KR101487053B1 - Dehumidifying Rotor having air conditioning ability and Method of manufacturing the Dehumidifying Rotor - Google Patents

Abstract

The present invention relates to a dehumidification rotor having an air cleaning function and a method for manufacturing the dehumidification rotor. The dehumidifying rotor has a shape of a disk and is rotatably installed in a dehumidifying device and has a dehumidifying material therein. The dehumidifying rotor rotates the dehumidifying device through the dehumidifying device, The rotor is equipped with a catalyst for adsorbing and decomposing contaminants in a humidifier passing through a dehumidifying rotor.
The dehumidification rotor of the present invention having the above-described air cleaning function of the present invention performs not only the dehumidification function but also various harmful substances such as nitrogen oxides, volatile organic compounds (VOCs) or pathogenic bacteria and fungi in the air, It is possible to simultaneously perform humidity control and air cleaning.

Description

[0001] The present invention relates to a dehumidifying rotor having an air cleaning function and a method for manufacturing the dehumidifying rotor,

The present invention relates to a dehumidification rotor having an air cleaning function and a method of manufacturing the dehumidification rotor.

Dehumidifiers used in homes and offices are usually adsorbed. This has the principle of removing the moisture contained in the room air by utilizing the moisture absorption and moisture-proof action of the dehumidification rotor to which the desiccant is applied. This type of dehumidifying device is also referred to as a dehumidifying rotor type dehumidifier.

Fig. 1 shows the structure of a general dehumidification rotor type dehumidifying device 11 equipped with the dehumidification rotor.

The dehumidification rotor 17 is in the form of a disk, but since the dehumidification rotor 1 has a side view, the dehumidification rotor 17 is indicated by a rectangle.

As shown in the drawing, the conventional dehumidifying device 11 includes a dehumidifying rotor 17 that takes the form of a disk rotatable about a rotating shaft 18 and rotates by being connected to a motor 21 by a belt 21, A heating air supply unit 12 for supplying the regeneration air heated by the regeneration unit 25 which is a part of the dehumidification rotor 17 and a humidification unit 18 for humidifying the room through the adsorption unit 23, (Not shown). The humidifier supply unit (26) includes a humidifier blower (27).

The regeneration section 25 and the adsorption section 23 do not mean the mutually separated areas of the dehumidification rotor 17 but the part facing the heating air supply section 12 during the rotation of the dehumidification rotor 17 Is the regeneration section (25), and the portion facing the humidifier supply section (26) is the adsorption section (23). Thus, for example, any one point of the dehumidification rotor 17 is the regeneration section 25 and the adsorption section 23 according to the rotation of the dehumidification rotor 17. [

Reference numeral 29 denotes an aftercooler. The aftercooler 29 passes through the adsorption unit 23 and lowers the temperature of the dried air to a desired level. The air having passed through the aftercooler 29 is supplied to the room through the dry air blower 31.

On the other hand, the heated air supply unit 12 is composed of a regeneration air blower 13 and a heater 15. [ The heating air supply unit 12 serves to pass the air that has passed through the regeneration air blower 13 through the regeneration unit 25 while being heated by the heater 15. [ The heated gun air is dried by damping moisture raised in the regeneration section 25 in a state of adsorbing the moisture of the humidifier (in accordance with the rotation of the dehumidification rotor). As a result, the desiccant inside the dehumidification rotor desiccant is returned to the region of the adsorption section 23 in a dried state, and adsorption is performed. As the dehumidifying agent, silica gel or zeolite may be used.

For reference, the dehumidifying agent has a high affinity for water vapor and can absorb water vapor of about 20% or more of the dry weight.

The heated air that has passed through the regeneration unit 25 passes moisture through the condenser (not shown) in a damp state, transfers moisture to the condenser through heat exchange with the outside air, and returns to the heated air supply unit 12 as regeneration air .

2, 3, 4 and 5 are diagrams for explaining the problems of the conventional dehumidifying rotor 17 used in the dehumidifier.

First, the dehumidification rotor 17 of the type shown in Figs. 2 and 3 includes a dehumidification rotor body 33 having a disk shape having a predetermined thickness and a through hole 33e formed at the center thereof, And casings 35a and 35b for accommodating the main body 33. The dehumidification rotor main body 33 is formed by winding an inorganic fiber after being formed into a corrugated shape and includes a rotor body 33b for providing a flow space 33d as an air passage and a rotor body 33b coated on the inward faces of the respective flow spaces 33d And a moisture absorption layer 33c.

The moisture absorption layer 33c is a portion coated with an inorganic dehumidifying agent such as silica gel or zeolite.

However, since the contact area between the humidifier and the moisture absorption layer 33c is small, the dehumidification efficiency of the dehumidification rotor 17 does not rise more than any other one, although the flow resistance of the air is low because the inside of the flow space 33d is almost empty. There was a problem. In particular, when the dehumidifying unit 33c is used for a long time due to the use of the dehumidifying unit, the moisture absorption efficiency is further lowered.

Figs. 4 and 5 are views showing other types of dehumidification rotors 17. Fig.

The dehumidification rotor 17 includes a dehumidification rotor main body 37 which takes the form of a wagon wheel and accommodates therein a moisture absorption material 39 in the form of granules, And a screen sheet 41 covering both side surfaces.

The dehumidification rotor main body 37 has a plurality of partition walls 37a extending in the radial direction, one end of which is fixed to a shaft hole 37c through which the rotary shaft 18 passes. The space between the partition walls 37a accommodates the moisture absorbent material 39 as a fluid space 37b through which air passes. The moisture absorbent material (39) absorbs moisture in the air passing through the flow space while filling the flow space (37b).

4 and 5, the amount of the moisture absorbing material 39 filled in one space is large because the volume of each of the fluid spaces 37b is large. Therefore, in the dehumidifying rotor 17 of the system shown in Figs. 4 and 5, There is a problem that it is broken or worn and can sink downward by gravity. When the moisture absorber 39 sinks downward, the air passing through the flow space 37b can not meet the moisture absorber and passes through, and the moisture removing efficiency remarkably drops. In addition, a noise phenomenon may occur due to the collision of the moisture absorptive material 39 with air during use.

In addition, the conventional dehumidification rotor 17 has merely a hygroscopic function, and has a drawback that it can not perform other functions such as air purification.

The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a method of adsorbing a low-temperature decomposition catalyst to an adsorbent, And to provide a dehumidification rotor having an air cleaning function capable of removing air, and a method of manufacturing the dehumidification rotor.

In order to achieve the above object, a dehumidifying rotor having an air cleaning function according to the present invention takes the form of a disk, is rotatably installed in a dehumidifying device, and has a dehumidifying material therein. The desiccant rotor is characterized in that a catalyst for adsorbing and decomposing contaminants in a humidifier passing through the dehumidifying rotor is provided in the dehumidifying rotor.

The dehumidifying apparatus may further include a humidifier supply unit for humidifying the humidifier through a part of the dehumidifying rotor and a heated air supply unit for passing the heated air through the remaining area of the humidifying rotor to dry the dehumidifying rotor, Is a low-temperature decomposition catalyst which uses heat of heated air passing through the dehumidification rotor by the heated air supply unit as catalyst reaction energy.

The dehumidifying material and the catalyst are coated on the surface of the dehumidifying rotor through which the air passes while being bound in a certain ratio.

In addition, the catalyst is a Pd / Mn / beta-zeoite catalyst and the dehumidifying material is zeolite or silica gel.

According to another aspect of the present invention, there is provided a method for manufacturing a dehumidification rotor, comprising: binding a catalyst and a dehumidifying agent to remove a contaminant in the air to obtain a catalyst and a dehumidifying agent mixture; Impregnating the inorganic fiber paper with the mixture obtained through the binding step; And a forming step of making the fiber paper after the impregnation step is formed into a corrugated cardboard sheet and wound up to form a disc-shaped honeycomb structured body.

The method may further include a heating step of applying heat to the fiber paper after the impregnation step is completed to fix the mixture to the fiber paper.

Further, the catalyst is a low-temperature decomposition catalyst that uses heat of heated air passing through the dehumidification rotor as catalyst reaction energy.

The dehumidification rotor of the present invention having the above-described air cleaning function of the present invention performs not only the dehumidification function but also various harmful substances such as nitrogen oxides, volatile organic compounds (VOCs) or pathogenic bacteria and fungi in the air, It is possible to simultaneously perform humidity control and air cleaning.

Fig. 1 is a configuration diagram showing a general dehumidifying device having a dehumidifying rotor.
FIGS. 2 to 5 are views for explaining the problems of the conventional dehumidification rotor.
6 is an exploded perspective view illustrating a structure of a dehumidifying rotor according to an embodiment of the present invention.
7 is a block diagram showing a method of manufacturing a dehumidification rotor according to an embodiment of the present invention.

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

6 is an exploded perspective view illustrating a structure of a dehumidifying rotor according to an embodiment of the present invention.

The same reference numerals as those of the above-mentioned reference numerals indicate the same members having the same function.

As shown in the drawing, the dehumidification rotor 43 according to the present embodiment has a disk of a certain thickness as a whole, passes through the air in the thickness direction thereof, A main body 43a and casings 35a and 35b covering the dehumidification rotor main body 43a.

The dehumidifying rotor main body 43 has a honeycomb inner structure in the form of a disk having a predetermined thickness. The dehumidifying rotor main body 43 has a rotor body 33b, which is produced by winding the inorganic fiber paper into a single- And a dehumidifying and air-cleaning layer 45 coated on the rotor body 33b to a predetermined thickness.

The dehumidification rotor main body 43 is obtained by consolidating a mixture prepared in advance on an inorganic fiber paper and winding it in a wave form by using a known wave forming device. A corrugated apparatus or a corrugating apparatus for corrugating an inorganic fiber paper having a certain thickness is a general one.

Particularly, the mixture is a dehumidifying and air-clarifying layer 45 produced by binding a catalyst and a dehumidifying agent for removing contaminants in the air, and forms a coating layer having a predetermined thickness on the surface of the rotor body 33b.

The dehumidifying and air-cleaning layer 45 is exposed to the flow space 33d provided by the rotor body 33b and reacted by the heated air passing through the flow space 33d. That is, the dehumidifying material in the dehumidifying and air-cleaning layer 45 removes the moisture in the air, and the catalyst reacts with the heat of the heated air to decompose contaminants in the air.

The coating thickness of the dehumidifying and air-cleaning layer 45 may vary depending on the capacity of the dehumidifying rotor 43, and may be, for example, about 5 mm.

Thus, since the dehumidifying and air-cleaning layer 45 is coated on the rotor body 33b to a predetermined thickness, it is possible to remove the contaminants in the air without increasing the flow resistance of the air and without involving a structural change There is.

As described above, the dehumidifying and air-clarifying layer 45 is a mixture of a dehumidifying agent and a low-temperature decomposition catalyst. The low-temperature decomposition catalyst is in contact with air passing through the flow space 33d, and adsorbs and decomposes contaminants in the air.

The low temperature decomposition catalyst of the present invention preferably comprises a metal or transition metal having low activation energy and good oxidation ability for low temperature decomposition. As the low-temperature decomposition catalyst, a noble metal catalyst may be used. For example, Pd / Mn / beta-zeoite having a catalytic reaction temperature of 40 to 90 ° C may be used.

Pd may be replaced with any one of Pt, Au and Rh, Mn may be replaced with any one of Cu, Fe and Ce, and b-zeolite may be replaced with TiO ₂ , SiO ₂ Or the like.

Although the casings 35a and 35b described above are used to cover the dehumidification rotor 43 of the present embodiment, it is also possible to use a different type of the casing 35a or 35b than the casings 35a and 35b as long as the dehumidification rotor 43 is rotatably accommodated. Casing can be applied.

7 is a block diagram showing a method of manufacturing a dehumidification rotor according to an embodiment of the present invention.

As shown in the drawing, the method of manufacturing the dehumidification rotor according to the present embodiment includes a binding step (S100), an impregnation step (S102), a heating step (S104), and a molding step (106).

The binding step (S100) is a step of binding the dehumidifying agent and the low-temperature decomposition catalyst to form the object to be coated with the dehumidifying and air-cleaning layer (45). The ratio of the dehumidifying agent to the low-temperature decomposition catalyst in the binding step (S100) differs depending on the purpose. For example, if more desorption is desired, the mixing ratio of the desiccant should be increased, and if the removal of pollutants is more important than dehumidification, the proportion of the low temperature decomposition catalyst should be increased.

The impregnating step (S102) subsequent to the binding step (S100) is a step of impregnating the prepared inorganic fiber paper after mixing the low temperature decomposition catalyst and the inorganic binder. At this time, the low-temperature decomposition catalyst is mixed with an inorganic binder of 10 wt% to 20 wt% based on the solids content of the low-temperature decomposition catalyst, and the concentration of the total impregnation solution is 3 wt% to 5 wt%. Alumina sol and silica sol are used as the inorganic binder used in the impregnation step.

5 g of the catalyst, 10% by weight of the binder relative to the catalyst, 30% by weight of the binder solution was used, the concentration of the whole impregnating solution was adjusted to 5% by weight, ≪ / RTI > The binder solids content is 5 g x 0.1 = 0.5 g and the binder solution concentration is 30%, so 1.67 g (= 0.5 / (30/100)) of the binder solution is required for 0.5 g of binder solid content, 5 g of the catalyst and 0.5 g of the binder were used in total. For the impregnation solution concentration of 5%, the solid content of 5.5 g was added with water to make the total weight 110 g (= 5.5 g / 5%), And the impregnation solution is impregnated with an inorganic fiber paper.

After the impregnation step (S102) is completed, a heating step (S104) is performed in which heat is applied to the inorganic fiber paper to fix the coating layer impregnated in the inorganic fiber paper in place. The dehumidifying and air-cleaning layer 45 is formed in the rotor body 33b through the heating step S104.

After the heating step (S104), the forming step (S106) is performed. In the forming step S106, the inorganic fiber paper, on which the dehumidifying and air-cleaning layer 45 is completely fixed, is formed into a wave form and then taken up to produce a disk-shaped rotor body 33b.

The dehumidification rotor body 43a is formed through the molding step S106 and all the steps are completed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: Dehumidifying device 12: Heating air supply part
13: regeneration air blower 15: heater
17: dehumidification rotor 18: rotating shaft
19: motor 21: belt
23: suction part 25: regeneration part
26: humidifier supply unit 27: humidifier blower
29: Aftercooler 31: Gun air blower
33: dehumidification rotor body 33b: rotor body
33c: moisture absorption layer 33d:
33e: through holes 35a, 35b: casing
37: dehumidification rotor body 43: dehumidification rotor
43a: dehumidification rotor body 45: dehumidification and air purification layer

Claims (10)

delete delete delete delete delete delete delete A binding step of binding a catalyst and a desiccant to remove contaminants in the air to obtain a catalyst and a desiccant mixture;
Impregnating the inorganic fiber paper with the mixture obtained through the binding step;
A heating step of applying heat to the fiber paper to fix the mixture to the fiber paper after the impregnation step is completed; And
Forming a corrugated fiber paper having the impregnated fiber paper into a corrugated fiberboard, and winding the corrugated cardboard sheet into a honeycomb structure. delete 9. The method of claim 8,
Wherein the catalyst is a low-temperature decomposition catalyst that uses heat of heated air passing through the dehumidification rotor as catalyst reaction energy.

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