KR100781636B1 - Dehumidifier - Google Patents

Abstract

A dehumidifier is provided to form condensed water holes and cutaway parts at lower and upper parts of reinforcement ribs of a bucket for preventing deformation and damage of a bucket and making distribution of condensed water uniform in a body part of the bucket. A dehumidifier includes a casing having an inlet and an outlet apart from the inlet, and a heat exchange part formed in the casing for dehumidifying air introduced via the inlet for discharging the same via the outlet. A condensed water collecting part is mounted at a lower part of the heat exchange part for collecting condensed water generated from the heat exchange part. A bucket(700) has a body part(710) detachably mounted to the casing for storing the collected condensed water, and reinforcement ribs(720) supporting an inside of the body part. The reinforcement ribs are formed with condensed water holes(723) at positions contacting a bottom surface of the body part, and cutaway part(721) at upper parts thereof for correcting elasticity against an external force applied to the body part in the case of detachment of the body part and simple flowing of the condensed water in the body part in spite of the reinforcement ribs. The reinforcement ribs are extended in the detachment direction of the body part.

Description

Dehumidifier {DEHUMIDIFIER}

1 is a side cross-sectional view of the dehumidifier according to the present invention,

Figure 2 is a perspective view of the bucket in the dehumidifier of Figure 1,

3 is a cross-sectional view taken along the line X-Y in the bucket of FIG.

Explanation of symbols on the main parts of the drawings

1: dehumidifier 100: casing

110: front cover 111: intake vent

120: rear cover 121: exhaust vent

130: bucket mounting portion 200: air purification filter

300: blower 310: fan unit

320: fan unit drive unit 400: heat exchange unit

410: evaporator 420: condenser

500: compressor 600: condensate collection unit

610: drain 700: bucket

710: bucket body 711: bucket bottom

713: bucket side wall 720: reinforcing rib

721: cutting portion 723: condensate moving hole

The present invention relates to a dehumidifier, and more particularly, to a dehumidifier having an improved structure of a bucket.

The dehumidifier inhales the humid air of the surrounding environment therein and then removes the moisture by the heat exchanger and discharges it, thereby lowering the humidity of the surrounding environment. The heat exchanger applied to the dehumidifier has a structure in which a refrigerant circulates for dehumidification of air. The dehumidifier removes heat from the ambient air by phase-transforming the refrigerant from the liquid to the gas in the heat exchanger, thereby lowering the temperature around the heat exchanger, and condensed water condensed with moisture in the air forms on the surface of the heat exchanger.

The dehumidifier collects the condensate and stores it in a bucket. When the condensate is filled inside the bucket, the user separates the bucket from the dehumidifier, discards the condensate, and mounts the dehumidifier again.

This dehumidifier is a structure that is vulnerable to external impact because the bucket has a tubular shape so that the condensed water is stored. Thus, the dehumidifier according to the prior art provides a reinforcing rib inside the bucket to prevent the bucket from being broken when the bucket is detached.

However, such a conventional dehumidifier has a problem in that the inside of the bucket is divided into a plurality of areas by reinforcing ribs, and condensate induced in the bucket is stored in one of the divided areas. This causes the weight of the condensate to be unevenly loaded into the bucket, which impairs the stability of the dehumidifier as a whole. In addition, when the user separates the bucket from the dehumidifier, there is a problem that the convenience of the user is impaired, such as condensate is poured from the bucket due to the uneven weight of the condensate.

Accordingly, it is an object of the present invention to provide a dehumidifier capable of uniformly distributing condensate stored in a bucket while supporting the bucket from external impact by a simple structure.

According to the present invention, there is provided a dehumidifier comprising: a casing having an intake port and an exhaust port spaced from the intake port; A heat exchanger provided inside the casing and configured to dehumidify air introduced from the intake port and discharge the air to the exhaust port; A condensate collection unit provided below the heat exchanger and collecting condensate generated from the heat exchanger; A bucket including a bucket body detachably provided at the casing and storing the collected condensate, and a reinforcing rib having a condensate moving hole formed in a region supporting the inside of the bucket body and in contact with the bottom surface of the bucket body; It is achieved by a dehumidifier comprising a.

Here, the reinforcing rib is preferably extended along the detachable direction of the bucket body.

Here, the reinforcing ribs preferably have a cutout formed on the upper side.

In addition, the air exchanger is interposed between the heat exchange part and the exhaust port, and further includes a blower for sucking the air outside the casing through the intake port and discharge the air through the heat exchange unit to the exhaust port.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figs. 1 to 3, the dehumidifier 1 according to the present invention comprises: a casing 100 having an inlet port 111 and an exhaust port 121; An air purification filter 200 mounted on the inlet 111 inside the casing 100; A blowing unit 300 interposed between the inlet port 111 and the exhaust port 121; A heat exchange part 400 interposed between the air purification filter 200 and the blower part 300; A compressor 500 provided below the casing 100; A condensate collector 600 provided under the heat exchanger 400; It includes; a bucket 700 detachably attached to the lower side of the casing 100 provided with the inlet 111.

The casing 100 accommodates all the components of the dehumidifier 1 therein and forms an appearance of the dehumidifier 1. The casing 100 has a front cover 110 having a front and a rear opening and covering the front surface; A rear cover 120 covering the rear surface; It includes; a bucket mounting portion 130, the bucket 700 is mounted on the lower side of the front cover (110). That is, the opened front surface of the casing 100 is covered by the front cover 110 at the upper side and the bucket 700 at the lower side.

The front cover 110 covers the front upper side of the casing 100. The front cover 110 is formed through the inlet port 111 on the plate surface, the humid air outside the casing 100 is sucked into the casing 100 through the inlet port 111.

The rear cover 120 covers the back of the casing (100). The rear cover 120 has an exhaust port 121 penetrated on the plate surface, and the air inside the casing 100 dehumidified by the heat exchange unit 400 is discharged to the outside of the casing 100 through the exhaust port 121.

Bucket mounting portion 130 is formed on the lower side of the front cover 110 of the front of the casing 100 so that the bucket 700 is mounted. Since the bucket 700 is mounted on the bucket mounting unit 130, the condensed water generated in the heat exchanger 400 may be stored in the bucket 700. When the bucket 700 is full of condensate, the user separates the bucket 700 from the bucket mounting unit 130 and discards the condensate, and then mounts the bucket 700 to the bucket mounting unit 130 again.

Bucket mounting portion 130 is applied to a variety of known techniques so that the mounted bucket 700 can support the mounting position without being randomly separated. For example, a protrusion (not shown) may be formed at one side of the bucket mounting unit 130, and a protrusion receiving groove (not shown) corresponding to the bucket 700 may be formed.

The air purification filter 200 is attached on the plate surface of the front cover 110 facing the inside of the casing 100. The air purification filter 200 covers the intake port 111 to filter external humid air sucked into the casing 100 through the intake port 111. As a result, foreign matters and the like contained in the air outside the casing 100 are attached to the heat exchanger 400 or the like, thereby preventing the cause of the failure or lowering the dehumidification efficiency. The air purification filter 200 needs to be replaced periodically because its filtering function is deteriorated with the passage of the service period. Thus, the user may replace the air purification filter 200 after removing the front cover 110 from the casing (100).

The blowing unit 300 is interposed between the heat exchange unit 400 and the exhaust port 121. The blower 300 forms such a series of air flows through which the air outside the casing 100 is sucked through the inlet 111 and discharged to the exhaust port 121 via the heat exchanger 400. Blowing unit 300, the fan unit 310; It includes; a fan unit driving unit 320 for driving the fan unit 310.

The heat exchanger 400 is interposed between the air purification filter 200 and the blower 300. The heat exchanger 400 performs a dehumidifying action on the moist air sucked through the air purification filter 200, and has a circulation structure of a phase transformation refrigerant for this purpose. The heat exchange part 400 includes an evaporator 410 provided on the air purification filter 200 side; It includes; a condenser 420 provided on the blower 300 side. As a result, the air passing through the air purification filter 200 sequentially passes through the evaporator 410 and the condenser 420 and moves toward the blower 300.

The evaporator 410 converts the refrigerant delivered from the condenser 420 from the liquid state to the gas state. In this process, the low temperature refrigerant absorbs heat to become high temperature and lowers the temperature of the area around the evaporator 410 by the principle of vaporization heat. Accordingly, moisture contained in the air surrounding the evaporator 410 is condensed to form on the surface of the evaporator 410, the air is removed to become dry air. The condensed water formed on the surface of the evaporator 410 is collected by the condensate collector 600 by descending on the evaporator 410.

The condenser 420 converts the high temperature gas refrigerant delivered from the compressor 500 into the low temperature liquid refrigerant. Heat is released during the phase transformation of the refrigerant from the gas to the liquid, and thus the temperature around the condenser 420 increases. Accordingly, while the air dehumidified from the evaporator 410 passes through the condenser 420, the air dehumidified becomes high temperature dry air and is discharged to the exhaust port 121.

The compressor 500 is provided below the evaporator 410 and the condenser 420. The compressor 500 compresses the low pressure refrigerant delivered from the evaporator 410, converts the low pressure refrigerant into a high pressure refrigerant, and delivers the refrigerant to the condenser 420. Dehumidification of air is performed in the heat exchange part 400 by a refrigeration cycle of the refrigerant circulating in the evaporator 410, the compressor 500, and the condenser 420.

The condensate collection unit 600 is provided below the evaporator 410 and collects condensate generated from the evaporator 410. The condensate collector 600 is condensed on the surface of the evaporator 410 by moist air passing through the evaporator 410, and collects condensed water falling on the surface of the evaporator 410. The condensate collector 600 has a drain 610 connected to the bucket 700 so that the collected condensate is delivered to the bucket 700.

The bucket 700 is mounted to the bucket mounting unit 130 and stores the condensed water discharged from the drain 610. Bucket 700, the bucket body 710; It includes; a reinforcing rib 720 provided in the bucket body 710.

Bucket body 710, the bucket bottom surface 711; A bucket side wall 713 that is bent upward from the bucket bottom surface 711 to form four-sided side walls of the bucket body 710, and has a box-shaped structure in which the upper side is open. The bucket body 710 has a curved portion 713a in which sidewalls facing the compressor 500 are bent into the bucket body 710 so as not to interfere with the compressor 500 when the bucket body 710 is mounted to the bucket mounting unit 130.

The bucket body 710 stores the condensed water in the inner space formed by the bucket bottom surface 711 and the bucket side wall 713. When the condensed water is filled in the bucket body 710 is provided so that the user can separate the bucket body 710 from the bucket mounting portion 130 to discard the condensate. To this end, the bucket body 710 preferably includes a transparent or semi-transparent material in whole or in part in order to visually check the level of the stored condensate. Alternatively, the bucket body 710 may include a sensor (not shown) that detects the level of the condensate, and notifies the user when the level of the stored condensate reaches a predetermined level, or operates the dehumidifier 1. Stop and the bucket body 710 may be provided to be automatically separated from the bucket mounting portion 130.

Bucket body 710 has a long left and right width and the upper side is open, the plastic material and the inside of the condensed water is stored in the fluid, the nature is susceptible to external shocks and its shape is easy to deform. In particular, in the process of attaching and detaching the bucket body 710 to the bucket mounting portion 130, the bucket body 710 is vulnerable to external force applied in the detachable direction. Thus, a reinforcing rib 720 extending in the detachable direction of the bucket body 710 is provided in the bucket body 710.

The reinforcing rib 720 has a flat plate shape extending along the detachable direction of the bucket body 710 and is formed between the bucket side walls 713 facing each other, thereby supporting the bucket body 710 against an external force. In the exemplary embodiment of the present invention, two reinforcing ribs 720 are provided in the bucket body 710, but the quantity thereof is not limited to the above exemplary embodiment.

The reinforcing rib 720 includes a cutout portion 721 formed at an upper side thereof; It includes; condensed water moving hole 723 formed through a region of the lower plate surface in contact with the bucket bottom surface 711.

The cutout 721 is formed by cutting a region of the upper side of the reinforcing rib 720 adjacent to the open upper side of the bucket body 710. If there is no cutout 721, the bucket body 710 is supported by the reinforcing ribs 720 in its detachable direction, so that the elastic deformation of the bucket body 710 with respect to the detachable direction is difficult. Therefore, the cutout 721 corrects the elasticity of the external force applied to the bucket body 710 when the bucket body 710 is attached and detached. In addition, the cutout 721 allows the condensed water to easily flow between the inner portions of the bucket body 710 partitioned by the reinforcing ribs 720.

The condensate movement hole 723 is formed in one region of the reinforcing rib 720 in contact with the bucket bottom surface 711. The condensate discharged through the drain 610 is stored in the bucket body 710, and the condensate starts from the bottom of the bucket 711 and rises along the bucket side wall 713. However, since the inside of the bucket main body 710 is divided into a plurality of areas by the reinforcing ribs 720, in the case where there is no condensate water moving hole 723, only the area immediately below the drainage part 610 among the plurality of divided areas. The condensate will fill up. Accordingly, by providing the condensate movement hole 723 under the reinforcing rib 720 in contact with the bucket bottom surface 711, the entire bucket bottom surface 711 regardless of the region where the condensate is partitioned by the reinforcing rib 720. To flow. As a result, the condensate is uniformly distributed throughout the bucket bottom surface 711.

By this structure, the operation | movement of the dehumidifier 1 which concerns on this invention is demonstrated with reference to FIGS.

The fan unit driver 320 drives the fan unit 310. As the fan unit 310 rotates, the air outside the casing 100 moves the intake port 111, the air purification filter 200, the heat exchanger 400, the blower 300, and the exhaust port 121. Flow is formed. Thus, humid air outside the casing 100 is sucked into the inlet 111.

The air sucked into the intake port 111 passes through the air purification filter 200 and is filtered. The air moves to the heat exchanger 400, and dehumidification is performed by the evaporator 410. In the evaporator 410, condensed water is generated on its surface by a dehumidifying action. The dry air dehumidified through the heat exchange unit 400 passes through the blower unit 300 and is discharged through the exhaust port 121.

Condensate formed in the evaporator 410 flows down the surface of the evaporator 410. The condensate is collected by the condensate collector 600 under the evaporator 410, and is discharged to the bucket 700 through the drain 610.

The inside of the bucket 700 is divided into a plurality of regions by the reinforcing rib 720. The condensed water is discharged to the area in which the drainage part 610 is provided. The condensed water reaching the bucket bottom surface 711 flows through the condensate movement hole 723 and is uniformly distributed throughout the bucket bottom surface 711.

As the condensate is discharged, the condensate flows through the condensate movement hole 723 to the entire area of the bucket 700, and the condensate rises to the same level in the bucket 700 regardless of the partition area by the reinforcing rib 720. do.

As such, by forming the condensate movement hole 723 in the reinforcing rib 720 in the bucket 700, it is possible to prevent the condensate from being distributed and stored in the bucket 700 unevenly.

As described above, according to the present invention, there is provided a dehumidifier which prevents deformation and breakage of the bucket and uniformizes the distribution of condensate stored in the bucket, thereby improving the reliability and ease of use of the product.

Claims (4)

In the dehumidifier, A casing having an inlet port and an exhaust port spaced from the inlet port; A heat exchanger provided inside the casing and configured to dehumidify air introduced from the intake port and discharge the air to the exhaust port; A condensate collection unit provided below the heat exchanger and collecting condensate generated from the heat exchanger; A bucket including a bucket body detachably provided at the casing and storing the collected condensate, and a reinforcing rib having a condensate moving hole formed in a region supporting the inside of the bucket body and in contact with the bottom surface of the bucket body; Dehumidifier comprising a. The method of claim 1, The reinforcing rib, the dehumidifier characterized in that extending along the detachable direction of the bucket body. The method of claim 1, The reinforcing rib has a dehumidifier characterized in that it has a cutout formed on the upper side. The method according to any one of claims 1 to 3, And a blower interposed between the heat exchange part and the exhaust port, and configured to suck air outside the casing into the intake port and discharge the air through the heat exchange part to the exhaust port.

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