KR20230049071A - Clothes Dryer - Google Patents

Abstract

A clothes dryer having a plurality of water storage tanks is disclosed to reduce the frequency of lifting condensed water generated from an evaporator to a high place and reduce the failure or noise of a drain pump. A clothes dryer includes a housing having a space inside to accommodate clothes, a heat pump device provided inside the housing to heat air to be supplied to the clothes and including a compressor, a condenser, and an evaporator, a first water storage tank provided to store condensate generated when air passes through the evaporator, a second water storage tank provided to store water transferred from the first storage tank, a pump provided between the first and second water storage tanks to transfer water from the first water storage tank to the second water storage tank, a first water level detector provided to detect the water level of the first water storage tank, and a second water level detector provided to detect the water level of the second water storage tank.

Description

Dryer {Clothes Dryer}

The present invention relates to a dryer having a heat pump cycle and having a structure for discharging dehumidified water generated in an evaporator.

[0002] A dryer for drying clothes is an example of a clothes treatment device, and includes a heat pump cycle composed of a compressor, a condenser, and an evaporator as a heat source. In such a dryer, a blowing path through which air flow passes is formed in the order of a condenser, a drum accommodating wet clothes, and an evaporator by a blower, and the circulated or intake air flow is warmed in the condenser, and the warmed air flow It is configured to evaporate the moisture of the clothes in the drum with the heat of the drum and at the same time recover the heat in the evaporator from the air flow containing a large amount of moisture passing through the drum. However, when heat is recovered from the air stream in the evaporator, since the temperature of the air stream is lowered, moisture contained in the air stream is condensed in the evaporator and appears as dehumidifying water.

This dehumidified water is temporarily stored, for example, in a dehumidified water reservoir installed at the lower part of the dryer or the lower part of the evaporator, and discarded by the user or discharged together with the laundry waste water if it is integrated with the washing machine. For example, in Japan, etc., since a drain mechanism such as a waterproof fan is installed in advance on the floor of a room where a washing machine or dryer is installed, the dehumidified water can flow from the dehumidified water reservoir to the drain below by gravity. .

However, in houses in Europe and the United States, washing machines and dryers are often installed in basements where drainage devices such as waterproof fans, such as those in Japan, are not installed. Therefore, in order to flow the dehumidified water of the dryer to the sewer pipe installed near the ground, it is necessary to pump up about 3 m to the vicinity of the ground once and discharge it.

Even in Japan, the height at which the dehumidifying water (W) is pumped is low compared to Europe and the United States, but this is disclosed in Japanese Patent Laid-Open No. 2006-087672, and as in the dryer 100 shown in FIG. 5, the dehumidifying water storage (3 ) by lifting the dehumidified water (W) stored in the drum 14 by the drain pump 6 to the height at which the drum 14 is installed, the drain hose connected to the drum 14 and connected to the drain on the bottom surface ( 7) Some have a drainage mechanism for dropping and flowing the dehumidifying water (W).

However, with reference to the structure in which dehumidifying water (W) is lifted by a drain pump as shown in Japanese Patent Application Laid-Open No. 2006-087672, as shown in FIG. 6, dehumidifying water (W) dehumidification having a water storage tank (3) for storing water, and a drain pump (6) with high power that can be discharged by lifting about 3m when the water storage tank (3) is almost full of dehumidifying water (W). If the drainage mechanism of the number W is used, various problems as described below will occur.

First, the water storage tank 3 of FIG. 6 is configured to store the dehumidified water (W) generated in the evaporator 13 by gravity by dropping it naturally, and needs to be installed in the lower part of the drum 14 or the evaporator 13. there is Since the height and the like of the drum 14 are determined to some extent due to restrictions on use, it is difficult to increase the storage capacity by increasing the height of the water storage tank 3. Therefore, the volume of the water storage tank 3 has no choice but to be made small.

Also, as shown in Fig. 6(a), even if the dehumidified water W stored until the water storage tank 3 is almost full is discharged through the drain hose 7 by the drain pump 6 with high output. 6 (b), when the dehumidifying water (W) on the storage tank (3) side is gone, it is necessary to stop the drainage pump (6) to prevent idle operation, malfunction, and noise. Then, since the drain hose 7 has a length of about 3 m and an inner diameter of about 13 mm in many cases, a large amount of dehumidified water W of about 0.4 L is stored in the water storage tank 3 as shown in FIG. ) returns to me. That is, once the drainage of the dehumidified water (W) is started, most of the storage tank (3) becomes a dead volume, and the dehumidified water (W) is not discharged and is continuously stored, so that the amount of dehumidified water (W) that can be stored will give In addition to having to reduce the volume of the water storage tank 3, the area that effectively acts for drainage is reduced, so the water storage tank 3 is immediately filled with dehumidified water W, and the drain pump ( 6) must be operated, and the number of times of ON/OFF per unit time increases, causing failure of the drain pump 6 earlier than usual. In addition, if the drain pump 6 of high output is operated frequently, its noise also becomes a problem.

Japanese Unexamined Patent Publication No. 2006-087672

The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a dryer capable of reducing the frequency of lifting dehumidified water generated in an evaporator to a high place and reducing malfunction or noise of a drain pump. .

In addition, a dryer provided with two water storage tanks and water level sensors is provided so that drainage is performed smoothly.

A dryer according to the spirit of the present invention includes a housing provided with a space for accommodating clothes therein, a heat pump device provided to heat air to be supplied to the clothes, and including a compressor, a condenser, and an evaporator, and heat exchange between the air and the evaporator. A first storage tank provided to store the condensed water generated through the storage, a second storage tank provided to store the water transferred from the first storage tank, and the transfer of water from the first storage tank to the second storage tank. A pump provided between the first storage tank and the second storage tank, a first water level detector provided to detect whether water is accommodated up to a first predetermined water level corresponding to a prescribed water level in the first storage tank, It includes a second water level detection unit provided to detect whether water is accommodated up to a second predetermined water level corresponding to a prescribed water level in the second water storage tank, and a drainage control unit provided to control the operation of the pump.

The pump may be disposed at a side of a lower end of the first storage tank to transfer water from the first storage tank and may be positioned lower than the first water level detection unit.

When the prescribed quantity of the second storage tank is greater than the prescribed quantity of the first storage tank, and the drainage control unit detects that the water level in the first storage tank is the first predetermined water level by the first water level detection unit. The pump is operated for a set predetermined time so that the water in the first storage tank is automatically transferred to the second storage tank, and the water level in the second storage tank is determined by the second water level detection unit to be the second predetermined water level. The transfer operation of the pump may be performed a plurality of times until detection. An opening is formed in the second storage tank so that air inside the second storage tank can be discharged to the outside when water flows into the second storage tank.

The drainage control unit may operate the pump for a predetermined time until the water level in the first storage tank becomes approximately zero from the first predetermined water level.

The pump may be disposed side by side with the first storage tank to the side of the first storage tank.

The second water level detection unit may be installed at a position lower than the highest water level of the second storage tank so that the second predetermined water level is set lower than the highest water level of the second storage tank.

The second water storage tank may be located lower than the space in which clothes are accommodated.

The first water level detection unit may be disposed at a position lower than the evaporator, and the second water level detection unit may be disposed at a position higher than the first level detection unit and lower than the highest part of the evaporator.

The dryer may further include an evaporator case accommodating the evaporator, and the second water level detector may be disposed at a position lower than a highest part of the evaporator case.

An opening of the second water storage tank may be provided at a higher position than the second water level detector.

The opening of the second storage tank may be provided at a position higher than the highest water level of the second storage tank.

The dryer may further include a pipe communicating with the opening of the second water storage tank.

The first storage tank may be located below the evaporator so that the condensate generated in the evaporator is collected in the first storage tank by gravity.

The second water level detector may include a liquid level detection sensor.

The second water storage tank may have a rectangular parallelepiped shape.

The second storage tank may have a larger volume than the first storage tank.

A dryer according to another aspect of the present invention is a dryer having a heat pump cycle composed of a compressor, a condenser, and an evaporator, and a blowing path through which air flows through the condenser, a drum accommodating clothes to be dried, and the evaporator in that order. , a first storage tank for storing the dehumidified water generated by passing the air flow through the evaporator, connected to the first storage tank, having a larger volume than the first storage tank, and transferring from the first storage tank A second storage tank for storing the dehumidified water, a drain pipe having one end opened at a position higher than the second storage tank, connected to the second storage tank and the other end of the drain pipe, and connected to the second storage tank It is characterized in that it is provided with a drain pump for discharging the stored dehumidifying water to the outside from one end of the drain pipe.

With this structure, the dehumidified water generated in the evaporator is first collected in the first storage tank, and whenever the amount of dehumidified water stored in the first storage tank reaches a predetermined amount, the volume of the dehumidified water is larger than that of the first storage tank. By transferring the dehumidified water to the second storage tank, a larger amount of dehumidified water than can be stored in the first storage tank may be stored in the second storage tank. Therefore, since the sum of the amount of dehumidifying water when pumped up to a high place through the drain pipe by the drain pump and discharged to the outside can be increased, the number of ON/OFF switching times per unit time of the drain pump can be reduced. In addition, since the number of times of ON/OFF switching per unit time of the drain pump can be reduced, power consumption required to operate the drain pump and deterioration or failure of the drain pump can be reduced, and at the same time, in order to lift dehumidified water to a high place, a large amount of output can be obtained. Even if it is, since the number of startups can be reduced, the noise of the drainage pump can also be reduced.

Furthermore, since the dehumidified water is stored in the second storage tank, the volume of the first storage tank can be reduced, and the first storage water can be easily located in a place where there is no space such as the lower part of the drum or the lower part of the evaporator in the dryer. Tanks can be installed.

In addition, the second water storage tank can be installed at a distance from the first water storage tank, and can be installed in a place with sufficient space in the dryer, and its volume can be easily increased. Furthermore, since the volume of the second water storage tank can be set large, even dehumidified water returning from the drain pipe when the drain pump is stopped can be absorbed by the second water storage tank with a margin.

The dehumidified water generated from the evaporator can be stored in the first storage tank with a simple configuration, and a pipe or seal between the case accommodating the evaporator and the first storage tank is also unnecessary, so that it is inexpensive. For this purpose, the first water storage tank may be integrally installed in the lower part of the evaporator case accommodating the evaporator.

In order to minimize power consumption or noise when transferring the dehumidified water from the first storage tank to the second storage tank, a transfer pump for transferring the dehumidified water from the first storage tank to the second storage tank is further provided. It should be provided. In this way, if the transfer pump is installed between the first storage tank and the second storage tank, since it is not necessary to lift the dehumidified water to a high place like the drain pump, a small transfer pump can be selected. can Therefore, since the transfer pump is of a small size, noise can be significantly reduced. In addition, when noise can be reduced, it is also possible to keep the transfer pump running, for example, all the time, making it easier to downsize the first water storage tank and making it less likely to be restricted in the installation location.

As a setting of each pump that is particularly effective in reducing noise and malfunction, it is exemplified that the drainage pump is configured with a high lift and convective flow compared to the transfer pump.

In order to enable the transfer of dehumidified water from the first storage tank to the second storage tank and discharge of the dehumidified water from the second storage tank to the outside and to reduce costs with only one drain pump, the drain pump What is necessary is just to further have a switching mechanism for switching between a first state in which the second storage tank is connected to the drain pipe and a second state in which the drain pump is connected to the first storage tank and the second storage tank.

In order to automatically process the dehumidified water stored in each water storage tank while reducing the number of ON/OFF times of each pump per unit time, a first water level detector for detecting the water level of the first water storage tank; a second water level detection unit for detecting a water level of the water level, and dehumidified water from the first water storage tank to the second water storage tank when the first water level detection unit detects that the water level in the first storage tank is a first predetermined water level. When the transfer pump or the drainage pump is operated for a first predetermined time to transfer the water, and the second water level detection unit detects that the water level in the second water storage tank is the second predetermined water level, the second water tank is removed from the outside. It may further include a drainage control unit configured to operate the drainage pump for a second predetermined time to discharge the dehumidified water.

In order to reliably prevent water leakage or backflow to the first storage tank or the evaporator due to backflow from the drain pipe, the second predetermined water level is set lower than the water level corresponding to the volume of the drain hose from the highest water level in the second storage tank. It should be. With this configuration, the second water storage tank may always have a capacity to prepare for backflow from the drain pipe.

In order to increase the volume of the second storage tank that effectively discharges the dehumidifying water to the outside and at the same time to reduce the possibility that the transfer pump and the drainage pump operate simultaneously, the drainage controller is configured to operate the dryer at the start of operation. may be configured to operate the drain pump for a third predetermined time regardless of the output of the second water level detection unit.

In order to reduce the resistance when transferring the dehumidified water from the first storage tank to the second storage tank and to facilitate miniaturization of the transfer pump, the second storage tank may have an air discharge pipe.

In order to further prevent leakage and construct the air discharge pipe at low cost, the air discharge pipe should be connected to the drain pipe at a position higher than the highest water level of the second storage tank.

As described above, according to the dryer of the present invention, a first water storage tank and two second water storage tanks are prepared, and a large amount of dehumidified water can be stored in the second water storage tank having a large capacity.

In addition, since the drain pump is configured to lift the dehumidified water to a high place at once and discharge the dehumidified water, the number of ON/OFF switching of the drain pump per unit time can be reduced. Accordingly, failure or deterioration of the drainage pump and power consumption can be reduced.

1 is a schematic diagram showing the configuration of a dryer according to a first embodiment of the present invention.
Fig. 2 is a schematic diagram showing the relationship between the drying time and the amount of dehumidifying water generated in the first embodiment of the present invention.
3 is a schematic diagram showing the configuration of a dryer according to a second embodiment of the present invention.
Fig. 4 is a schematic diagram showing the configuration of a dryer according to a third embodiment of the present invention.
5 is an example of a configuration of lifting and discharging dehumidified water in a conventional dryer.
6 is a schematic diagram illustrating a problem related to reverse flow of dehumidifying water that occurs when a drainage mechanism of a conventional dryer is adapted to discharge dehumidifying water from a high place.

EMBODIMENT OF THE INVENTION 1st Embodiment of this invention is described, referring drawings.

The dryer 100 of the first embodiment uses a heat pump cycle 1 composed of a compressor 11, a condenser 12, and an evaporator 13, and is for drying wet clothes.

As shown in FIG. 1, the dryer 100 has a blowing path 2 through which air flows in the order of the condenser 12, the drum 14 accommodating clothes, and the evaporator 13, This air stream is formed by a blower (15) installed downstream of the evaporator (13). With this configuration, the airflow receives heat from the condenser 12 and becomes warm, evaporating moisture from the clothes in the drum 14. In addition, the air stream containing moisture is exhausted from the blower 15 at the same time as heat is recovered from the evaporator 13 . In addition, the dehumidified water (W) is condensed in the evaporator (13) due to the temperature decrease of the air flow.

The dryer 100 of the first embodiment includes a drainage mechanism 200 for discharging the dehumidified water W generated in the evaporator 13 to the outside. In addition, the drain from the dryer 100 is not discharged to a drain located at a lower position than the dryer 100 installed on the floor or the like, but dehumidified water W is discharged to a drain part installed about 3 m above, for example. It is configured to be lifted and discharged.

As shown in FIG. 1, the drainage mechanism 200 includes a first water storage tank 3, a transfer pump 4, and a second water storage tank 5 installed from the evaporator 13 to an external drainage area. ), a drainage pump (6), and a drainage hose (7). Furthermore, this drainage mechanism 200 is provided with a drainage controller (not shown) that controls the transfer pump 4 and the drainage pump 6 . Briefly explaining the function of each part, the first storage tank 3 is for temporarily storing the dehumidified water W generated in the evaporator 13, and the dehumidified water in the first storage tank 3 The dehumidified water (W) is transferred to the second storage tank (5) by the transfer pump (4) when the water (W) is full or reaches a specified amount. By repeating this operation several times, when the water quantity in the second storage tank 5 is full or reaches the specified quantity, the drain pump 6 and the drain hose 7 dehumidify the outside of the dryer 100. It is designed to discharge water (W). In addition, one end of the drain hose 7 is opened at a position approximately 3m above the point where the second water storage tank 5 is installed, and the other end is installed at the drain pump 6.

Hereinafter, each part will be described in detail.

The first water storage tank 3 is connected to the evaporator case 131 accommodated in the evaporator 13 by a pipe, and is installed below the evaporator 13 . That is, droplets of the dehumidifying water W generated in the evaporator 13 are collected in the first storage tank 3 by gravity movement. Describing the shape and size of the first water storage tank 3, it has a substantially rectangular parallelepiped shape that can be accommodated in the lower space of the evaporator 13 inside the housing of the dryer 100. Compared to the second water storage tank 5 described later, its volume is formed small, and it is formed small so that it can be placed in a position suitable for collecting the dehumidified water W from the evaporator 13. It is determined whether the upper part of the first storage tank 3 is filled with dehumidifying water W or whether the dehumidifying water W is stored in the first storage tank 3 up to a first predetermined water level corresponding to the prescribed amount. A first water level detector 31 for detection is provided. Examples of the first water level detection unit 31 include a liquid level detection sensor, and various sensors such as a contact type and a non-contact type can be used. In this embodiment, the first water level detector 31 detects only whether or not the water level in the first water storage tank 3 is the first predetermined water level, but may be capable of sequentially measuring other water levels.

The transfer pump 4 is a small-sized and low-capacity pump compared to the drain pump 6 described later, and transfers the dehumidified water W from the first storage tank 3 to the second storage tank 5. It is to do. Here, the transfer pump 4 has the ability to lift the dehumidifying water W up to the height of the dryer housing, and lifting the dehumidifying water upward by about 3 m is not expected.

The second water storage tank 5 is installed in a part where a large space can be secured in a place different from the lower part of the drum 14, the evaporator 13, etc. in the dryer housing, and the first It has a larger volume compared to the water storage tank 3. More specifically, when the first water storage tank 3 has a volume of about 0.1 L, the second water storage tank 5 has a volume of about 1.0 L. That is, the second water storage tank 5 is configured to have a volume about 10 times that of the first water storage tank 3 . The size of each tank is set in this way, for example, as shown in FIG. 2, when clothes of about 3.6 kg are dried, the total amount of dehumidifying water (W) is about 1000 mL, and dehumidification occurs in one minute. It is based on the fact that the amount of water (W) is about 50 mL/min. Furthermore, the second water storage tank 5 also has a substantially rectangular parallelepiped shape, and a second water level detection unit for detecting whether or not the dehumidified water W is stored up to a second predetermined water level corresponding to a predetermined water level at an upper portion of the second water storage tank 5. (51) is installed. This second water level detection unit 51 also uses a liquid surface detection sensor similarly to the first water level detection unit 31, but other water level detectors and water quantity measuring devices may be used.

In more detail about the installation position of the second water level detector 51, the second predetermined water level is when the drain pump 6 discharges the dehumidified water W from the drain hose 7 to the outside. At this time, the second water level detection unit 51 is configured to absorb the volume of the dehumidified water W in the drain hose 7, that is, the volume of the drain hose 7 even when reverse flow occurs. It is installed at a position lower than a predetermined water level from In addition, an opening is provided on the upper surface of the second water storage tank 5 so that internal air can be discharged to the outside even when dehumidified water W enters the inside. An air discharge pipe 52 is installed in this opening, and the air discharge pipe 52 is installed to join the drain hose 7 at a position higher than the highest water level of the second storage tank 5.

The drain pump 6 has the ability to discharge the dehumidified water W collected in the second storage tank 5 to the outside after lifting it up to a height of about 3 m. That is, compared to the transfer pump 4, the drainage pump 6 is composed of a high lift and convective flow. More specifically, the transfer pump 4 has a head capacity of 0.5 m and a flow rate of 0.5 L/min, whereas the drain pump 6 has a head capacity of 3.0 m and a flow rate of 10 L/min.

The drainage control unit controls the operation of the transfer pump 4 and the drainage pump 6, and its function is performed by a so-called computer or microcomputer equipped with input/output means such as a CPU, memory, and A/D converter. It will come true. More specifically, the drainage control unit, when it is detected by the first water level detection unit 31 that the water level of the first storage tank 3 is a first predetermined water level, controls the water drainage from the first water tank 3 to the first water level. 2 In order to transfer the dehumidified water (W) to the water storage tank (5), the transfer pump (4) or the drainage pump (6) is operated for a first predetermined time, and the second water level detector (51) detects the second stored water. When it is detected that the water level in the tank 5 is at the second predetermined water level, the drainage pump 6 is operated for a second predetermined time to discharge the dehumidified water W from the second storage tank 5 to the outside. It is configured to drive as much as possible.

Here, the first predetermined time is the time from when the transfer pump 4 is operated until the water level in the first storage tank 3 becomes approximately zero from the first predetermined water level, for example, experimentally. You have to decide. The second predetermined time is the time from when the drain pump 6 is operated until the water level in the second storage tank 5 becomes approximately zero from the second predetermined water level, and may be determined experimentally as well. . In this way, since the operation of the transfer pump 4 and the drainage pump 6 are controlled based on time rather than water level, the dehumidified water W can be efficiently discharged with a simple configuration. can

In addition, when the dryer 100 is started, the drainage control unit operates the drain pump 6 for a third predetermined time regardless of outputs from the first water level detection unit 31 and the second water level detection unit 51. It is configured to operate. In this way, even when the dryer 100 is started, the drain pump 6 is operated so that the inside of the second storage tank 5 is substantially emptied and a sufficient amount of dehumidified water W can be stored. Therefore, it is easy to shift the operating timings of the transfer pump 4 and the drainage pump 6, and the possibility that both pumps are operating can be reduced. Therefore, it is possible to prevent generation of loud noise due to simultaneous operation of each pump.

<Effects of the first embodiment>

According to the dryer 100 of the first embodiment configured as described above, the dehumidified water W generated in the evaporator 13 is stored in the small first water storage tank 3 installed below the evaporator 13. It can be collected without using power by using gravity. And whenever the dehumidified water (W) is stored up to the first predetermined water level in the first storage tank (3), it is transferred to the large-sized second storage tank (5) by the transfer pump (4) having a small output and a small output. After transferring the dehumidifying water (W) in a large amount, the dehumidifying water (W) can be lifted to a high place by the drain pump 6 of high output and discharged to the outside. That is, the dehumidified water (W) is not divided into several small portions and lifted to a high place, but is collected in a large amount in the second water storage tank 5 and then discharged to the outside. repetitions can be reduced. Therefore, it is possible to prevent the life of the drain pump from being remarkably shortened due to the frequent operation of the drain pump, and at the same time, the noise of the drain pump 6 can be significantly reduced due to the small number of operations.

Furthermore, since the second water storage tank 5 has a larger volume than the first water storage tank 3 and can store a large amount of dehumidified water W until discharged, one time dehumidified water W The ratio of the volume of the dehumidified water (W) flowing back from a high place to the second water storage tank 5 when the discharge pump is stopped to the volume that can be discharged through discharge can be significantly reduced, and at the time of discharge The volume of the dehumidifying water W serving as the dead volume can be made as small as possible. Therefore, compared to the conventional one, one end of the drain hose 7 is opened at a higher place, and even when the dehumidified water W is discharged by lifting it to a higher place, the dehumidified water W can be efficiently discharged to the outside. .

In addition, since it has the first storage tank 3 and the second storage tank 5, the first storage tank 3 is suitable for collecting the dehumidified water W generated from the evaporator 13. In addition to miniaturization to be installed in a narrow place, the second water storage tank 5 may be enlarged to store as much dehumidifying water W as possible until the dehumidifying water W is discharged.

Therefore, even if there are restrictions due to the arrangement of the main member, such as the drum 14 or the evaporator 13, in the dryer housing, the first water storage tank 3 is small and can be installed without being affected. In other words, the degree of freedom in the design of the first water storage tank 3 and the second water storage tank 5 can be increased.

Further, modified embodiments of the first embodiment will be described. In the first embodiment, the transfer pump 4 is operated for a predetermined time when the water level in the first storage tank 3 reaches the first predetermined water level, but is always operated when the noise is sufficiently small. You can do it.

Next, the dryer 100 of the second embodiment will be described. In addition, the same code|symbol is attached|subjected to the same member as 1st Embodiment.

As shown in FIG. 3, the drainage mechanism of the dryer 100 of the second embodiment differs from the first embodiment in the installation method of the first water storage tank 3. In the first embodiment, the evaporator case 131 and the first storage tank 3 are installed separately, but in the second embodiment, the first storage tank 3 is integrated with the lower part of the evaporator case 131. I have it installed.

<Effect of the second embodiment>

With this structure, the first water storage tank 3 can be reduced in size and the dehumidified water W can be efficiently collected. In addition, by integrally installing, there is no need to install a pipe connecting the evaporator case 131 and the first water storage tank 3 or a seal to prevent water leakage, so that a simpler structure can be achieved.

Next, the dryer 100 of the third embodiment will be described. In addition, the same code|symbol is attached|subjected to the same member as 1st Embodiment.

In the drainage mechanism 200 of the dryer 100 according to the third embodiment, the transfer pump 4 is not provided, and the second water storage tank 5 is removed from the first water storage tank 3 only by the drainage pump 6. ) and discharge of the dehumidified water W from the second water storage tank 5 to the outside.

That is, the drainage mechanism 200 is configured in a first state in which the drainage pump 6 is connected to the second storage tank 5 and the drain pipe, and in which the drainage pump 6 is connected to the first storage tank 3 and a switching mechanism 8 for switching the second state connected to the second water storage tank 5.

More specifically, as shown in FIG. 4, the first water storage tank 3 is piped below the drain pump 6 and the second water tank 5 through a first switching valve 81 which is a three-way valve. connected by In addition, the drain pump 6 is connected to the other end of the drain hose 7 and the top of the second storage tank 5 by a pipe through a second switching valve 82 which is a three-way valve. Further, the drainage controller is configured to control the direction of the first selector valve 81 and the second selector valve 82 to also control switching of the connection of each member.

The drainage control unit is shown in FIG. 4(a) when the first water storage tank 3 reaches a first predetermined water level and transfers the dehumidified water from the first water storage tank 3 to the second water storage tank 5. As shown in the figure, the first switching valve 81 is controlled so that the first storage tank 3 and the drain pump 6 communicate with each other and at the same time, the piping to the second storage tank 5 side is closed. Furthermore, the drainage controller controls the second switching valve 82 to communicate with the drainage pump 6 and the second water storage tank 5 and at the same time block the drain hose 7 side. After that, the drain control unit operates the drain pump 6 .

When discharging the dehumidified water (W) from the second storage tank (5) to the outside through the drain hose (7), the drainage control unit is directed to the first switching valve (81) to the second storage tank ( 5) communicates with the drain pump 6 and controls to close the first storage tank side, and communicates the drain pump 6 and the drain hose 7 for the second switching valve 82 The side of the second water storage tank 5 is controlled to be closed. After that, the drainage controller operates the drainage pump 6 to discharge the dehumidified water W to the outside.

<Effects of the third embodiment>

According to the dryer 100 of the third embodiment configured as described above, the number of pumps used is reduced, and at the same time, the transfer of the dehumidified water W from the first storage tank 3 to the second storage tank 5 and the above The dehumidified water W can be discharged from the second water storage tank 5 to the outside.

Other embodiments will be described.

In each of the above embodiments, a drain hose is shown as an example of a drain pipe for discharging dehumidified water from the second water storage tank to the outside, but a pipe other than the hose may be used.

In addition, the shapes of the first water storage tank and the second water storage tank are not particularly limited, and may be modified according to arrangements of other drums or evaporators. That is, the capacity of the second water storage tank may be larger than that of the first water storage tank.

In addition, various combinations or modifications of the various embodiments may be performed within the limits that do not violate the spirit of the present invention.

100: dryer 1: heat pump cycle
11: compressor 12: condenser
13: evaporator 131: evaporator case
14: drum 2: blowing path
3: first water storage tank 31: first water level detector
4: transfer pump 5: second water storage tank
51: second water level detection unit 52: air discharge pipe
6: drain pump 7: drain hose (drain pipe)
8: conversion mechanism

Claims (10)

A housing provided with a space for receiving clothes therein;
a heat pump device provided to heat air to be supplied to the clothes and including a compressor, a condenser, and an evaporator;
a first water storage tank provided to store condensed water generated through heat exchange between air and the evaporator;
a second storage tank provided to store water transported from the first storage tank;
a pump provided between the first storage tank and the second storage tank to transfer water from the first storage tank to the second storage tank;
a first water level detection unit provided to detect whether water is stored up to a first predetermined water level corresponding to a prescribed quantity of water in the first water storage tank;
a second water level detection unit provided to detect whether water is stored up to a second predetermined water level corresponding to a prescribed quantity of water in the second water storage tank; and
And a drainage control unit provided to control the operation of the pump,
The pump is disposed at a side of a lower end of the first storage tank to transfer water from the first storage tank and is positioned lower than the first water level detection unit. According to claim 1,
The drainage control unit operates the pump for a predetermined time until the water level in the first storage tank becomes approximately zero from the first predetermined water level. According to claim 1,
The dryer of claim 1, wherein the pump is disposed side by side with the first storage tank in a side of the first storage tank. According to claim 1,
The first water level detection unit is provided at a lower position than the evaporator. According to claim 1,
The second water level detection unit is disposed at a position higher than the first water level detection unit and lower than the highest part of the evaporator case in which the evaporator is accommodated. According to claim 1,
An opening is formed in the second storage tank so that air inside the second storage tank can be discharged to the outside when water flows into the second storage tank,
The opening of the second water storage tank is provided at a higher position than the second water level detector. According to claim 6,
Dryer further comprising a pipe communicating with the opening of the second water storage tank. According to claim 1,
The first storage tank is located below the evaporator so that the condensate generated in the evaporator is collected in the first storage tank by gravity. According to claim 1,
The second water level detection unit includes a liquid level detection sensor. According to claim 1,
The second storage tank has a larger volume than the first storage tank.

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