KR101511371B1 - Air conditioning system and method using oyster shell - Google Patents

Abstract

The present invention relates to an air conditioning system and method using oyster shell, and are provided to use the byproducts of fishes to purify the air in an economically friendly and efficient way; to silently purify the air without using a compressor or a refrigerant; to simplify the equipment structure; to reduce the costs for installation, maintenance, and operation; and to purify the air in an economical way, by comprising: an air conditioning path comprising an air outlet connected with one side of an indoor space, an air inlet connected with the other side of the indoor space, and a flow path connected from the air outlet to the air inlet; and at least one dehumidifying unit placed inside the flow path which removes steam in the air flowing from the air outlet to the air inlet, and the dehumidifying unit comprising a moisture absorbing unit placed crossing the inside of the flow path comprising oyster shell powders which absorbs steam in the air; and a heat absorbing unit contacting one side of the moisture absorbing unit which removes the heat of adsorption of the moisture absorbing unit.

Description

Technical Field [0001] The present invention relates to an air conditioning system and an air conditioning system using oyster shells,

The present invention relates to an air conditioning system and an air conditioning method using oyster shells, and more particularly, to an air conditioning system and an air conditioning method for adsorbing water vapor in the atmosphere using oyster shells.

The air conditioner, that is, the air conditioner performs functions of adjusting the temperature, humidity, air flow, and air cleanliness of the air to suit the purpose of use of the air in a specific area.

Especially in the indoor environment, the humidity of the inside air is important. When the humidity in the air is high, it causes decay and corrosion and odor and bacteria are generated. Therefore, the interior space where electricity, communication and various electronic equipments A device for removing such moisture is required. Conversely, if the humidity is too low to dry the room, the body's immunity can be reduced to cause colds, rhinitis, and allergies.

A common air conditioning system is dehumidified through a rotary rotor carrying a moisture adsorbent such as silica gel or zeolite.

On the other hand, the oyster shell is a oyster shell, which is a dispersion produced in oyster cultivation, and its main component is calcium carbonate (CaCO ₃ ). Oyster shells are used in various industrial fields such as various fertilizer in agriculture field and construction materials in construction field. In the field of construction, oyster shells can be used as solidifying agents, which is based on the adsorption properties of oyster shells. There is a need to study the use of the adsorption property of oyster shells in air conditioners.

One aspect of the present invention is to provide an air conditioning system and an air conditioning method that are eco-friendly and efficient by recycling fishery byproducts, and are easy to operate equipment.

Another aspect of the present invention is to provide an air conditioning system and an air conditioning method which are quiet, vibration-free, and simple in construction, because they do not require a compressor or a refrigerant using a thermoelectric element.

An air conditioning system according to the present invention is an air conditioning system for purifying air in an indoor space, comprising an air outlet connected to one side of the indoor space and an air inlet connected to the other side of the indoor space, An air conditioning furnace; And at least one dehumidifying unit disposed in the flow passage and removing water vapor in the air flowing from the air outlet to the air inlet. Here, the dehumidifying unit is disposed across the inside of the flow path, and includes a moisture absorbing portion including oyster shell powder that absorbs water vapor in the air; And a heat absorbing portion contacting the one side of the moisture absorbing portion to remove the heat of adsorption of the moisture absorbing portion.

In the air conditioning system according to the present invention, the air conditioning system may further include a heat exchange unit disposed inside the flow path and performing heat and cooling the air flowing from the air outlet to the air inlet.

In the air conditioning system according to the present invention, the heat absorbing portion and the heat exchanging portion may include a thermoelectric element having a Peltier effect.

In the air conditioning system according to the present invention, the heat absorbing unit and the heat exchanging unit may be powered by the solar power supply unit.

In the air conditioning system according to the present invention, there is further provided an exhaust blowing fan disposed at an air outlet and allowing air in the indoor space to flow into the flow passage, and an inflow blowing fan disposed in the air inlet, .

In the air conditioning system according to the present invention, the air outlet may be formed at the lower end of the indoor space, and the air inlet may be formed at the upper end of the indoor space.

In the air conditioning system according to the present invention, the flow path may include a path formed by bending at least once.

In the air conditioning system according to the present invention, the air purifying path may further include a baffle in which a plurality of shielding plates are staggered in the flow path so that air in the flow path meanders.

In the air conditioning system according to the present invention, the dehumidifying unit may further include a dehumidifying unit blowing fan disposed in front of the moisture absorbing unit with respect to the direction of the air flow in the duct, so that air is introduced into the moisture absorbing unit.

In the air conditioning system according to the present invention, the heat absorbing portion may be formed such that one surface thereof is in contact with the moisture absorption portion, and the other surface is exposed to the outside of the flow path.

In the air conditioning system according to the present invention, the dehumidifying unit may further include a radiating fin disposed on the other surface of the heat absorbing portion and discharging the heat of the heat absorbing portion to the outside of the flow path.

In the air conditioning system according to the present invention, the air purifying passage may include a first door portion disposed in front of the dehumidifying unit with respect to an air flow direction in the flow path, And a second door part disposed at the rear of the dehumidifying unit with respect to the air flow direction in the flow path and opening to discharge the outside air introduced into the flow path.

An air conditioning method according to the present invention is an air conditioning method for purifying air in an indoor space, comprising the steps of: introducing air in an indoor space into a flow path connected to an air outlet through an air outlet connected to one side of the indoor space; Removing water vapor in the air flowing into the flow path through at least one dehumidifying unit disposed in the flow path; And discharging the steam-depleted air along the flow path and discharging it through the air inlet connected to the flow path to the indoor space. Here, the dehumidifying unit is disposed across the inside of the flow path, and includes a moisture absorbing portion including oyster shell powder that absorbs water vapor in the air; And a heat absorbing portion contacting the one side of the moisture absorbing portion to remove the heat of adsorption of the moisture absorbing portion.

In the air conditioning method according to the present invention, the heat absorbing portion includes a thermoelectric element having a Peltier effect, and the heat absorbing portion can remove the heat of adsorption through an endothermic reaction by applying an electric current.

In the air conditioning method according to the present invention, drying the oyster shell powder of the moisture absorption portion may further include:

In the air conditioning method according to the present invention, drying the oyster shell powder may include the steps of introducing outside air into the channel; Passing outside air through the moisture absorption portion to remove water vapor adsorbed on the oyster shell powder; And discharging the outside air passing through the moisture absorption portion to the outside of the flow path.

In the air conditioning method according to the present invention, when the outside air flows into the flow path, the air outlet port and the air inlet port of the flow path can be closed.

In the air conditioning method according to the present invention, water vapor adsorbed on the oyster shell powder can be removed by inducing an exothermic reaction in the heat absorbing part including the thermoelectric element.

According to the embodiments of the present invention, by recycling the fishery by-products, the air can be cleaned efficiently and efficiently.

In addition, according to the embodiments of the present invention, air can be purified quietly by not using a compressor or a refrigerant. Also, the structure of the apparatus is simple, and it is possible to economically clean the air by reducing the installation, maintenance and operation cost of the apparatus.

1 is a schematic diagram illustrating an air conditioning system according to an embodiment of the present invention.
2 is a conceptual diagram showing a phenomenon of absorbing water vapor in a moisture absorption portion in an air conditioning system according to an embodiment of the present invention.
Figs. 3A and 3B are enlarged views showing the area A in Fig.
4 is a configuration diagram illustrating the operation of the air conditioning system according to an embodiment of the present invention.

Hereinafter, the air conditioning system and the air conditioning method using the oyster shell according to the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Wherein like reference numerals refer to like elements throughout.

In the drawings, the thickness is enlarged to clearly represent the layers and regions. In the drawings, for the convenience of explanation, the thicknesses of some layers and regions are exaggerated. It will be understood that when a layer, film, region, plate, or the like is referred to as being "on" another portion, it includes not only the other portion "directly on" but also the other portion in between.

Also, throughout the specification, when an element is referred to as " including " an element, it is understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise. Also, throughout the specification, the term " on " means to be located above or below a target portion, and does not necessarily mean that the target portion is located on the image side with respect to the gravitational direction.

1 is a schematic diagram illustrating an air conditioning system according to an embodiment of the present invention.

The air conditioning system according to an embodiment of the present invention is a system for purifying air in an indoor space, and includes an air conditioning furnace 100 and at least one dehumidifying unit 200.

The air conditioning furnace 100 is a means for discharging the air in the indoor space IS and purifying it and then introducing the purified air into the indoor space IS and includes an air outlet 110 connected to one side of the indoor space IS, And an air inlet port 120 connected to the other side of the air inlet port IS and connected to the air inlet port 120 from the air outlet port 110. [ The air in the indoor space IS flows into the flow path 102 through the air outlet 110 and moves along the flow path 102. After passing through the air flow path, the air in the indoor space IS passes through the air inlet 120 again, Respectively. It is possible to circulate the air repeatedly several times depending on the state of the air in the indoor space IS.

1, it is preferable that the flow path 102 has a path 102a formed by bending at least one time, as shown in FIG. 1, in order to secure a heat exchange time in the dehumidifying unit 200 or the heat exchanging unit 300 This is to lower the air flow rate.

The air outlet 110 is formed at the lower end of the indoor space IS and the air inlet 120 can be formed at the upper end of the indoor space IS, In order to circulate air. The discharge air blowing fan 112 can be disposed in the air discharge port 110 so that the air in the indoor space IS can flow smoothly into the flow passage 102 and the flow of air in the flow passage 102 can be facilitated. have. Similarly, the air inlet 120 may be provided with an inlet blowing fan 122 to smoothly flow the conditioned air passing through the flow passage 102 into the indoor space IS, It can help flow.

The dehumidifying unit 200 is an apparatus for removing water vapor contained in room air introduced into the flow path 102 and is disposed in the flow path 102 along at least one of the flow paths 102. The dehumidifying unit 200 includes a moisture absorbing unit 210 and a heat absorbing unit 220.

The moisture absorbing portion 210 is a means for removing water vapor contained in the room air by making contact with the room air introduced into the channel 102. In order to make all the air passing through the channel 102 pass through the moisture absorbing portion 210, 102). The moisture absorption portion 210 includes the oyster shell powder 210, which is a oyster shell, which is a dispersion generated in the oyster style, and has a property of adsorbing moisture. The moisture absorption portion 210 is made of powder by crushing the oyster shell angle to widen the surface area in contact with air.

2 is a conceptual diagram showing a phenomenon of absorbing water vapor in a moisture absorption portion in an air conditioning system according to an embodiment of the present invention.

The water vapor (VW) particles contained in the indoor air enter between the fine pores 214 formed on the surface of the oyster shell powder 212 constituting the moisture absorption portion 210. The water vapor (VW) particles are adsorbed on the oyster shell powder 212 through the surface and micropores 214. By doing so, the moisture absorption unit 210 can reduce the latent heat load of the air conditioning system according to the present embodiment.

The heat absorbing portion 220 abuts on one side of the moisture absorbing portion 210 to remove the heat of adsorption generated in the moisture absorbing portion 210. The heat absorbing portion 220 may be composed of a thermoelectric element having a Peltier effect that generates heat or absorbs heat when a current flows through the two dissimilar metal junctions. That is, when the power source is applied, the heat absorbing unit 220 generates an endothermic reaction and absorbs the heat of adsorption generated in the moisture absorbing unit 210. By utilizing the properties of the thermoelectric element that undergoes an endothermic reaction, no separate compressor or coolant is required in the dehumidifying unit 200, so that the installation is simple, noise and vibration are prevented, power consumption is reduced, The system can be used environmentally friendly. The heat absorbing unit 230 is connected to the power supply unit and is operated by receiving power from the power supply unit, which will be described later.

The heat absorbing portion 220 may be formed in a plate shape as shown in FIG. 1, and one surface may contact the moisture absorbing portion 210. Of course, the heat absorbing portion 220 is not limited to this shape, If the shape is variously changed, it can be implemented. The heat absorbing part 220 may be provided as a pair facing each other, and the moisture absorbing part 210 may be disposed between the pair. The heat absorbing portion 220 may be formed such that one surface of the heat absorbing portion 220 is in contact with the moisture absorbing portion 210 and the other surface of the heat absorbing portion 220 is exposed to the outside of the flow path 210. In this case, the heat dissipation fin 230 may be disposed on the other surface of the heat absorbing portion 220 to efficiently discharge the heat absorbed by the heat absorbing portion 220 to the outside.

3A and 3B are enlarged views showing a region A of FIG. 1, wherein FIG. 3A shows adsorption of water vapor in the air by the moisture absorption portion 210, FIG. 3B shows absorption of water vapor in the air by the moisture absorption portion 210 and the heat absorption portion 220 ). ≪ / RTI >

As shown in FIG. 3A, the air having the water vapor (WV) passes through the flow path 102 and is adsorbed by the moisture absorption portion 210, and the humidity of the air is lowered. At this time, adsorption heat is generated in the moisture absorption portion 210, and the heat of adsorption is externally discharged through the heat absorption portion 220 contacting the moisture absorption portion 210 as shown in FIG. 3B. The heat absorbed by the heat absorbing portion 220 can be discharged to the outer surface of the heat absorbing portion 220 through the heat dissipating fin 230.

The dehumidifying unit 200 may further include a dehumidifying unit blowing fan 240 disposed in front of or behind the moisture absorbing unit 210 with respect to an air flow direction in the flow path 102. The dehumidifying unit blowing fan 240 allows the air to pass through the moisture absorbing unit 210 without stagnation due to the moisture absorbing unit 210. When the air blowing fan 240 is disposed in front of the moisture absorbing unit 210, the air in the air flow channel 102 can be introduced into the moisture absorbing unit 210. When the air blowing fan 240 is connected to the moisture absorbing unit 210, The air in the hygroscopic unit 210 can be discharged to the flow path 102.

The heat exchange unit 300 is disposed inside the flow path 102 as means for sensibly cooling the air flowing from the air outlet 110 to the air inlet 120. For efficient sensible heat cooling, the heat exchanging part 300 is preferably disposed behind the dehumidifying unit 200 with respect to the air flow direction. This is because the air in which the steam is removed to a certain degree by the dehumidifying unit 200 can be easily sensed and cooled. The heat exchanging unit 300 is connected to the power supply unit and is operated by receiving power from the power supply unit, which will be described later.

A plurality of heat exchange units 300 may be disposed along the flow path 102. Further, the heat exchanging unit 300 may be disposed in the curved path 102a of the flow path 102 having a low air flow rate to ensure a heat exchange time. The baffle 500 for lowering the airflow rate may also be formed in the flow path 102 adjacent to the heat exchange unit 300. As shown in FIG. 1, the baffle 500 may be formed such that a plurality of shielding plates 510a and 510b are staggered so that the air meanders. However, the baffle 500 is a mesh- It can be selected from a variety of configurations that can slow the flow of air, such as structures or perforated plates.

The heat absorbing unit 220 or the heat exchanging unit 300 of the dehumidifying unit 200 including the thermoelectric element receives the power and absorbs the heat. The power can be supplied through the solar power supplying unit 400. The solar power supply unit 400 converts sunlight absorbed through the solar module 410 into electrical energy and stores the converted electrical energy into a DC current through a rectifier 420 and then through a variable resistor 430, (220) or the heat exchange unit (300).

The oyster shell powder 212 contained in the moisture absorption unit 210 of the dehumidifying unit 200 can receive the water vapor VW by circulating the air in the indoor space IS through the air purifier 100 several times. The water vapor (VW) can no longer be absorbed beyond the limit. In this case, it is necessary to dry the oyster shell powder 212 and desorb the water vapor VW adsorbed on the oyster shell powder 212.

4 is a configuration diagram illustrating the operation of the air conditioning system according to an embodiment of the present invention.

The air conditioning system according to an embodiment of the present invention includes a first door portion (not shown) disposed in front of the dehumidifying unit 200 and opening to introduce outside air into the flow path 102, 600a and a second door portion 600b which is disposed behind the dehumidifying unit 200 and opens to discharge the outside air introduced into the flow path 102 based on the direction of air flow in the flow path 102 .

The first door portion 600a and the second door portion 600b are closed when the air in the indoor space IS is circulated and purified through the air purifier 100. [ When the oyster shell powder 212 is no longer able to absorb the water vapor VW during the air purification operation, the first door portion 600a and the second door portion 600b are opened to allow external air to flow through the flow path 102, Lt; / RTI > The outside air flowing through the first door portion 600a flows along the flow path 102 and then flows through the moisture absorption portion 210 of the dehumidifying unit 200 and then flows along the flow path 102, And then flows out of the oil passage 102 through the oil passage 600b. The oyster shell powder 212 of the moisture absorption unit 210 is dried by the flow of the external air, and the adsorbed water vapor can be desorbed.

The first door portion 600a and the second door portion 600b may be disposed at both ends of the straight path of the flow path 1020 as shown in FIG. 4 so that the outside air can flow smoothly. The first door portion 600a and the second door portion 600b are formed with an outside air blowing fan (not shown) so that outside air can smoothly flow in and out.

The air outlet 110 and the air inlet 120 are closed so that outside air is not directly introduced into the indoor space IS in a state where the first door portion 600a and the second door portion 600b are opened The shutters 700a and 700b may be formed in the flow path 102, respectively. The shutters 700a and 700b are opened to allow air to flow along the flow path 102 during the air cleaning operation and when the first door portion 600a and the second door portion 600b are opened to introduce outside air Lt; / RTI > The first door portion 600a and the second door portion 600b may be disposed at both ends of the straight path of the flow path 1020 as shown in FIG. 4 so that the outside air can flow smoothly.

The heat absorbing part 220 composed of the thermoelectric element removes the heat of adsorption generated in the moisture absorbing part 210 by applying a current so that an endothermic reaction occurs during the air purification. When the external air is introduced as described above, The polarity of the current applied to the device can be changed so that the exothermic reaction can be generated in the heat absorbing portion 220. The water vapor adsorbed on the oyster shell powder 212 of the moisture absorption unit 210 can be efficiently removed by heating the heat absorption unit 220.

The air conditioning system according to an embodiment of the present invention is connected to the heat absorbing portion 220, the first door portion 600a, the second door portion 600b and the shutters 700a and 700b of the dehumidifying unit 200, And a control unit (not shown) for controlling the operation.

The oyster shell powder 212 of the moisture absorber 210 reaches a state in which the water vapor VW can not be adsorbed through the mass sensor or the like attached to the moisture absorber 210 The control unit opens the first door unit 600a and the second door unit 600b and drives the shutters 700a and 700b to move the air outlet 110 and the air inlet 120 Can be closed.

In this case, the control unit may change the polarity of the current applied to the thermoelectric element of the scavenging unit 200 in the heat absorbing unit 220 so that the exothermic reaction occurs in the heat absorbing unit 220.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the present invention.

100: air conditioning furnace 110: air outlet
120: air inlet 200: dehumidifying unit
210: moisture absorption portion 220:
230: heat dissipating unit 240: blowing fan
300: heat exchanger 400: solar power supply

Claims (18)

An air conditioning system for purifying air in an indoor space,
An air outlet connected to one side of the indoor space and an air inlet connected to the other side of the indoor space, and an air flow passage connected from the air outlet to the air inlet; And
At least one dehumidifying unit disposed in the flow passage and removing water vapor from air flowing from the air outlet to the air inlet;
/ RTI >
The dehumidifying unit
A moisture absorption portion disposed across the inside of the flow path and containing oyster shell powder absorbing water vapor in the air; And
A heat absorbing portion contacting the one side of the moisture absorbing portion to remove the heat of adsorption of the moisture absorbing portion;
. The method according to claim 1,
And a heat exchange unit disposed inside the flow passage for sensing and cooling the air flowing from the air outlet to the air inlet. 3. The method of claim 2,
Wherein the heat absorbing portion and the heat exchanging portion include a thermoelectric element having a Peltier effect. The method of claim 3,
Wherein the heat absorbing unit and the heat exchanging unit are powered by a solar power supply unit. The method according to claim 1,
A discharge blowing fan disposed in the air discharge port for allowing air in the indoor space to flow into the flow passage,
And an inflow ventilating fan disposed in the air inlet for allowing the air passing through the air passage to flow into the indoor space. The method according to claim 1,
Wherein the air outlet is formed at a lower end of the indoor space,
Wherein the air inlet is formed at an upper end of the indoor space. The method according to claim 1,
Wherein the flow path includes a path formed by bending at least once. The method according to claim 1,
The air-
Further comprising a baffle in which a plurality of shielding plates are staggeredly arranged in the flow path so that air in the flow path meanders. The method according to claim 1,
The dehumidifying unit
Further comprising a dehumidification unit blowing fan disposed in front of the moisture absorption unit to guide the air to the moisture absorption unit based on an air flow direction in the flow passage. The method according to claim 1,
The heat absorbing portion
Wherein one surface is in contact with the hygroscopic portion and the other surface is exposed to the outside of the flow path. 11. The method of claim 10,
The dehumidifying unit
And a radiating fin disposed on the other surface of the heat absorbing portion and discharging the heat of the heat absorbing portion to the outside of the flow path. The method according to claim 1,
The air-
A first door portion disposed in front of the dehumidifying unit with respect to an air flow direction in the flow path and opening to introduce outside air into the flow path; And
And a second door portion disposed at a rear side of the dehumidifying unit with respect to an air flow direction in the flow path and opening to discharge outside air introduced into the flow path. An air conditioning method for purifying air in an indoor space,
Introducing air in the indoor space into an air passage connected to the air outlet through an air outlet connected to one side of the indoor space;
Removing water vapor in the air flowing into the flow path through at least one dehumidifying unit disposed in the flow path; And
Discharging the steam-removed air along the flow path and discharging the air through the air inlet connected to the flow path to the indoor space;
/ RTI >
The dehumidifying unit
A moisture absorption portion disposed across the inside of the flow path and containing oyster shell powder absorbing water vapor in the air; And
A heat absorbing portion contacting the one side of the moisture absorbing portion to remove the heat of adsorption of the moisture absorbing portion;
. 14. The method of claim 13,
Wherein the heat absorbing portion includes a thermoelectric element having a Peltier effect, and the heat absorbing portion applies current to remove the heat of adsorption through an endothermic reaction. 15. The method of claim 14,
And drying the oyster shell powder of the moisture absorber. 16. The method of claim 15,
The step of drying the oyster shell powder
Flowing outside air into the flow path;
Passing the outside air through a moisture absorption unit to remove water vapor adsorbed on the oyster shell powder;
And discharging outside air having passed through the moisture absorber to the outside of the flow path. 17. The method of claim 16,
And closing the air discharge port and the air inlet port of the flow passage when the outside air flows into the flow passage. 17. The method of claim 16,
When the water vapor adsorbed on the oyster shell powder is removed,
And inducing an exothermic reaction in the heat absorbing part including the thermoelectric element to remove the water vapor.

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