KR20110001156U - Dehumidifier - Google Patents

Abstract

The present invention relates to a new type of small dehumidifier capable of accurately detecting the condensate level while preventing condensate from being scattered to the surroundings by improving the structure of sensing the condensate level.

To this end, the present invention forms an appearance, the body case is formed with an air inlet for the inlet of the air and an air outlet for the outlet of the dehumidified air, respectively; A dehumidifying unit provided in an upper space of the main body case to remove moisture from air introduced into the air inlet; A condensate storage container removably provided in a bottom space of the main body case and storing condensed water generated by a dehumidifying operation of the dehumidifying unit; And a water level detector configured to correspond to each component on an inner wall portion of a side portion of the condensate reservoir and an inner wall surface of the bottom space of the main body case to detect a level of condensate stored in the condensate reservoir. A small dehumidifier is provided.

Compact dehumidifiers, condensate reservoirs, water level detection

Description

Small dehumidifiers

The present invention relates to a small dehumidifier, and more specifically, to improve the structure of sensing the level of condensate generated by the dehumidification operation and collected in the condensate reservoir, the condensate is scattered to the surroundings while allowing accurate detection of the condensate level. The present invention relates to a new type of small dehumidifier which can prevent the phenomenon and can be used for personal use or portable to a local area.

In general, the dehumidifier is a device that removes moisture contained in the indoor air and supplies it back to the room.

The dehumidifier is configured to pass through a heat exchanger after sucking the air in the room so that the moisture contained in the sucked air can be separated, and the moisture separated from the air is collected in the condensate reservoir and discharged.

At this time, the condensate reservoir is built in a buoyancy body for sensing the high water level, and the detection switch for confirming whether the condensate reservoir is stored in the portion of the body case coupled to the condensate reservoir according to the operation of the buoyancy body Each sensing switch is provided to check whether the water level is full.

However, due to the characteristics of the dehumidifier, a large amount of water is present in the main body case, and various switches are connected to the coupling portion of the condensate reservoir when the condensate reservoir is combined with a large amount of moisture, such as the flow of condensate. It is undesirable to construct.

Furthermore, when various switches are provided at the site where the condensate reservoir is combined, the height of the overall product is increased and condensate flowing from the heat exchanger is scattered while falling into the condensate reservoir. It has a problem that it has no choice but to influence.

In particular, since the structure for checking the high water level of the condensate reservoir is configured to be able to check the high water level by a mechanical operation, such as a bleeding device and a detection switch operated by it, the compression force of the switch lever of the detection switch There is a problem that the reliability of the water level sensing is low, as the timing of detecting the full water level may be different depending on the resilience.

In addition, since the conventional general dehumidifier is a structure using a heat exchanger, not only the size of the overall product is large, but also the structure is complicated, and thus it is difficult to form a compact.

Of course, recently, a dehumidifier in which a thermoelectric module is applied instead of a heat exchanger, such as Korean Utility Model Publication No. 20-0341948, is provided. However, the conventional dehumidifier does not consider the flow direction of air and the flow direction of condensate. It has the disadvantage of not being made sufficiently.

The present invention is devised to solve the various problems according to the prior art described above, the object of the present invention is to enable accurate sensing of the condensate level in the condensate reservoir and to prevent errors in the level check, condensate The aim is to provide a new type of small dehumidifier that can be used for personal use or for local use as well as to prevent it from scattering around.

Small dehumidifier of the present invention for achieving the above object forms an appearance, the main body case each formed with an air inlet for the inlet of air and an air outlet for the outflow of the dehumidified air; A dehumidifying unit provided in an upper space of the main body case to remove moisture from air introduced into the air inlet; A condensate storage container removably provided in a bottom space of the main body case and storing condensed water generated by a dehumidifying operation of the dehumidifying unit; And a water level detector configured to correspond to each component on an inner wall portion of the bottom portion of the condensate reservoir and the bottom space of the main body case to sense the level of condensate stored in the condensate reservoir. .

Here, the water level detection unit and the support rod formed perpendicular to any one side in the condensate reservoir, and coupled to surround the support rod while rising and rising in accordance with the condensate level in the condensate reservoir, and a plotter with a magnet installed on the circumferential surface And a water level sensor provided on an inner wall surface of a portion of the bottom space of the main body case in which the condensate reservoir is installed and detecting proximity of the magnet installed in the plotter.

In addition, at least one of the magnet of the plotter constituting the water level sensor or the water level sensor is provided in plurality, characterized in that spaced apart from each other in the vertical direction of the plotter.

In addition, the dehumidifying unit is located on the front side of the blowing fan and the air blowing fan, and having a heat generating side wall surface and the heat absorbing side wall surface, respectively by the blowing fan to heat the air passing through the heat generating side wall surface dehumidification And a heat dissipation fin which is in close contact with the heat generating side wall surface and the heat absorbing side wall surface of the thermoelectric module.

In addition, the air inlet formed in the main body case is formed on any one of the circumferential wall surface of the main body case, the air outlet is formed on the upper surface of the main body case, the heat dissipation side wall surface of the thermoelectric module of the two heat dissipation fins The heat-dissipating fin that is in close contact is characterized in that the flow of air blown by the blowing fan is guided in the direction in which the air outlet is formed.

In addition, the bottom space and the corresponding condensate reservoir in the main body case is characterized in that it further comprises a storage detecting unit for confirming the storage of the condensate reservoir and providing a control signal to perform the dehumidification operation according to the storage or not. It is done.

In this case, the storage detecting unit is configured to include a magnet provided on any one side wall surface of the condensate reservoir, and a sensor provided at a position adjacent to the magnet when the condensate reservoir is stored in the bottom space of the main body case. It features.

As described above, the small dehumidifier according to the present invention can be miniaturized by using a thermoelectric module, so that personal use or portable use to a localized site can be performed.

In addition, the small dehumidifier according to the present invention can minimize the separation distance between the dehumidifying unit and the condensate reservoir by arranging the configuration for detecting the water level of the condensate so as to be a circumferential side portion of the condensate reservoir. The condensate flowing down the condensate has an effect that can be prevented from being scattered in the process of falling into the condensate reservoir, thereby preventing the surrounding electronic components from being damaged by the influence of moisture.

In particular, the small dehumidifier according to the present invention is composed of an electronic sensor, such as a magnet and a sensor for sensing the water level detection unit, has the effect of improving the reliability of the water level check and minimize the failure rate of the water level detection unit It has the effect of being able to.

Hereinafter, a preferred embodiment of the present invention will be described with reference to FIGS. 1 to 9.

As shown in FIG. 1, the small dehumidifier according to the preferred embodiment of the present invention includes a main body case 100, a dehumidifying unit 200, a condensate reservoir 300, and a water level detecting unit 400. do.

This will be described in more detail below for each configuration.

First, the main body case 100 is a part forming the appearance of a small dehumidifier according to an embodiment of the present invention, the air inlet 110 for the inflow of air and the air outlet 120 for outflow of the dehumidified air, respectively Is formed.

In this case, as shown in FIG. 1, the air inlet 110 is formed at an upper end of the front surface of the main body case 100, and the air outlet 120 is formed at an upper surface of the main body case 100.

In addition, the main body case 100 has a partition wall 130 for partitioning the upper space and the lower space is formed, the condensate outlet hole 131 for the discharge of condensate is formed in the partition wall 130 do.

Next, the dehumidifying unit 200 is a series of components for removing moisture from the air introduced through the air inlet 110, and is fixedly installed in the upper space of the main body case 100.

The embodiment of the present invention suggests that the dehumidifying unit 200 includes a blowing fan 210, a thermoelectric module 220, and a pair of heat dissipation fins 230 and 240.

In this case, the blower fan 210 is a series of components for blowing air, and is installed to be located in the rear space of the upper space in the main body case 100 as shown in FIGS. 1 and 2.

In addition, the thermoelectric module 220 is connected to the n-type and p-type thermoelectric semiconductor (pi) type so as to be electrically in series and thermally parallel, so that the It means a module having an inner side wall and an outer side wall to selectively endotherm or heat generation depending on the supply direction.

At this time, in the embodiment of the present invention, the inner wall of the inner wall and the outer wall of the thermoelectric module 220 facing the blowing fan 210 is set as the heat generating side wall surface, the outer wall which is the opposite wall surface to the heat absorbing side wall surface. It is configured to be set, and the two heat dissipation fins (230, 240) to each of the wall surface is presented to be fixed in close contact.

That is, moisture is removed from the air by heating the air passing through the heat dissipation fins (hereinafter referred to as “first heat dissipation fins”) 230 which are in close contact with the heat generating side wall of the thermoelectric module 220 by the blowing fan 210. In addition, the moisture thus removed is condensed on the heat dissipation fins (hereinafter, referred to as “second heat dissipation fins”) 240 closely fixed to the heat absorbing side wall surface of the thermoelectric module 220 and the second heat dissipation fins 240. Ride the surface of the will flow down.

The first heat dissipation fins 230 of the heat dissipation fins 230 and 240 serve to heat the air by receiving high temperature heat from the heat generating side wall of the thermoelectric module 220 and guide the flow of the air. As a configuration, a plurality of acids and valleys are formed along the outer surface, and the second heat dissipation fin 240 serves to condense the moisture removed from the air and at the same time induce the flow direction of the condensed water. As a configuration to play a role, a plurality of mountains and valleys are formed along the outer surface. This is as shown in Figure 1 attached.

At this time, the peaks and valleys of the first heat dissipation fin 230 are formed long in a vertical direction (up and down direction), so that the flow of air blown by the blowing fan 210 is guided to the upper direction in which the air outlet 120 is formed. It is configured to be.

Next, the condensate reservoir 300 is a series of components for receiving and storing the condensate flowed down from the second heat radiating fin (240).

The condensate reservoir 300 is provided detachably in the bottom space of the main body case 100, the condensate inlet 310 is formed through the upper surface.

At this time, the upper end of the condensate reservoir 300 is formed with a concave concave end 320 is formed in the bottom, the condensate inlet 310 is formed in the concave end (320).

Of course, the portion where the condensate outlet hole 131 is formed in the partition wall 130 of the main body case 100 may also be formed to correspond to the upper surface shape (shape of the concave end) of the condensate storage container 300. .

Next, the water level detection unit 400 is a series of components for detecting the level of the condensate stored in the condensate reservoir 300.

In the embodiment of the present invention, the water level detecting unit 400 is configured as an electronic sensor, and the water level detecting unit 400 is located at any one side portion of the main body case 100 as shown in FIGS. 2 and 3. Suggests positioning.

This is because the water level sensing structure using the mechanical switching structure as in the prior art is located on the upper portion of the condensate reservoir, the height of the overall product was high, in particular condensate because the distance between the condensate falling portion and the condensate reservoir is wide Since there is a problem of scattering generated while falling, the present invention is to solve the above problems by narrowing the gap between the condensate reservoir 300 and the second heat dissipation fin 240 as much as possible.

Water level detection unit 400 according to an embodiment of the present invention for this purpose is configured to include a support rod 410 and the plotter 420 and the water level detection sensor 430 as shown in Figs.

Here, the support rod 410 is formed perpendicular to the portion of the inner space of the condensate reservoir 300 adjacent to one side wall surface.

In addition, the plotter 420 is formed in the form of a ring through the inside is coupled to surround the support rod 410 is composed of a buoyancy body (elevating body) to move up and down in accordance with the condensate level in the condensate reservoir 300, A magnet 440 is installed on the circumferential surface of the plotter 420. At this time, the magnet 440 is formed in a ring shape is installed so as to completely surround the circumferential surface of the plotter 420, which is the floater 420 is lifted by the guide of the support rod in accordance with the change in the level of the condensate Even if it is rotated in the middle so that the distance between the magnet 440 and the water level sensor 430 is always maintained to ensure a smooth sensing.

In addition, the water level sensor 430 is provided on the inner wall surface of the portion where the condensate storage container 300 is installed in the bottom space of the main body case 100 is close to the magnet 440 installed in the plotter 420 It is a sensor configured to detect.

On the other hand, in the embodiment of the present invention suggests that the storage detecting unit 500 for confirming whether or not the storage of the condensate reservoir 300 is further included in the site where the water level sensor 430 is installed.

At this time, the storage detector 500 is configured to provide a signal so that dehumidification operation can be performed only when it is confirmed that the storage of the condensate reservoir has been made, may be configured as a proximity sensor such as a conventional optical sensor, The contact point is pressed by the storage of the condensate reservoir, it may be configured as a switch, as shown in the embodiment shown in Figures 3 to 6 attached to the magnet 510 on the outer wall surface of the condensate reservoir 300 In addition to the installation, the inner wall surface of the body case 100 corresponding thereto may be configured in various ways such as a sensor 520 for sensing the proximity of the magnet 510.

In the following, the operation of the small dehumidifier according to the preferred embodiment of the present invention described above will be described with reference to FIGS. 4 to 6.

First, when the operation of performing the dehumidification operation by the user's selection is generated, it is checked by the storage detector 500 whether the condensate storage container 300 is stored.

If the condensate reservoir 300 is not received, the operation of the blower fan 210 for dehumidification operation is not performed and the operation of the thermoelectric module 220 constituting the dehumidifying unit 200 is performed. You won't lose.

On the other hand, if it is confirmed that the storage of the condensate reservoir 300 is made as shown in Figures 4 to 6 attached to the thermoelectric constituting the dehumidifying unit 200 and the blowing fan 210 for the dehumidification operation is driven As power is supplied to the module 220, hot heat is emitted through the heat generating side wall of the thermoelectric module 220, and heat is absorbed from the surrounding air through the heat absorbing side wall of the thermoelectric module 220. .

Therefore, the air in the room is introduced into the upper space in the body case 100 through the air inlet 110 of the body case 100 by the blowing force driven by the blower fan 210 and the thermoelectric module. Heat exchanged with the first heat dissipation fin 230 provided on the heat generating side wall of the 220 while receiving the guidance of the flow by the first heat dissipation fin 230 through the air outlet 120 formed on the upper surface of the body case 100 Is discharged.

Here, the air introduced into the main body case 100 through the air inlet 110 contains a large amount of moisture, and the moisture is separated from the air by heat exchange with the first heat dissipation fin 230. In addition, a state condensed on the surface of the second heat dissipation fin 240 is achieved.

In this case, since the second heat radiation fin 240 is deprived of heat to the heat absorbing side wall surface of the thermoelectric module 220 by the operation of the thermoelectric module 220, the second heat radiation fin 240 is substantially at a low temperature. Water separated from the air is condensed on the surface of the two heat radiation fins 240.

Then, the water condensed on the surface of the second heat dissipation fin 240 as described above flows down the surface of the second heat dissipation fin 240, the condensed water outlet hole 131 formed in the partition wall 130 of the body case 100 ) And sequentially pass through the condensate inlet 310 formed on the upper surface of the condensate reservoir 3300 is collected in the condensate reservoir 300.

At this time, the condensate flowing through the condensate outlet hole 131 to the upper surface of the condensate reservoir 300 is guided by the concave end 320 formed in the upper surface of the condensate reservoir 300 is the condensate inlet 310 Flows to the outside, preventing dripping to the surroundings.

In particular, the condensed water passing through the condensed water outlet hole 131 formed in the partition wall 130 is located between the partition wall 130 of the main body case 100 and the upper surface of the condensate storage container 300 in close proximity. During the fall to the concave end 320 formed on the upper surface of the reservoir 300 is scattered or flows down around the condensate reservoir 300 is prevented, and falls accurately into the concave end (320).

As the above-described process is repeated, the condensate level in the condensate reservoir 300 is gradually raised. At this time, the plotter 420 constituting the water level detector 400 is supported as the condensate level rises. It is gradually raised while being supported by the rod 410.

In addition, at this time, whether or not the proximity of the magnet 440 installed on the circumferential surface of the plotter 420 by the water level sensor 430 is made continuously, if the proximity of the magnet 440 as shown in FIG. If it is confirmed that the condensate water level has reached the full water level will stop the operation of the dehumidification operation.

On the other hand, Figures 7 to 9 attached to the operation state of the water level detection unit of the small dehumidifier according to another embodiment of the present invention.

That is, in another embodiment of the present invention, it is shown that the magnet and the water level sensor constituting the water level detection unit may be provided as a plurality of magnets 441 and 442 and a plurality of water level sensors 431 and 432, respectively. will be.

As such, when the magnets 441 and 442 and the water level detection sensors 431 and 432 are configured in plural numbers (for example, two by two), the water level for the condensate in the condensate reservoir 300 may be more accurately detected.

That is, when only the water level sensor 432 located at the lower side of the two water level sensors 431 and 432 as shown in FIG. 7 detects the proximity to the at least one or more magnets 441 and 442, the condensate storage of the condensate reservoir 300 is stored. As shown in FIG. 8, when both the water level sensors 431 and 432 sense the proximity of each of the magnets 441 and 442, the condensate storage space in the condensate reservoir 300 reaches the full water level. As shown in FIG. 9, when only the water level sensor 431 located at the upper side of the two water level sensors 431 and 432 detects the proximity of the at least one magnet 441 and 442, the condensed water in the condensate reservoir 300 You can see that it is full water.

Therefore, in the state as shown in FIG. 8, a warning is performed (eg, blinking of a warning lamp) to guide condensate discharge in the condensate reservoir 300, and in the case of FIG. 9, the dehumidification operation is stopped to overflow the condensate. It is desirable to be controlled so that it can be prevented.

Of course, although not shown, any one of the water level sensor 430 and the magnet 440 may be configured in plural. For example, only a plurality of water level sensors may be configured.

1 is a side perspective view showing a part of the cross-sectional view for explaining the internal structure of a small dehumidifier according to a preferred embodiment of the present invention

Figure 2 is a rear perspective view showing a part of the cross-sectional view for explaining the internal structure of the small dehumidifier according to a preferred embodiment of the present invention

Figure 3 is a front sectional view showing the internal structure of the small dehumidifier according to a preferred embodiment of the present invention

4 to 6 is a cross-sectional view showing the main part for explaining the operating state of the water level detection unit of the small dehumidifier according to a preferred embodiment of the present invention

7 to 9 is a cross-sectional view showing the main part for explaining the operating state of the water level detection unit of the small dehumidifier according to another embodiment of the present invention

Explanation of symbols for main parts of the drawings

100. Main unit case 110. Air inlet

120. Air outlet 130. Partition wall

131. Condensate outlet 200. Dehumidifier

210. Blower fan 220. Thermoelectric module

230. First heat sink fin 240. Second heat sink fin

300. Condensate reservoir 310. Condensate inlet

320. Urine 400. Water level detector

410. Support Rod 420. Plotter

440. Magnet 430. Water level sensor

500. Storage detector

Claims (7)

A main body case having an appearance and having an air inlet for inflow of air and an air outlet for outflow of dehumidified air; A dehumidifying unit provided in an upper space of the main body case to remove moisture from air introduced into the air inlet; A condensate storage container removably provided in a bottom space of the main body case and storing condensed water generated by a dehumidifying operation of the dehumidifying unit; And, Small dehumidifier comprising: a water level detector for detecting the water level of the condensate stored in the condensate reservoir is installed so that each component corresponding to the inner wall portion of the side portion of the condensate reservoir and the bottom space of the body case . The method of claim 1, The water level detection unit A support rod vertically formed on one side of the condensate reservoir, A floater coupled to surround the support rod and a magnet installed on a circumferential surface of the condensate while being elevated according to the condensate level in the condensate reservoir; Small dehumidifier comprising a water level sensor for detecting the proximity of the magnet installed in the plotter while being provided on the inner wall surface of the portion of the bottom space of the main body case in which the condensate reservoir is installed. The method of claim 2, Miniature dehumidifier, characterized in that the magnet of the plotter constituting the water level detection unit, or at least one of the water level detection sensor is provided in plurality, spaced apart from each other in the vertical direction of the plotter. The method of claim 1, The dehumidifying unit Blower fan to blow air, A thermoelectric module positioned at the front side of the blower fan and having a heat generating side wall and an endothermic side wall, respectively, and operated by the blower fan to heat and dehumidify air passing through the heat generating side wall; Small dehumidifier characterized in that it comprises two heat radiation fins in close contact with each of the heat generating side wall and the heat absorbing side wall surface of the thermoelectric module. The method of claim 4, wherein The air inlet formed in the main body case is formed on any one of the peripheral wall surface of the main body case, the air outlet is formed on the upper surface of the main body case, The heat dissipation fin of the two heat dissipation fins in close contact with the heat generating side wall of the thermoelectric module is formed so that the flow of air blown by the blowing fan is guided in the direction in which the air outlet is formed. The method of claim 1, The bottom space of the main body case and the condensate reservoir corresponding thereto further include an accommodating detector configured to check whether the condensate reservoir is accommodated and to provide a control signal to perform a dehumidification operation according to the storage. Mini Dehumidifier. The method of claim 6, The storage detector A magnet provided on one side wall of the condensate reservoir; And a sensing sensor provided at a position adjacent to the magnet when the condensate reservoir is accommodated in the bottom space of the main body case.

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