KR20160067610A - Using a fuel cell heat recovry drying unit and its dry method - Google Patents

Abstract

The present invention provides a drying device using fuel cell heat recovery, which can be applied to home appliances and houses as a device using fuel cell heat, and a drying method thereof. According to the present invention, the drying device using fuel cell heat recovery comprises a dehumidifying rotor (20) and a heat exchange unit (53). The drying device dehumidifies the indoor air with heat of a fuel cell, and can always use the heat of the fuel cell for other purposes than hot water and heating, although a conventional method enables limited heat utilization. Thus, the present invention can increase usage of the fuel cell and heat energy, raise the standard of living, and provide a constant pleasant indoor environment.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a drying apparatus for recovering a fuel cell array,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drying apparatus using a fuel cell array recovery and a drying method thereof, and more particularly, to a drying apparatus using a fuel cell array recovery apparatus applicable to a life- ≪ / RTI >

R & D on new and renewable energy has been actively conducted around the world in order to solve the problem of energy supply and demand due to depletion of fossil fuels and to cope with various environmental regulations such as GHG reduction policy. Among them, fuel cell is a technology that generates energy through electrochemical reaction using hydrogen as a fuel. It has no concern about depletion of energy source, can realize high power generation efficiency, and does not discharge pollutants. Ultimately, it is attracting attention as a technology that can be solved.

In addition, recent energy production and supply methods are changing to form distributed cogeneration systems that maximize utilization efficiency and minimize transmission and distribution losses. Fuel cells have a comparative advantage in terms of high conversion efficiency and environmental friendliness when compared to other distributed generation systems such as gas engines, gas turbines, and the like.

Such a fuel cell technology can be applied to various fields such as portable, building, transportation, power generation, and emergency power supply. Among them, fuel cells used in houses and small commercial buildings are mainly PEMFC (Polymer Electrolyte Membrane Fuel Cell: PEMFC), which is considered to be the closest to commercialization. PEMFC is a system in which natural gas is reformed into hydrogen (Reforming), it is advantageous to expand the supply using the existing city gas network even before the hydrogen infrastructure is established.

According to the prior art that proposes such a fuel cell system, Korean Patent Registration No. 10-1416397 entitled " Fuel cell system and its operation method "improves power generation safety, maintains operation of an air blower safely and improves overall durability And Korean Patent Laid-Open Publication No. 10-2007-0038515 proposes a device and a control method capable of maximizing utilization efficiency of fuel by stably coping with fluctuations in fuel cell system "fuel cell system" .

In the fuel cell system described above, electricity and heat are produced at the same time because of the characteristics of the system, and the ratio can not be freely adjusted. On the other hand, the demand for energy changes rapidly during the day and increases or decreases according to the seasons. Thermal energy tends to fluctuate more rapidly than electricity, and the heat left unused is lost.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the problems of the related art, and it is an object of the present invention to provide a system capable of using thermal energy of a fuel cell for domestic and industrial appliances that operate by using electricity and gas as a heat source, And at the same time, it is an object of the present invention to provide a drying apparatus using a new type of fuel cell array recovery which can reduce the energy cost required for operation of the apparatus, and a drying method thereof.

In addition, by providing a drying device that can utilize the heat of the fuel cell at all times in addition to hot water and heating by raising the heat utilization rate experienced by the actual user compared to the heat recovery efficiency, And a drying method using the same.

According to an aspect of the present invention, there is provided a drying apparatus using thermal energy of a fuel cell, the drying apparatus comprising: a dehumidifying rotor (20) rotating and drying humid air in a room; A drive motor (3) for driving the dehumidification rotor (20) to rotate; An inlet (41) for sucking humid air into the dehumidification rotor (20); An indoor air circulation blower 43 for delivering the dried air to the room through the humid air sucked into the suction port 41; A regeneration air inlet port (51) for sucking regeneration air for removing moisture from the outside of the dehumidification rotor (20); A heat exchange unit (53) used to raise the temperature of the regeneration air sucked from the regeneration air intake port (51) by supplying thermal energy to the arrangement of the fuel cells; The regeneration air passing through the heat exchange unit (53) is transferred to the dehumidification rotor (20) to regenerate the dehumidification rotor (20) which absorbs moisture with moist air, and the regeneration air A blower 55 for blowing air; The indoor air circulation fan 43, the reconditioning air intake port 51, the heat exchanging unit 53 and the reconditioning air blowing fan 55 are accommodated in the housing 50, the dehumidifying rotor 20, the driving motor 3, the suction port 41, A case (30) having an inner portion to be opened and closed; A control module provided outside the case (30) to adjust the rotational speed of the dehumidification rotor (20); The dehumidifying structure may be formed through the heat exchanging unit 53 using the arrangement number of the fuel cells.

In the drying apparatus using the recovered fuel cell array, the humid air and the regeneration air may be separated into a partition wall so as not to be mixed with each other inside the case 30. [

In the drying apparatus using the fuel cell array recovery, the indoor air circulation blower 43 may further include an air filter to provide indoor air.

According to an aspect of the present invention for achieving the above object, there is provided a drying method using thermal energy of a fuel cell, comprising: a suction step of sucking humid air in a room; A drying step in which the humid air in the suction step passes through the dehumidification rotor 20 to dry air; A drying step of drying the dehumidifying rotor (20); and a drying step of drying the dehumidified rotor (20). Wherein the desiccant rotor drying step comprises: a regeneration air sucking step of sucking regeneration air from the outside; A regeneration air heating step of increasing the temperature of the regeneration air to an arrangement of the fuel cells; A passing step in which the regeneration air is heated and passed through the dehumidification rotor (20); And a discharging step of discharging the regeneration air containing the moisture of the dehumidifying rotor 20 to the outside in the passing step, so that the dehumidifying rotor 20 can be dehumidified by using the arrangement number of the fuel cell.

In the drying method using the recovered fuel cell array, the humid air and the reconditioning air may be separated into the partition walls so as not to be mixed with each other, thereby performing the drying method.

According to the drying apparatus and the drying method using the recovered fuel cell array according to the present invention, the dehumidification rotor 20 and the heat exchanging unit 53 are provided to dehumidify the indoor air by arranging the fuel cells, In addition to the hot water and heating provided by the heat utilization rate, the drying device using the fuel cell array recovery which can always use the heat of the fuel cell and the drying method thereof are provided to increase the utilization rate of the fuel cell, And a pleasant indoor environment can be maintained.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a dehumidification structure of a desiccant system;
2 illustrates a drying apparatus using a fuel cell arrangement recovery according to a preferred embodiment of the present invention;
3 shows a dehumidification rotor according to a preferred embodiment of the present invention;
4 is a flowchart illustrating a drying method using a fuel cell arrangement recovery according to a preferred embodiment of the present invention;
5 is a flowchart showing a dehumidification rotor drying step according to a preferred embodiment of the present invention.

1 is a view showing a dehumidification structure of a desiccant system.

Generally, dehumidifiers are mainly sold by small home appliance companies for compressor type products, decency type and hybrid type products for industrial use and building use mainly by air conditioning and dehumidifying companies. Since the compressor type consumes a large amount of power, desiccant dehumidifiers tend to be introduced to dehumidify in domestic and small buildings. The desiccant is mainly used by applying an inorganic material such as silica gel.

1, the desiccant dehumidifier 1 is provided with a disc rotor 2 whose center is located in the form of a desiccant, and the rotor 2 is driven by the belt 4 at a speed of less than 20 revolutions per hour The room air slowly rotating by the motor 3 passes through the rotor 2, and moisture is supplied to the decanter and the humidity is lowered, and then the air flows back into the room through the blower 5. At this time, the desiccant having the moisture is dried by the heat treatment (6) of the reconditioning air introduced from the outside, and the reconditioning air of which the humidity is increased is discharged to the outside through the exhaust port (7). At this time, the room air and the regeneration air are separated into the partition walls so as not to be mixed with each other inside the dehumidifier 1, and the heat of adsorption is generated when the room air provides moisture to the desiccant, and in order to smoothly remove the moisture of the desiccant Heat energy should be supplied to the regeneration air.

The desiccant dehumidifier (1) can be applied to a drying apparatus using the recovered fuel cell array, which is an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 2 to 5. On the other hand, a technique for driving a fuel cell, a technique for enabling heat generated in a stack of a fuel cell to be stored in a heat storage unit, a technique for forming a partition wall for preventing air mixing of a desiccant, It will be apparent to those skilled in the art to which the present invention applies and those skilled in the relevant arts, and those skilled in the art to which the present invention pertains, .

2 is a diagram illustrating a drying apparatus using a fuel cell array recovery according to a preferred embodiment of the present invention. 3 is a view showing a dehumidifying rotor according to a preferred embodiment of the present invention.

2 and 3, the drying apparatus 10 using the fuel cell arrangement recovery includes a dehumidifying rotor 20, a driving motor 3, an inlet 41, an indoor air circulating fan 43, A heat exchange unit 53, a blower for feeding regeneration air 55, a case 30, and a control module (not shown).

As described above, the drying apparatus using the thermal energy of the fuel cell includes the driving motor 3 for driving the rotating dehumidification rotor 20 and the dehumidification rotor 20 to dry humid air in the room. A suction port 41 for sucking humid air through the dehumidification rotor 20 and an indoor air circulation fan 43 for transferring the dried humid air sucked by the desiccant rotor 20 to the room do. On the other hand, there is provided a regeneration air inlet port 51 for sucking regeneration air to remove moisture from the outside of the dehumidification rotor 20, and regenerated air sucked from the regeneration air inlet port 51 is supplied with thermal energy in an array of fuel cells And a heat exchanging unit 53 used to increase the temperature of the dehumidifying air. The regeneration air passing through the heat exchanging unit 53 is transferred to the dehumidifying rotor 20 to regenerate the dehumidifying rotor 20 in which moisture is adsorbed by the humid air, And a recuperative air transfer blower 55 for discharging the humid recycle air passing therethrough to the outside. In addition, the dehumidification rotor 20, the driving motor 3, the inlet port 41, the indoor air circulation fan 43, the reconditioning air intake port 51, the heat exchanging unit 53, And a control module provided on the outside of the case 30 to adjust the rotational speed of the dehumidifying rotor 20. [

The dehumidification rotor 20 and the drive motor 3 are applicable to the desiccant dehumidifier 1 with reference to Fig. 1, the dehumidification rotor 20 is controlled by the drive motor 3, And can be removed by a user so as to be operated or stopped by an externally provided control module.

3, the dehumidifying rotor 20 according to the embodiment of the present invention has a large surface area to increase the contact area with air, reduce the steam transmission resistance, and at the same time, Shaped microstructure.

The suction port 41 is provided at one side of the case 30 to allow humid indoor air to be sucked into the case 30. The humid indoor air can be dried by the desiccant rotor 20.

The indoor air circulation blower 43 provides humid room air through the dehumidification rotor 20 to the room, and in the embodiment of the present invention, the maximum air volume is 360 m 3 / h, but is not limited thereto .

The regeneration air inlet 51 sucks the regeneration air from the outside, and the temperature of the regeneration air is increased by the heat exchanging part 53.

The heat exchanging unit 53 uses a plate pin type coil having a capacity of 700 kcal / h to store the heat energy by collecting the arrangement generated in the stack of the fuel cell.

The recirculated air blowing fan 55 is a device for causing the reconditioning air heated by passing through the heat exchanging part 53 to pass through the dehumidifying rotor 20 to discharge the moisture of the dehumidifying rotor 20 back to the outside, The maximum air flow rate is 360 m 3 / h as in the case of the air blower 43, but is not limited thereto.

The case 30 is formed to have a size capable of accommodating the above-described configuration, and may include a control module on the outside or be installed in any one of the indoor spaces to enable the device to be driven. The case 30 is provided with a structure in which the humid air and the regeneration air are separated into septa so as not to be mixed with each other inside the case 30. [ In addition, the indoor air circulation blower 43 may further include an air filter (not shown) to provide indoor air.

According to the drying apparatus 10 using the fuel cell array recovery, the dehumidifying rotor 20 and the heat exchanging unit 53 are provided to dehumidify the room air in the arrangement of the fuel cells, It is possible to increase the utilization rate of fuel cells, to improve the utilization of heat energy, to improve living standards, and to maintain a pleasant indoor environment by providing a drying device using a fuel cell array recovery which can always utilize the heat of the fuel cell in addition to hot water and heating .

4 is a flowchart showing a drying method using a fuel cell array recovery according to a preferred embodiment of the present invention. 5 is a flowchart showing a dehumidification rotor drying step according to a preferred embodiment of the present invention.

4 and 5, the drying method using thermal energy of the fuel cell is composed of a suction step, a drying step, and a supply step, and further includes a dehumidifying rotor drying step, Step, and discharge steps.

The drying method using the recovered fuel cell array according to the preferred embodiment of the present invention includes a suction step of sucking humid air in the room and a drying step of humid air in the suction step passing through the desiccant rotor 20 to dry the air, And a supplying step of supplying the air dried in the drying step to the room.

The desiccant rotor drying step further includes a dehumidifying rotor drying step of drying the dehumidification rotor 20. The dehumidifying rotor drying step includes a regeneration air sucking step of sucking regeneration air from the outside and a regeneration air heating step , And a discharging step of discharging the regeneration air containing moisture of the dehumidifying rotor (20) to the outside in the passing step in which the regeneration air is heated and passed to the dehumidifying rotor (20).

The suction step is a step of sucking the humid indoor air through the suction port 41 and providing it to the inside of the case 30.

The drying step allows the humid room air introduced through the inlet 41 to be dried by passing through the dehumidification rotor 20.

The supplying step has a supplying step by being supplied to the room through the indoor air circulating fan 43 for passing the dried air passing through the dehumidifying rotor 20 back into the room.

Meanwhile, the dehumidification rotor 20 has a dehumidifying rotor drying step to remove water by damping water through the above steps.

The regeneration air sucking step receives external regeneration air from the regeneration air intake port 51 connected to the outside.

In the regeneration air heating step, the regeneration air supplied from the outside recovers the arrangement of the fuel cells, passes through the heat exchange unit 53 having heat energy, and is heated to raise the temperature.

In the passing step, the regeneration air whose temperature has risen can be removed by passing through the dehumidification rotor 20, and the regeneration air having moisture is discharged through the regeneration air transfer blower 55 to the outside. At this time, the wet air and the regeneration air are separated into the partition walls in the case 30 so as not to be mixed with each other, and each drying method is performed.

The drying method using the recovery of the fuel cell array includes the dehumidifying rotor 20 and the heat exchanging part 53 to dehumidify the room air in the arrangement of the fuel cells, It is possible to increase the utilization rate of the fuel cell, to improve the utilization of heat energy, to improve the living standard, and to maintain a pleasant indoor environment by providing the drying device using the fuel cell array recovery capable of always using the heat of the fuel cell and the drying method thereof.

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. It will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the invention.

1: Desiccant dehumidifier 2: Rotor
3: drive motor 4: belt
5: blower 6:
7: Outlet
10: Drying device using fuel cell array recovery
20: dehumidification rotor 30: case
41: inlet port 43: indoor air circulation blower
51: regeneration air inlet port 53: heat exchange section
55: blower for regenerating air

Claims (5)

1. A drying apparatus using thermal energy of a fuel cell,
A rotatable dehumidification rotor 20 for drying humid air in the room;
A drive motor (3) for driving the dehumidification rotor (20) to rotate;
An inlet (41) for sucking humid air into the dehumidification rotor (20);
An indoor air circulation blower 43 for delivering the dried air to the room through the humid air sucked into the suction port 41;
A regeneration air inlet port (51) for sucking regeneration air for removing moisture from the outside of the dehumidification rotor (20);
A heat exchange unit (53) used to raise the temperature of the regeneration air sucked from the regeneration air intake port (51) by supplying thermal energy to the arrangement of the fuel cells;
The regeneration air passing through the heat exchange unit (53) is transferred to the dehumidification rotor (20) to regenerate the dehumidification rotor (20) which absorbs moisture with moist air, and the regeneration air A blower 55 for blowing air;
The indoor air circulation fan 43, the reconditioning air intake port 51, the heat exchanging unit 53 and the reconditioning air blowing fan 55 are accommodated in the housing 50, the dehumidifying rotor 20, the driving motor 3, the suction port 41, A case (30) having an inner portion to be opened and closed;
A control module provided outside the case (30) to adjust the rotational speed of the dehumidification rotor (20); Including
And a dehumidifying structure through the heat exchanging part (53) using the arrangement number of the fuel cells.
The method according to claim 1,
Wherein the humid air and the regeneration air are separated into septa so as not to be mixed with each other inside the case (30).
3. The method of claim 2,
Wherein the indoor air circulation blower (43) further includes an air filter to provide indoor air to the indoor space.
In a drying method using thermal energy of a fuel cell,
A suction step of sucking humid air in the room;
A drying step in which the humid air in the suction step passes through the dehumidification rotor 20 to dry air;
And a supplying step of supplying the air dried in the drying step to the room,
A dehumidification rotor drying step of drying the dehumidification rotor (20); Further included,
The dehumidifying rotor drying step includes a regeneration air sucking step of sucking regeneration air from the outside;
A regeneration air heating step of increasing the temperature of the regeneration air to an arrangement of the fuel cells;
A passing step in which the regeneration air is heated and passed through the dehumidification rotor (20);
And a discharging step of discharging the regeneration air containing the moisture of the dehumidifying rotor (20) to the outside in the passing step, wherein the dehumidifying rotor (20) has a dehumidifying structure by using the arrangement recovery of the fuel cell Drying method.
5. The method of claim 4,
Wherein the humid air and the reconditioning air are separated into septa so as not to be mixed with each other, thereby performing a drying method.

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