>. In this way, by arranging the liquid guide groove <NUM> and the diffluent groove <NUM> that are in communication with each other, on one hand, a diffluent effect can be achieved to reduce a hydraulic pressure, and on the other hand, a path for a back flow of the condensed fluid is increased, which is beneficial to preventing the condensed fluid from flowing back into the air duct through the inlet of the liquid guide groove <NUM>.

Accordingly, according to the liquid-discharging partition <NUM> for the dryer <NUM>, the liquid guide groove <NUM> and the diffluent groove <NUM> are in communication with each other. In this way, when the negative pressure is generated in the air duct, the condensed fluid flowing back to the outlet <NUM> of the liquid guide groove <NUM> can flow to the liquid guide groove <NUM> and the diffluent groove <NUM> respectively. Therefore, on one hand, a diffluent effect can be achieved to reduce a hydraulic pressure, and on the other hand, a path for a back flow of the condensed fluid is increased, which is beneficial to preventing the condensed fluid from flowing back into the air duct.

In some embodiments of the present disclosure, as illustrated in <FIG>, at least two liquid passing openings <NUM> are provided. One of the at least two liquid passing openings <NUM> is formed as the inlet of the diffluent groove <NUM> and another one of the at least two liquid passing openings is formed as the outlet of the diffluent groove <NUM>. Therefore, the diffluent groove <NUM> has an inlet and an outlet that are in communication with the liquid guide groove <NUM>, which facilitates the condensed fluid in the liquid guide groove <NUM> to flow into and flow out of the diffluent groove <NUM>, and is beneficial to improving a diffluent efficiency of the diffluent groove <NUM>.

For example, as illustrated in <FIG>, two liquid passing openings <NUM> are provided and spaced apart from each other in a length direction of the liquid guide groove <NUM>. The liquid passing opening <NUM> approximate to the inlet <NUM> of the liquid guide groove <NUM> is an inlet of the diffluent groove <NUM>, and the liquid passing opening <NUM> distal to the inlet <NUM> of the liquid guide groove <NUM> is an outlet of the diffluent groove <NUM>.

In some embodiments of the present disclosure, referring to <FIG>, a plurality of liquid passing openings <NUM> is provided and spaced apart from one another in the length direction of the liquid guide groove <NUM> and is each in communication with the diffluent groove <NUM>. This facilitates the flowing of the condensed fluid in the liquid guide groove <NUM> into or out of the diffluent groove <NUM>, and is advantageous in improving the diffluent efficiency of the diffluent groove <NUM>. Of course, the present disclosure is not limited to this, and only one liquid passing opening <NUM> may be provided.

As illustrated in <FIG>, the liquid-discharging partition <NUM> includes a plate body <NUM>, a liquid guide portion <NUM>, and a diffluent portion <NUM>. The liquid guide portion <NUM> is arranged on a side surface of the plate body <NUM>. The liquid guide groove <NUM> is defined between the liquid guide portion <NUM> and the plate body <NUM>. The diffluent portion <NUM> is arranged on a side surface of the plate body <NUM>. The diffluent groove <NUM> is defined by the plate body <NUM> and the diffluent portion <NUM>; and/or the diffluent groove <NUM> is defined by the plate body <NUM>, the liquid guide portion <NUM>, and the diffluent portion <NUM>.

For example, as illustrated in <FIG> and <FIG>, the liquid guiding portion <NUM> arranged on a side surface of the plate body <NUM>, and the liquid guide groove <NUM> is defined by the liquid guiding portion <NUM> and the plate body <NUM>. The diffluent portion <NUM> is arranged on a side surface of the plate body <NUM>, and the diffluent groove <NUM> is defined by the plate body <NUM>, the liquid guide portion <NUM>, and the diffluent portion <NUM>. The diffluent groove <NUM> is in communication with the liquid guide groove <NUM> through two liquid passing openings <NUM>.

As illustrated in <FIG> and <FIG>, the liquid-discharging partition <NUM> further includes a first liquid retaining rib <NUM> arranged on the plate body <NUM>, located within the diffluent groove <NUM>, and spaced apart from the liquid guide portion <NUM>. It can be understood that the arrangement of the first liquid retaining rib <NUM> in the diffluent groove <NUM> is beneficial to increasing a resistance to the back flowing of the condensed fluid when a negative pressure is generated in the air duct, and therefore is beneficial to preventing the condensed fluid from flowing back into the air duct.

As illustrated in <FIG> and <FIG>, the liquid-discharging partition <NUM> further includes a second liquid retaining rib <NUM> arranged on the plate body <NUM>, located within the diffluent groove <NUM>, and spaced apart from the liquid guide portion <NUM>. The second liquid retaining rib <NUM> is connected to the first liquid retaining rib <NUM>. An extending direction of the second liquid retaining rib <NUM> is not parallel to an extending direction of the first liquid retaining rib <NUM>. It can be understood that by a cross arrangement of the first liquid retaining rib <NUM> and the second liquid retaining rib <NUM>, the path for the back flow of the condensed fluid is further increased, the resistance to the back flowing of the condensed fluid is increased at the same time. Besides, the structure is simple, and is convenient for processing and forming.

Further, as illustrated in <FIG>, a plurality of liquid guide ribs <NUM> is provided and spaced apart from one another. Every two adjacent first liquid retaining ribs <NUM> are connected to each other by a second liquid retaining rib <NUM>. Here, a plurality refers to two or more. It can be understood that the first liquid retaining ribs <NUM> and the second liquid retaining ribs <NUM> are in a cross arrangement, and every two adjacent first liquid retaining ribs <NUM> are connected by the second liquid retaining rib <NUM>. In this way, it is beneficial to further increasing the path for the back flow of the condensed fluid while increasing the resistance to the back flowing of the condensed fluid.

In some embodiments of the present disclosure, as illustrated in <FIG> and <FIG>, on a plane parallel to the plate body <NUM>, at least one of an extending direction of the first liquid retaining rib <NUM> or an extending direction of the second liquid retaining rib <NUM> is not parallel to the length direction of the liquid guide groove <NUM>. For example, neither the extending direction of the first liquid retaining rib <NUM> nor the extending direction of the second liquid retaining rib <NUM> is parallel to the length direction of the liquid guide groove <NUM>. Therefore, when the negative pressure is generated in the air duct, the resistance of the first liquid retaining rib <NUM> and the second liquid retaining rib <NUM> to the back flowing of the condensed fluid can be further increased.

Further, as illustrated in <FIG>, the liquid-discharging partition <NUM> further includes a third liquid retaining rib <NUM> arranged on the plate body <NUM> and located within the diffluent groove <NUM>. The third liquid retaining rib <NUM> is parallel to the first liquid retaining rib <NUM>. The third liquid retaining rib <NUM> is located between two adjacent first liquid retaining ribs <NUM> and spaced apart from the second liquid retaining rib <NUM>. Therefore, the first liquid retaining rib <NUM>, the second liquid retaining rib <NUM>, and the third liquid retaining rib <NUM> form a labyrinth-shaped structure, which greatly increases the path for the back flow of the condensed fluid while increasing the resistance to the back flowing with a simple structure and low cost. For example, as illustrated in <FIG>, a plurality of third liquid retaining ribs <NUM> may be provided, and the plurality of third liquid retaining ribs <NUM> are arranged in parallel and spaced apart from each other.

In some embodiments of the present disclosure, referring to <FIG>, the liquid guide groove <NUM> has a first side wall <NUM> and a second side wall <NUM> that are opposite to each other. For example, as illustrated in <FIG>, the first side wall <NUM> and the second side wall <NUM> are defined by inner side walls of the liquid guide portion <NUM> that are opposite to each other in the F2 direction. At least one of the first side wall <NUM> or the second side wall <NUM> has a liquid guide rib <NUM> provided on an inner surface thereof. The liquid guide rib <NUM> on one of the first side wall <NUM> and the second side wall <NUM> extends obliquely towards the other of the first side wall <NUM> and the second side wall <NUM>. In other words, only one of the first side wall <NUM> and the second side wall <NUM> has a liquid guide rib <NUM> provided on an inner surface thereof, and the liquid guide rib <NUM> extends obliquely towards the other of the first side wall <NUM> and the second side wall <NUM>. Alternatively, as illustrated in <FIG>, each of the first side wall <NUM> and the second side wall <NUM> has a liquid guide rib <NUM> provided on an inner surface thereof, and the liquid guide rib <NUM> on either one of the first side wall <NUM> and the second side wall <NUM> extends obliquely towards the other of the first side wall <NUM> and the second side wall <NUM>. In this way, the provision of the liquid guide rib <NUM> is beneficial for increasing the resistance to the flowing of the condensed fluid in the liquid guide groove <NUM> and preventing the back flowing of the condensed fluid, when the negative pressure is generated in the air duct.

In some examples, as illustrated in <FIG>, the liquid guide rib <NUM> extends obliquely towards the outlet <NUM> of the liquid guide groove <NUM> from outside to inside in the width direction of the liquid guide groove <NUM>. In the F2 direction, a direction approaching the first side wall <NUM> and a direction approaching the second side wall <NUM> is "outside", and a direction approaching a center of the liquid guide groove <NUM> is "inside". It can be understood that, during the collection of the condensed fluid, the liquid guide rib <NUM> can play a role in guiding water, and when the negative pressure is generated and the back flowing is caused, the liquid guide rib <NUM> increases the resistance to the back flowing of the condensed fluid and can prevent the condensed fluid from flowing back to the air duct.

In some embodiments of the present disclosure, referring to <FIG>, a plurality of liquid guide ribs <NUM> is provided and spaced apart from one another in the length direction of the liquid guide groove <NUM>. Therefore, by the arrangement of the plurality of liquid guide ribs <NUM> spaced apart from one another, when the negative pressure is generated and the back flowing is caused, the resistance to the back flowing of the condensed fluid is further increased to prevent the condensed fluid from flowing back to the air duct.

Further, as illustrated in <FIG>, the plurality of liquid guide ribs <NUM> includes a first liquid guide rib <NUM> and a second liquid guide rib <NUM>. The first liquid guide rib <NUM> has an end connected to the first side wall <NUM>, and another end extending obliquely towards the outlet <NUM> of the liquid guide groove <NUM> and spaced apart from the second side wall <NUM>. The second liquid guide rib <NUM> has an end connected to the second side wall <NUM>, and another end extending obliquely towards the outlet <NUM> of the liquid guide groove <NUM> and spaced apart from the first side wall <NUM>. It can be understood that, by the arrangement of the first liquid guide rib <NUM> and the second liquid guide rib <NUM> that are spaced apart from each other, during the collection of the condensed fluid, the first liquid guide rib <NUM> and the second liquid guide rib <NUM> can play a good role in guiding water, and when the negative pressure is generated and the back flowing is caused, the first liquid guide rib <NUM> and the second liquid guide rib <NUM> can further increase the resistance to the back flowing of the condensed fluid, which is beneficial to preventing the condensed fluid from flowing back to the air duct.

In some embodiments of the present disclosure, the plurality of liquid guide ribs <NUM> includes a plurality of first liquid guide ribs <NUM> and a plurality of second liquid guide ribs <NUM>. The plurality of first liquid guide ribs <NUM> and the plurality of second liquid guide ribs <NUM> are arranged alternately and spaced apart from each other in the length direction of the liquid guide groove <NUM>. Therefore, when the negative pressure is generated and the back flowing is caused, the resistance to the back flowing of the condensed fluid can be greatly increased to prevent the condensed fluid from flowing back to the air duct. The structure is simple and the production cost is low.

In some embodiments of the present disclosure, the liquid passing opening <NUM> is defined in one of the first side wall <NUM> and the second side wall <NUM> closer to the diffluent portion <NUM>. Therefore, the structure is simple, and is beneficial to the processing and forming of the liquid-discharging partition <NUM>.

In some embodiments of the present disclosure, the liquid guiding portion <NUM> and the diffluent portion <NUM> are each a flexible member. For example, the liquid guide portion <NUM> and the diffluent portion <NUM> are each a silicone member or a rubber member. In this way, a sealing performance between the liquid-discharging partition <NUM> and an inner bottom wall of an air duct housing <NUM> can be enhanced, which is beneficial to preventing the condensed fluid from flowing into the air duct through gaps between the liquid guide portion <NUM>, the diffluent portion <NUM>, and the air duct housing <NUM>, and is beneficial to improving the drying efficiency.

In some embodiments of the present disclosure, the first liquid retaining rib <NUM>, the second liquid retaining rib <NUM>, the third liquid retaining rib <NUM>, and the liquid guide rib <NUM> are each a flexible member. For example, the first liquid retaining rib <NUM>, the second liquid retaining rib <NUM>, the third liquid retaining rib <NUM>, and the liquid guide rib <NUM> are each a silicone member or a rubber member.

Referring to <FIG> and <FIG>, a dryer <NUM> according to embodiments of the present disclosure includes an air duct housing <NUM> and the liquid-discharging partition <NUM> for the dryer <NUM> according to the above embodiments of the present disclosure. The air duct housing has a chamber <NUM> where an evaporator <NUM> and a condenser <NUM> are mounted. The liquid-discharging partition <NUM> is located within the chamber <NUM>. A liquid-discharging channel a is defined between an inner bottom wall of the chamber <NUM> and each of the liquid guide groove <NUM> and the diffluent groove <NUM>.

For example, as illustrated in <FIG> and <FIG>, each of the evaporator <NUM> and the condenser <NUM> is arranged on the liquid-discharging partition <NUM> and can play a role in pressing the liquid-discharging partition <NUM> tight. The chamber <NUM> has a water guide groove <NUM> provided on the inner bottom wall thereof. The evaporator <NUM> is arranged on the water guide groove <NUM>, and the water guide groove <NUM> is in communication with the inlet <NUM> of the liquid guide groove <NUM>. When the dryer <NUM> operates normally, i.e., the negative pressure is not generated in the air duct, the condensed fluid on the evaporator <NUM> can flow downwards into the water guide groove <NUM>, then flow into the liquid guide groove <NUM> and the diffluent groove <NUM> through the inlet <NUM> of the liquid guide groove <NUM>, and finally be discharged through the outlet <NUM> of the liquid guide groove <NUM>.

When the negative pressure is generated in the air duct, the condensed fluid flowing back from the water storage portion <NUM> flows to the outlet <NUM> of the liquid guide groove <NUM>, and flows into the liquid guide groove <NUM> and the diffluent groove <NUM> after passing through the outlet <NUM> of the liquid guide groove <NUM>. By the provision of the liquid guide groove <NUM> and the diffluent groove <NUM> which are in communication with each other, on one hand, a diffluent effect can be achieved to reduce a hydraulic pressure, and on the other hand, the path for the back flow of the condensed fluid is increased, which is beneficial to preventing the condensed fluid from flowing back into the air duct through the inlet of the liquid guide groove <NUM>.

According to the dryer <NUM> of the embodiments of the present disclosure, by the provision of the liquid-discharging partition <NUM> for the dryer <NUM> according to the above embodiments of the present disclosure, when the negative pressure is generated in the air duct, the condensed fluid flowing back to the outlet <NUM> of the liquid guide groove <NUM> can flow to the liquid guide groove <NUM> and the diffluent groove <NUM>. On one hand, the diffluent effect can be achieved to reduce the hydraulic pressure, and on the other hand, the path for the back flow of the condensed fluid is increased, which is beneficial to preventing the condensed fluid from flowing back into the air duct and therefore is beneficial to improving the drying efficiency.

Other configurations and operations of the dryer <NUM> according to the embodiments of the present disclosure are known to those of ordinary skill in the art, and will not be described in detail herein.

It should be understood that in the description of the present disclosure, the orientation or position relationship indicated by the terms "center", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", etc., is based on the orientation or position relationship shown in the drawings, and is only for the convenience of describing the present disclosure and simplifying the description, rather than indicating or implying that the defined device or element must have a specific orientation or must be constructed and operated in a specific orientation. Thus, the orientation or position relationship indicated by these terms cannot be understood as limitations on the present disclosure.

In addition, the terms "first" and "second" are only used for purpose of description, and cannot be understood as indicating or implying relative importance or implicitly indicating the number of indicated technical features. Therefore, the features defined by the terms "first" and "second" may explicitly or implicitly include at least one of the features. In the description of the present disclosure, "plurality" means at least two, unless otherwise specifically defined.

Claim 1:
A liquid-discharging partition (<NUM>) for a dryer (<NUM>), the liquid-discharging partition (<NUM>) having:
a liquid guide groove (<NUM>) having an inlet (<NUM>) and an outlet (<NUM>), the inlet (<NUM>) and the outlet (<NUM>) being defined at two ends of the liquid guide groove (<NUM>) in a length direction of the liquid guide groove (<NUM>), respectively; and
a diffluent groove (<NUM>) defined on at least one side of the liquid guide groove (<NUM>) in a width direction of the liquid guide groove (<NUM>), the diffluent groove (<NUM>) being in communication with the liquid guide groove (<NUM>) through at least one liquid passing opening (<NUM>);
a plate body (<NUM>);
a liquid guide portion (<NUM>) arranged on a side surface of the plate body (<NUM>), wherein the liquid guide groove (<NUM>) is defined between the liquid guide portion (<NUM>) and the plate body (<NUM>); and
a diffluent portion (<NUM>) arranged on a side surface of the plate body (<NUM>),
wherein the diffluent groove (<NUM>) is defined by the plate body (<NUM>) and the diffluent portion (<NUM>), and/or the diffluent groove (<NUM>) is defined by the plate body (<NUM>), the liquid guide portion (<NUM>), and the diffluent portion (<NUM>);
the liquid-discharging partition (<NUM>) further comprising:
at least one first liquid retaining rib (<NUM>) arranged on the plate body (<NUM>) and located within the diffluent groove (<NUM>), wherein the at least one first liquid retaining rib (<NUM>) is spaced apart from the liquid guide portion (<NUM>);
characterised in that the liquid-discharging partition (<NUM>) further comprises:
a second liquid retaining rib (<NUM>) arranged on the plate body (<NUM>) and located within the diffluent groove (<NUM>), wherein the second liquid retaining rib (<NUM>) is spaced apart from the liquid guide portion (<NUM>) and connected to the at least one first liquid retaining rib (<NUM>), and wherein on a plane parallel to the plate body (<NUM>), an extending direction of the second liquid retaining rib (<NUM>) is not parallel to an extending direction of each of the at least one first liquid retaining rib (<NUM>).