KR20110116340A - Laundry machine - Google Patents

Abstract

The present invention relates to a device having a function of drying a garment, in particular as a drying object. Such a device may be referred to as a clothing device having a drying function.
According to the present invention, the heater is turned on to start the hot air drying, the heater is turned off at a predetermined upper limit temperature (T1) and the heater is turned on at a predetermined lower limit temperature (Ta) is repeated clothing is performed hot air drying In the apparatus, it is possible to provide a garment apparatus characterized in that the predetermined upper limit temperature is raised (T3) after a predetermined time after the predetermined upper limit temperature (T1) is first reached after the start of the hot air drying.

Description

Clothing Machine {Laundry Machine}

The present invention relates to a device having a function of drying a garment, in particular as a drying object. Such a device may be referred to as a clothing device having a drying function.

The clothing device having a drying function has a drying-only device having only a drying function, and there is a drying combined washing device having a washing function of clothes. Moreover, according to the structure or the form, there exists a drum type device which dries clothes while using a rotatable drum, and a so-called cabinet type device which hangs and dries clothes.

In general, a conventional dry laundry machine includes a tub for receiving the wash water for washing water. In the tub, a drum in which laundry is located is rotatably installed.

The drum is connected to a rotating shaft, and a motor is used to rotate the rotating shaft.

The rotating shaft is rotatably supported by a bearing housing installed on the rear wall of the tub. A suspension is connected to the tub, and vibrations of the drum and the tub are dampened by the suspension.

For drying functions, drying ducts and condensation ducts are included. The drying duct is located at the top of the tub and the heater and fan are installed inside. One end of the condensation duct is connected to the tub and the other end is connected to the drying duct.

In addition, cooling water is supplied into the condensation duct to condense the moisture contained in the wet air. The wet air is introduced into the drying duct after the moisture is removed while contacting the cooling water while flowing the condensation duct. The hot air returned to the drying duct is reheated through the heater and supplied to the tub again. In this way, the air is circulated to dry the way is called a circulation type, there is an exhaust type method in contrast.

Exhaust type is widely used in drying equipment, especially drum type dryers. In such a dryer, the humid air inside the drum is discharged to the outside of the dryer without entering the drying duct. And the drying duct outside the dryer is introduced into the drying duct is heated. Therefore, the exhaust system does not include a condensation duct or the like for condensing moisture in the air.

An important factor in the drying of the garment apparatus is the drying time. The drying time corresponds to most of the time for supplying hot air. In other words, it takes most of the time to remove moisture by applying hot air to wet clothing and heating it.

As the temperature of hot air increases, the amount of saturated steam increases, so it is well known that the temperature of hot air must be increased for faster drying. However, in consideration of the heat damage of the laundry and the overheating of the clothing apparatus, the temperature of the hot air is controlled within an appropriate range. In general, the temperature of the hot air is controlled by turning on / off the heater through the temperature of the heater or the temperature near the heater.

Referring to the heater control or hot air temperature control method in the conventional clothing apparatus in detail as follows.

First, after turning on the heater and operating the fan, hot air is supplied into the tub and drum to heat clothes and moisture. In the initial stage of hot air supply, since the heater is continuously on, the temperature of the hot air continuously increases. Thus, the temperature of clothing and moisture also increases continuously.

On the other hand, excessive rise in hot air temperature is limited in consideration of the material of drying clothes and the boiling temperature of water. To this end, the heater may be controlled to be turned off at a predetermined upper limit temperature (for example, 106 degrees Celsius) after the initial heater is turned on. Of course, the fan can be operated continuously, intermittently or periodically while the heater is off. Thus, the temperature of the hot air will decrease. Here, the excessively low temperature of the hot air means an increase in drying time, so that the heater is turned on again at a predetermined lower limit temperature (eg, 103 degrees Celsius).

That is, by controlling the heater to be turned off at the upper limit temperature and turned on at the lower limit temperature to prevent excessive temperature rise of the hot air, while preventing excessive temperature drop, hot air drying is effectively performed.

However, such heater control involves the following problem.

Since the heater control controls on / off of the heater based on the temperature of the heater or the temperature near the heater, there is a problem that it is not possible to prevent overheating that may occur at a certain portion on the entire flow path through which the air is circulated.

More specifically, hot air heated after dehumidification is supplied between the heater and the drum based on the heater and the drum, heat exchange is performed in the drum or the tub, and heat exchanged after the dehumidification is introduced into the heater. Therefore, there is a problem that the room for overheating is very large on the hot wind flow path between the drums and the heaters. This is because there is no object that heat is effectively transmitted like moisture on the flow path. In particular, since hot air is continuously supplied at the initial stage of hot air supply, the overheating margin on the hot air flow path between the heater and the drum may be increased.

Such overheating may cause thermal deformation or breakage of the configuration, thereby reducing the safety and reliability of the clothing device.

An object of the present invention is to provide a clothing device that effectively controls the hot air temperature to prevent overheating to improve safety and reliability.

In addition, an object of the present invention is to provide a clothing device that effectively controls the heater to minimize the increase in the hot air drying time to increase safety and user convenience.

An object of the present invention is to provide a safe garment apparatus by preventing the door glass located in front of the drum from overheating and rupturing.

An object of the present invention is to provide a garment apparatus for condensing by natural cooling without using a separate forced cooling means. That is, an object of the present invention is to provide a clothing device having a simple configuration by excluding a configuration of supplying a separate cooling water or supplying a cold wind for condensing moisture in the air. Alternatively, when condensing by a forced cooling method, it is possible to provide a clothes device with an improved condensation rate.

In order to solve the above object, in the present invention, the heater is turned on to start hot air drying, and the heater is turned off at a preset upper limit temperature T1 and the heater is turned on at a preset lower limit temperature Ta. A garment apparatus in which hot air drying is performed, wherein the predetermined upper limit temperature is raised after a predetermined time after the predetermined upper limit temperature T1 is first reached after the start of the hot air drying (T3). to provide.

Here, the raising of the upper limit temperature may be performed once, or may be performed in multiple stages. In addition, it is preferable that the upper limit temperature T3 raised after the multi-stage upward end is not changed until the end of hot air drying. This is because the control of the heater is preferably performed while maintaining the optimum upper limit temperature at the time when the drying is concentrated.

The upward may be made in three steps. This means that the upper limit temperature is divided into three sections.

Preferably, the upward timing t2 is changed according to a time t1 at which the predetermined upper limit temperature T1 is first reached after the start of drying the hot air. This upward timing means both the first upward timing and the next upward timing.

Preferably, the upward timing is set at the same ratio with respect to the time t1. In addition, the upper limit temperature (T1) is preferably set to 100 ℃ or more.

The predetermined lower limit temperature Ta may be raised together with the predetermined upper limit temperature T1. The lower limit temperature Ta may be set to less than 100 ° C., and the raised lower limit temperature Tb may be set to 100 ° C. or more.

In addition, it is preferable that the difference between the upper limit temperature T1 and the lower limit temperature Ta is equal to the difference between the upwardly elevated temperature T2 and the lower limit temperature Tb.

The clothing device preferably includes a hot air discharge port provided to supply hot air from the front of the drum to the inside of the drum. And a door having a door glass projecting into the drum to open and close the front opening of the drum.

The upper portion of the door glass may be inclined downward to guide the hot air discharged vertically from the hot air discharge port into the drum.

The position or shape of the hot air discharge port and the hot air discharged through the door glass may be substantially supplied into the drum.

Embodiments of the clothing device, the rotary shaft is connected to the drum in which the clothing is received; A bearing housing rotatably supporting the rotating shaft; A motor for rotating the rotating shaft; And it is connected to the bearing housing, it may comprise a suspension unit for cushioning the vibration of the drum.

Embodiment of the clothing device, the tub; A drum provided to accommodate clothes in the tub; A drive unit including a rotating shaft connected to the drum, a bearing housing rotatably supporting the rotating shaft, and a motor for rotating the rotating shaft; And it may include a flexible member formed to seal the rear portion of the tub to prevent leakage from the tub to the drive unit, the drive unit to move relative to the tub.

And, an embodiment of the clothing device, the tub; A drum provided to accommodate clothes in the tub; And a suspension unit for supporting the drum, wherein the tub may be rigidly supported than the drum is supported by the suspension unit.

In order to achieve the above object, the present invention also provides a clothing apparatus in which the heater is turned off at a predetermined upper limit temperature (T_u2) and the heater is turned on at a predetermined lower limit temperature (T_l2) so that hot air drying is performed. The heater may be turned on to provide a clothing apparatus, characterized in that the predetermined upper limit temperature and the lower limit temperature are lowered until a predetermined time elapses after the start of hot air drying.

And, the present invention, the drying duct provided with a heater; A drum through which hot air is introduced from the drying duct to dry clothes; A temperature sensor detecting a temperature of the heater or the heater; Clothing comprising a controller to turn on the heater to start hot air drying, to control the on / off of the heater in accordance with the temperature sensed by the temperature sensor, the upper limit temperature of the heater is turned off step by step A device can be provided.

Here, the upper limit temperature at which the heater is first turned off is set such that the maximum temperature measured at 100 ° C. or higher and on the path from the drying duct to the inside of the drum does not exceed 30% or more with respect to the upper limit temperature. This is preferred.

In addition, the time interval during which the step-up is performed is preferably set differently according to the time required for the first off after the heater is turned on.

According to an embodiment of the present invention, a drying duct provided with a heater; A drum through which hot air is introduced from the drying duct to dry clothes; A temperature sensor for sensing a temperature of the hot air; And controlling the on / off of the heater according to the temperature sensed by the temperature sensor to perform drying, changing the upper limit temperature at which the heater is turned off at the beginning of drying before the detected temperature reaches a normal state. Provided is a garment apparatus comprising a controller.

Here, it is preferable that the heater off temperature in the initial stage of drying is lower than the heater off temperature in the steady state.

According to the present invention, it is possible to provide a clothing device that effectively controls the hot air temperature to prevent overheating, thereby enhancing safety and reliability.

In addition, according to the present invention can effectively control the heater to minimize the increase in the hot air drying time can provide a clothing device that improves safety and user convenience.

According to the present invention, it is possible to prevent the door glass positioned in front of the drum from overheating and to rupture, thereby providing a safe garment apparatus.

According to the present invention, it is possible to provide a garment apparatus for condensing by natural cooling without using a separate forced cooling means. That is, it is possible to provide a clothing device having a simple configuration by eliminating the configuration of a separate cooling water supply or cold wind supply for condensing moisture in the air. And, when condensing by the forced cooling method, it is possible to provide a clothes device with improved condensation rate.

1 is a block diagram of a garment apparatus according to the present invention;
2 is a perspective view of a tub assembly of a garment apparatus according to an embodiment of the present invention;
3 is a perspective view of a garment apparatus according to an embodiment of the present invention;
4 is a sectional view of portion A of FIG. 2;
5 is an experimental graph to which the embodiment according to the present invention is applied;
6 is an experimental graph of a conventional clothing apparatus.

Hereinafter, with reference to the accompanying drawings will be described embodiments of the present invention;

Since the present invention relates to a garment apparatus having a drying function, it is not limited to a specific type of garment apparatus of the garment apparatus. Therefore, it is not limited to the drum type dryer or drum type washing-and-dryer mentioned later.

First, with reference to Figure 1 will be described in detail the configuration of the garment apparatus according to an embodiment of the present invention.

In order to dry, a heater 21 for heating air is provided. The heater is not controlled to be constantly on while the drying is performed. This is because the heater itself may be overheated, and the temperature of the heated hot air may be too high. Therefore, the on / off of the heater is preferably controlled appropriately.

In the state that the heater is off, the temperature of the air is lowered. However, in order to perform drying effectively, it is desirable that the temperature of the air be high. Therefore, the time period during which the heater is turned off needs to be appropriately set in consideration of overheating and cooling.

In consideration of the foregoing, it is preferable that the on / off of the heater is controlled according to the temperature. That is, the heater may be turned off at a preset upper limit temperature, and the heating of the heater at a preset lower limit temperature may be controlled to be repeated. Therefore, it is possible to indirectly control the time interval in which the heater is turned off.

By appropriately setting the predetermined upper limit temperature, overheating of the heater and hot air can be prevented, while overcooling can be prevented by appropriately setting the predetermined lower limit temperature. Thus, it is possible to shorten the drying time very effectively.

In order to heat the air through the heater, it is preferable that a fan 22 for generating a flow of air is provided.

In addition, the configuration is provided to form a space for accommodating the clothes, it is to dry the clothes through the air heated through the heater in the space. A configuration for forming such a space may be referred to as a drum 10.

The drum may be referred to as a drum in a general washing machine, or may be referred to as a clothing receiving unit inside a cabinet. In the case of a general washing machine, a motor (not shown) for rotating the drum will be provided. Thus, the drum is meant to include a clothes receiving portion in the cabinet type dryer.

The controller 30 may be provided to control the driving of the heater 21. Of course, the controller 30 may also control the driving of the fan 22 or the motor described above. That is, the controller 30 may perform the control necessary for the operation of the clothing device.

A variable for controlling the driving of the heater 21 in the controller 30 may be provided in various ways, but preferably includes a temperature variable. Therefore, it is preferable that a temperature sensor 23 is further provided to sense the temperature of the heater 21 or the temperature around the heater 21.

In addition, it is preferable to heat the air in a specific space in consideration of the thermal efficiency. Therefore, the drying duct 20 is preferably provided to provide a space for heating the air. Of course, the drying duct 20 may be provided with the above-described temperature sensor or fan 22 as well as the heater 21.

The drum 10 accommodates a drying object, that is, clothing containing moisture. Water boils at 100 ° C under normal conditions and absorbs large amounts of heat when evaporating from water to steam. Thus, as long as there is some water in the drum, it is very difficult for the temperature inside the drum to exceed 100 ° C.

Of course, even if the temperature of the air in the drum 10 does not reach 100 ° C evaporation occurs, at this time absorbs a large amount of heat. The amount of this evaporated water will naturally be higher as the temperature rises.

In the early stage of drying, that is, the amount of moisture evaporated in the early stage of drying the clothes through the hot air and the heater is continuously turned on, the temperature of the hot air continuously increases, and the temperature inside the drum also increases. However, when the temperature of the incoming hot air is about 100 ° C., the temperature inside the drum is varied between about 50 ° C. and 75 ° C.

Here, controlling the on / off of the heater ultimately raises the temperature inside the drum heated by the hot air to make it optimal for drying. The problem is that these heaters can be turned on and off properly to control the temperature inside the drum, but overheating can occur in other parts.

As shown in FIG. 1, hot air may flow into the drum from the drying duct 20. Then, the hot air heat exchanged in the drum 10 may be introduced into the drying duct 20 again. In this case, it can be said to be a type of drying in which air is circulated. On the other hand, the hot air heat exchanged in the drum 10 may be exhausted to the outside of the clothing apparatus, which may be referred to as an exhaust type drying. In the case of the exhaust type, the outside air flows into the drying duct 20.

In any case, the temperature of the air flowing into the drying duct 20 will be lower than the temperature of the air flowing out of the drying duct 20. In addition, there is little possibility that water may exist on a path through which hot air flows from the drying duct 20 to the drum (hereinafter referred to as a “drum inlet path” for convenience of description). Therefore, there is a fear that the temperature on the path is excessively increased compared to the temperature inside the drum. This may cause thermal damage, thermal deformation and damage due to overheating of the components, and high temperatures may be transmitted to the outside, causing damage to the user. Of course, it can prevent damage due to overheating to some extent through heat-resistant reinforcing material or insulation, but this only causes the price rise of the product and the complexity of the composition.

In particular, such overheating is likely to occur early in the hot air drying. This is because, at this time, the temperature of the hot air and the temperature inside the drum are constantly rising while the heater is continuously turned on.

In other words, the amount of heat introduced is greater on the drum inlet path than the amount of heat delivered to the surroundings. Therefore, the temperature on the drum inlet path is increased more than the heater 21 or the temperature around the heater (hereinafter referred to as "sensing temperature" for convenience of explanation). According to the experiments of the present inventors, it can be seen that the maximum temperature on the drum inlet path can be raised to 160 ° C. when the hot air drying initial sensing temperature reaches a predetermined upper limit temperature, for example, 106 ° C. Of course, the sensing temperature may vary depending on the position of the temperature sensor, that is, where the temperature is sensed.

This excessive rise in temperature can be said to play a large role in reducing the durability of the components on the drum inlet path. In particular, when the glass door glass is provided on the drum inlet path, the door class may be broken due to overheating.

In order to solve this problem, the predetermined upper limit temperature is preferably changed so as not to be constant throughout the hot air drying process. That is, it is preferable to change the predetermined upper limit temperature step by step in consideration of the temperature and drying time of the hot air.

Here, in order to perform drying with an optimal drying time, the predetermined upper limit temperature at the time when drying is most actively performed is very important. The most active drying is when the evaporation of water occurs most actively. Therefore, since the heat absorption by the evaporation is the most time, it is preferable to allow the most heat amount to be supplied into the drum at this time.

Therefore, if the whole process of hot air drying is divided into sections, the heater is turned on for the first time, and the time when the temperature rise and the water evaporation in the drum are expanded is increased by the initial drying, the period during which the water evaporation is most active, and the dry evaporation gradually decreases. It can be divided into terminal drying. Therefore, the above-described predetermined upper limit temperature is set so as to perform optimum drying in the medium term drying period. In consideration of this, the predetermined upper limit temperature may be set to 106 ° C. Of course, the temperature may correspond to the case of general drying for drying clothing resistant to heat, such as clothing made of cotton. Therefore, considering the nature of the clothes to be dried, the temperature may be set lower. After all, the predetermined upper limit temperature is preferably a set temperature in the middle stage drying, or a set temperature of the middle stage drying and the final stage drying. This is because there is a fear that overheating occurs due to the upper limit temperature in the initial drying as described above.

The heater control in the hot air drying process will be described in detail with reference to FIG. 5.

First, when the heater is turned on for the first time and hot air drying starts, the heater is turned off when the preset upper limit temperature is reached. Here, the predetermined upper limit temperature at which the heater is turned off for the first time after the start of hot air drying is preferably lower than the predetermined upper limit temperature in the above-described medium-term drying. The former predetermined upper limit temperature may be called T1 for convenience, and the latter predetermined upper limit temperature may be called T3. That is, it is preferable that T1 is preset to be lower than T3.

When the hot air drying elapses for a predetermined time t1 with the heater turned on, the heater is turned off. That is, the temperature of the hot air and the temperature inside the drum are continuously increased until the predetermined time t1. The predetermined time t1 will vary depending on the amount of clothes to be dried (amount of clothing) or the amount of moisture to be dried. That is, the greater the amount of water and the greater the amount of moisture, the more t1 will increase.

However, by setting the temperature of T1 lower than T3 as described above, it is possible to prevent the drum inlet temperature from rising too high. Detailed description thereof will be described later.

Meanwhile, the temperature for turning off the heater as well as the temperature for turning on the heater again after turning off the heater are important and this may be referred to as a predetermined lower limit temperature. The predetermined lower limit temperature is preferably set appropriately in order to prevent overcooling and in consideration of the sensing error of the temperature sensor in relation to the predetermined upper limit temperature.

The predetermined lower limit temperature may be constantly set constantly during the hot air drying process. Of course, it may vary according to the above-described preset upper limit temperature T1 or T3. In the latter case, when the preset upper limit temperature rises, it is preferable that the preset lower limit temperature also rises.

First, when the temperature reaches T1 and the heater is turned off for the first time, the temperature may be controlled to reach the preset lower limit temperature Ta so that the heater is turned on again. Thereafter, the heater may be controlled to be repeatedly turned on / off in a range of T1 and Ta for a predetermined time t2. The T1 may be changed to T3 and this may be referred to as a two step upward. This is because once set T1 is changed back to T3. In addition, T1 may be changed to T2, which is a higher temperature, and may be changed upward to T3 after a predetermined time t3 has elapsed. This can be referred to as three steps upward.

Here, the predetermined lower limit temperature corresponding to T2 may be referred to as Tb, and the predetermined lower limit temperature corresponding to T3 may be referred to as Tc. And it is preferable that T2 is higher than T1, and T3 becomes higher than T2. That is, the preset upper limit temperature is preferably set to be gradually raised. In addition, the preset lower limit temperature is preferably set to gradually increase.

To simplify this, the heater is controlled in the T1 / Ta range in one step for t2 hours, the heater is controlled in the T2 / Tb range in two steps for t3 hours, and the heater in the T3 / Tc range in three steps for t4 hours. Can be said to be controlled.

Although the time until the t1 time may be referred to as initial drying, the time at which the heater starts to be controlled by T3, that is, before the time t1 + t2 + t3 may be referred to as initial drying and the subsequent term may be referred to as medium drying.

Therefore, it is preferable that the predetermined upper limit temperature is increased by multiple steps until t4 before the middle stage drying, but it is preferable that the T3 is not changed after the middle stage drying. Of course, it is preferable that Tc is not changed. The T3 and Tc may not be changed until the hot air drying is completed.

On the other hand, as described above, the time t1 from the start of drying until reaching T1 is not constant. That depends on the amount of water and the amount of moisture. Therefore, it is preferable that the time points t2 and t3 set upward from T1 to T2 or T3 vary depending on the t1. For example, when t1 is 20 minutes, it is upward after 10 minutes, and when t1 is 26 minutes, it is preferable to be upward after 13 minutes. That is, t1 to t2 may control the on / off of the heater through T1 and Ta. After t2, on / off of the heater is controlled through T2 and Tb.After t3, e.g., t3 is 10 minutes when t1 is 20 minutes, t3 is 13 minutes when t1 is 26 minutes, and T3 and Tc The on / off of the heater can be controlled.

In other words, the uptime of the T1 depends on the t1, and when the upstream is performed in multiple stages, t2 and t3 may be set at the same ratio with respect to the t1. If the ratio is 0.5, t2 and t3 may be set equal to (t1) / 2, respectively. In addition, if the four-step upward is made in the same manner, if the time of (t1) / 3 elapses, T1 may be set to be upward.

In addition, it is preferable that the difference between T1 and Ta is not changed. In other words, it is preferable that the difference between T2 and Tb is the same as the difference between T3 and Tc. This is to prevent overcooling and to prevent malfunction due to the sensing temperature deviation of the temperature sensor.

The hot air drying described above may be a specific drying course. It may be a series of courses that are performed until the apparel device is started and stopped. It may also be a specific cycle of this series of courses. That is, as a cycle in which the heater is turned on for the first time and then terminated after the on / off is repeatedly controlled, such a hot air drying cycle may be performed a plurality of times to constitute one drying course. Therefore, as shown in FIG. 2, when the t4 time is finished, the hot air drying may be terminated, and only the fan may be driven for t5 time to supply the cold air. Therefore, the hot air drying can also be seen as narrowly meaning the time from when the heater is turned on until the on / off is performed according to the sensing temperature.

Hereinafter, with reference to Figure 2, the configuration of the garment apparatus according to an embodiment of the present invention will be described in detail.

As shown in FIG. 2, the clothing apparatus may include a drying duct 20 having a heater 21 and a drum 10 through which hot air is introduced from the drying duct 20 to dry clothes. have.

This embodiment may further comprise a tub 50 to perform the washing.

On the other hand, a controller (not shown, see FIG. 1 30) may be provided to control the temperature of the hot air or the temperature of the heater. Such a controller may be provided to control the operation of various components of the garment apparatus.

More specifically, the controller may be provided to control the on / off of the heater. In order to control the heater, it is preferable that a temperature sensor (see FIG. 1 23) for sensing a temperature is provided. The temperature sensor senses a temperature near the heater 21 or the heater, and this temperature may be referred to as a sensing temperature.

The controller preferably controls the heater 21 to be turned on to start hot air drying and controls the heater 21 according to the temperature (sensing temperature) detected by the temperature sensor. That is, the on / off of the heater 21 is controlled according to the sensing temperature.

It is preferable that the controller changes the upper limit temperature at which the heater is turned off, and the controller can raise it in stages.

As shown in FIG. 2, in the present embodiment, the condensation duct may be omitted, unlike a general dry garment apparatus. That is, the space between the tub 50 and the drum 10 can be used as a condensation space. This will be described in detail with reference to FIG. 3.

According to the garment apparatus shown in Fig. 3, the volume of the tub and the volume of the drum can be further increased for the same cabinet size than in the related art. Therefore, since the surface area of the tub can be further increased, natural cooling of the hot air can be satisfactorily achieved. In this case, the hot air supplied into the drum evaporates moisture in the drum, and condenses by dissipating heat to the tub surface in the space between the drum and the tub. The hot air condensed is discharged through the hot air outlet 51 shown in FIG. 2, and the hot air is introduced again into the drying duct 20. Of course, such circulation of air can be achieved by driving the fan 22.

For natural condensation, the rotational speed of the fan 22 can be further increased as compared with the conventional garment apparatus of the same standard. That is, it is possible to further increase the air volume and wind speed. If the heater capacity is the same, increasing the air flow rate or wind speed means that the heat exchange area per unit time is further increased. This is the same principle that clothes dry faster than in the case of windy weather in warm weather. Thus, the overall heat absorbing and dissipating action can be made more active.

Further increase in the air volume and the wind speed can be achieved by omitting the condensation duct. This is because the flow resistance of the condensation duct has a certain limit in increasing the air volume or the wind speed. Therefore, since it is possible to omit the axial duct and directly introduce the hot air from the tub to the drying duct, it is possible to further increase the air flow rate or wind speed through the fan. In this case, it is preferable that the cross-sectional area of the hot air outlet 51 is larger than the case of using a condensation duct.

In this embodiment, as shown in Figure 3, the rotating shaft connected to the drum, a bearing housing for rotatably supporting the rotating shaft, a drive unit including a motor for rotating the rotating shaft, and connected to the bearing housing to the vibration of the drum It may be made by including a suspension unit for cushioning.

In other words, unlike the conventional clothing device, the suspension unit does not support the tub, but directly absorbs the vibration of the drum through the bearing housing. Therefore, the vibration of the tub is minimized to further increase the volume of the tub. That is, the tub may be supported more rigidly than the drum is supported by the suspension unit.

In addition, the present embodiment may include a flexible member formed to seal the rear portion of the tub to prevent leakage from the tub to the drive unit, but to allow the drive unit to move relatively by the tub.

Due to the structural features of the tub, drum and suspension unit, natural condensation is possible in the space between the drum and the tub.

The configuration of the garment apparatus shown in FIG. 3 will be described in detail.

1 is a combined washing device having both a drying function and a washing function. In this embodiment, the condensation unit is a tub.

In the washing apparatus of the above embodiment, the tub is fixedly supported to the cabinet. The tub may include a tub front 100 constituting the front part and a tubblare 120 constituting the rear part.

The tub front 100 and the tubular 120 may be assembled by screws, and form a space in which the drum is accommodated. The tubular 120 has an opening at the rear side. The tubular 120 is connected to the rear gasket 250 that is a flexible member in the portion forming the opening. In addition, the rear gasket 250 may be connected to the tub back 130 at a radially inner portion. The tub back 130 has a through hole through which a rotating shaft passes. The rear gasket 250 is made so that the vibration of the tub back 130 can be flexibly deformed to the extent that the vibration of the tub back 130 is not transmitted to the tubular 120.

The rear gasket 250 is connected to the tub back 130 and the tubular 120 so as to be respectively sealed so that the wash water in the tub does not leak. The tubback 130 vibrates with the drum when the drum rotates, and is spaced apart from the tubular 120 at a sufficient interval so as not to interfere with the tubular 120. Since the rear gasket 250 may be flexibly deformed, the tubback 130 allows relative movement without interfering with the tubular 120. The back gasket 250 may have a curved or pleated portion 252 that may extend to a sufficient length to allow such relative movement of the tubback 130.

The tub has an entrance to its laundry at its front part. The front side of the tub with such an entrance to prevent the washing water outflow through the entrance, prevent the flow of laundry or foreign matter between the tub and the drum, or a front gasket 200 for other functions is to be installed Can be.

The drum may include a drum front 300, a drum center 320, a drum bag 340, and the like. In addition, a ball balancer may be installed at the front part and the rear part of the drum, respectively. The drum bag 340 is connected to the spider 350, the spider 350 is connected to the rotating shaft 351. The drum is rotated in the tub by the rotational force transmitted through the rotating shaft 351.

The rotating shaft 351 is connected to the motor through the tub back 130. In this embodiment, the motor is connected concentrically with the rotating shaft. That is, in this embodiment, the motor is directly connected to the rotating shaft. Specifically, the rotor of the motor and the rotation shaft 351 are directly connected. The bearing housing 400 is coupled to the rear surface 128 of the tub bag 130. In addition, the bearing housing 400 rotatably supports the rotation shaft 351 between the motor and the tub back 130.

The stator 80 is fixed to the bearing housing 400. The rotor is positioned around the stator 80. As described above, the rotor is directly connected to the rotation shaft 351. The motor is an outer rotor type motor that is directly connected to the rotating shaft 351.

The bearing housing 400 is supported from the cabinet base 600 through the suspension unit. The suspension unit may include a plurality of brackets connected to the bearing housing. The plurality of brackets may include radial brackets 430 and 431 connected to the bearing housing and extended in the radial direction, and axial brackets 440 and 450 extending in the front-rear direction or the rotation axis direction of the drum.

In addition, the suspension unit may include a plurality of suspensions connected to the plurality of brackets.

In this embodiment, the suspension may include three vertical suspensions 500, 510, and 520 and two inclined suspensions 530 and 540 that are inclined with respect to the front-rear direction. The suspension unit is not connected to the cabinet base 600 in a completely fixed manner, but is connected to allow some degree of elastic deformation to allow the drum to move forward and backward and to the left and right. That is, the suspension unit is elastically supported to allow rotation to some extent in the front and rear and left and right with respect to the support point connected to the base. The vertically installed suspension for such elastic support may be installed in the base 600 via a rubber bushing. The vertical installation of the suspension can be configured to elastically dampen the vibration of the drum and the tilted installation can be configured to damp the vibration. That is, in the vibration system including the spring and the damping means, the vertical installation may serve as a spring and the tilted installation may serve as a damping means.

The tub is fixedly installed in the cabinet, the vibration of the drum is buffered by the suspension unit. The tub may have its front and rear parts fixed to the cabinet. The tub may be seated and supported on the base of the cabinet, and furthermore, the tub may be fixed to the base.

Washing apparatus of the present embodiment may be said to be substantially separated from the support structure of the tub and the drum. In addition, the tub may be referred to as a washing machine of the structure does not vibrate even if the drum vibrates. Here, the vibration amount of the drum delivered to the tub may vary depending on the rear gasket.

In addition, in the washing apparatus of the present embodiment, since the vibration of the tub is remarkably small, the interval of the tub, which is maintained due to the vibration, is not required, so the outer surface of the tub may be located as close as possible to the cabinet. And this makes it possible to expand the size of the tub even if the size of the cabinet is not increased, and to increase the capacity of the washing apparatus in the size of the same appearance.

Substantially, the distance between the cabinet light 630 or the cabinet left 640 and the tub may be about 5 mm. In the conventional tub washing machine vibrating together was about 30mm at intervals so that the vibration of the tub does not interfere with the cabinet. If the diameter of the tub is considered, the diameter of the tub can be expanded by 50 mm more than in the conventional embodiment. This makes a significant difference to the extent that the capacity of the washing machine can be increased by one step at the same appearance size.

Although not shown, the washing apparatus may include a water supply valve connected to the water to supply the washing water to the tub. And, a detergent box for storing detergent may be installed.

The water supply valve may be connected through the detergent box and a hose. The detergent box may be connected through the tub and the hose. Thus, when washing is performed, the water supply valve operates to supply water from the tap water to the tub via the detergent box.

On the other hand, in this embodiment, it is preferable that substantially all the hot air discharged from the drying duct is supplied into the drum. This is because hot air flowing directly into the space between the tub and the drum may interfere with the above-described natural condensation. Therefore, as shown in FIG. 2, the hot air outlet 25 is preferably provided to supply hot air from the front of the drum 10 to the inside of the drum.

The hot air outlet 25 may be provided to pass through the gasket 40. Here, the gasket is configured to prevent the wash water from leaking out of the tub through the front opening of the drum 10. Therefore, the hot air outlet 25 is located in front of the front opening of the drum 10. And, in order to supply substantially all the hot air discharged into the drum, the hot air discharge port 25 is preferably provided to discharge the hot air vertically.

In many cases, the door that opens and closes the drum front opening includes a door glass (not shown). It is made of glass or reinforced plastics, so that the inside of the drum can be seen from the outside of the door. These door glasses protrude mostly towards the inside of the drum to perform the function of preventing the clothes from moving to the drum front opening. Details of the door and the door glass are self-explanatory, so detailed description thereof will be omitted.

In this embodiment, the upper portion of the door glass is preferably formed to be inclined downward to guide the hot air discharged vertically from the hot air discharge port 25 into the drum. Through the position of the hot air discharge port 25 and the shape of the door glass, all the hot air discharged substantially can be guided into the drum. This is because a portion of the door glass is located inside the drum more than the portion of the gasket 40 when the door is closed.

The shape and structural features of the drum inlet path further enhance the drying efficiency. However, there is a fear that overheating may occur on the drum inlet path as described above. In particular, overheating of the door glass may be a problem. In order to solve this problem, the above-described heater control may be further required.

Hereinafter, the overheat prevention effect will be described in detail with reference to FIGS. 4 to 6.

4 is a cross-sectional view of the portion A of FIG. 2. That is, the cross section of a particular portion on the drum inlet path. 5 is a temperature graph by the heater control described above, and FIG. 6 is a temperature graph by the heater control based on a single (unchanged) upper limit / lower limit temperature.

The present inventors carried out an experiment to measure the temperature in many parts as shown in Figure 4 to measure the degree of overheating on the drum inlet path during hot air drying. In addition, although not shown, the temperature was also measured at the top of the door glass. 5 and 6 show these measurement results.

First, FIG. 6 shows a temperature change in a state where T3 and Tc are set to be fixed in hot air drying. It can be seen that the temperature rises up to 160 ° C. on the drum inlet path as shown in FIG. 6. That is, it can be seen that the sensing temperature reaches T3, which is very overheated at a specific location on the drum inlet path when the heater is first turned off.

In the various positions HE01 to HE05 and TM_HE shown in FIG. 4, it can be seen that the more heat is directed from the right to the left, the more overheated. It is expected that this is because the wind speed or the air volume at various positions are changed due to the shape of the heater, the installation position, and the shape of the fan or the drying duct.

In addition, as shown in Figure 6, it can be seen that the temperature in the door glass rises up to about 120 ℃. Accordingly, it can be seen that overheating occurs in the drum inlet path including the door glass during the hot air drying, particularly in the early stage of hot air drying.

However, it can be seen that the maximum temperature on the drum inlet path can be lowered to approximately 130 ° C. by controlling the heater through T1 or T1 and T2 lower than T3 at the beginning of hot air drying as shown in FIG. 5. This indicates that overheating on the drum inlet path can be very effectively prevented without changing the optimal T3 / Tc in the drying period where drying is most active. That is, overheating can be prevented very effectively without maintaining drying efficiency and increasing drying time.

In particular, it can be seen that the maximum temperature in the door glass can be lowered to approximately 115 ° C. as shown in FIG. 5.

Through this, it is possible to provide a safer clothing device by lowering the thermal shock of the door glass. In addition, it is possible to perform drying more efficiently without wasting energy.

The present invention is not limited to the above-described embodiments, and those skilled in the art can make modifications without departing from the spirit of the present invention, and such modifications are within the scope of the present invention.

10 drum 20 drying duct
21: heater 22: fan
23: temperature sensor 30: controller

Claims (22)

In a clothing apparatus in which a heater is turned on and hot air drying starts, the heater is turned off at a predetermined upper limit temperature T1 and the heater is turned on at a predetermined lower limit temperature Ta, thereby performing hot air drying.
And a predetermined upper limit temperature is raised after a predetermined time after the predetermined upper limit temperature T1 is first reached after the start of drying the hot air (T3). The method of claim 1,
Apparel apparatus characterized in that the upper limit of the temperature is made in a multi-step. The method of claim 2,
The upper limit temperature T3, which is raised after the multi-step upward end, is not changed until the end of hot air drying. The method of claim 3, wherein
Apparatus characterized in that the up is made in three steps. The method of claim 1,
Apparatus according to claim 1, wherein the upward time point t2 is changed according to a time t1 at which the predetermined upper limit temperature T1 is first reached after the start of drying the hot air. The method of claim 5, wherein
And the upward time is set at the same ratio with respect to the time t1. The method of claim 1,
The upper limit temperature (T1) is a clothing device, characterized in that set to more than 100 ℃. The method according to any one of claims 1 to 7,
The predetermined lower limit temperature Ta is also raised together with the predetermined upper limit temperature T1. The method of claim 8,
The lower limit temperature (Ta) is set to less than 100 ℃, the lower limit temperature (Tb) is the garment apparatus characterized in that it is set to more than 100 ℃. The method of claim 8,
The difference between the upper limit temperature (T1) and the lower limit temperature (Ta) is a clothing device, characterized in that the same as the difference between the upward upward temperature (T2) and the lower limit temperature (Tb). The method of claim 1,
Apparatus comprising a hot air discharge port provided to supply hot air from the front of the drum to the inside of the drum. The method of claim 11,
And a door having a door glass projecting into the drum to open and close the front opening of the drum. The method of claim 12,
And an upper part of the door glass is inclined downward to guide the hot air discharged vertically from the hot air discharge port into the drum. The method according to any one of claims 11 to 13,
A rotating shaft connected to the drum in which the garment is accommodated;
A bearing housing rotatably supporting the rotating shaft;
A motor for rotating the rotating shaft; And
And a suspension unit connected to the bearing housing and configured to cushion vibration of the drum. The method according to any one of claims 11 to 13,
Tub;
A drum provided to accommodate clothes in the tub;
A drive unit including a rotating shaft connected to the drum, a bearing housing rotatably supporting the rotating shaft, and a motor for rotating the rotating shaft; And
And a flexible member formed to seal a rear portion of the tub so as to prevent leakage from the tub to the driving part, and to allow the driving part to move relative to the tub. The method according to any one of claims 11 to 13,
Tub;
A drum provided to accommodate clothes in the tub; And
And a suspension unit for supporting the drum, wherein the tub is rigidly supported than the drum is supported by the suspension unit. In the clothing device in which the hot air drying is performed by repeating the heater is turned off at a predetermined upper limit temperature (T_u2) and the heater is turned on at a predetermined lower limit temperature (T_l2),
And the predetermined upper limit temperature and the lower limit temperature are lowered until a predetermined time after the heater is turned on and the hot air drying starts. Drying duct provided with a heater;
A drum through which hot air is introduced from the drying duct to dry clothes;
A temperature sensor detecting a temperature of the heater or the heater;
Clothing comprising a controller to turn on the heater to start hot air drying, to control the on / off of the heater in accordance with the temperature sensed by the temperature sensor, the upper limit temperature of the heater is turned off step by step Device. The method of claim 18,
The upper limit temperature at which the heater is first turned off is set such that the maximum temperature measured at 100 ° C. or higher and on the path from the drying duct to the inside of the drum does not exceed 30% of the upper limit temperature. Clothing apparatus. The method of claim 18,
Apparatus according to claim 1, wherein the time interval at which the step-up is performed is set differently according to the time required for the first turn-off after the heater is turned on. Drying duct provided with a heater;
A drum through which hot air is introduced from the drying duct to dry clothes;
A temperature sensor for sensing a temperature of the hot air;
A controller for controlling the on / off of the heater according to the temperature detected by the temperature sensor to perform the drying, changing the upper limit temperature at which the heater is turned off at the beginning of drying before the detected temperature reaches a normal state Clothing device comprising a. The method of claim 21,
And the heater off temperature at the initial stage of drying is lower than the heater off temperature at the steady state.

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