JP4607356B2 - Dehumidifying air conditioner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a dehumidifying air conditioner that uses a dehumidifying rotor to produce dry air, which is cooled and supplied to the room.
[0002]
[Prior art]
The dehumidifying air conditioner does not use chlorofluorocarbon, and because it uses heat as a driving energy source, it can use various types of energy such as gas combustion heat, exhaust heat, or solar heat, thus reducing carbon dioxide emissions. It has many features, such as being able to suppress power peaks in summer.
[0003]
A conventional dehumidifying air conditioner will be described with reference to FIGS. Reference numeral 1 denotes a blower that sends the atmospheric OA to the adsorption zone 3 of the dehumidifying rotor 2. As a result, the temperature of the air rises due to heat of adsorption and becomes dry air. Here, the dehumidifying rotor 2 is a paper in which a honeycomb (honeycomb) -like paper is loaded with a moisture absorbent such as silica gel or zeolite, and is rotated by a motor (not shown) via a belt or the like (not shown). It is driven. The dehumidifying rotor 2 has a shape as shown in FIG.
[0004]
Air exiting the adsorption zone 3 of the dehumidifying rotor 2 passes through the rotary sensible heat exchange element 4. Here, the rotary sensible heat exchange element 4 is a thin plate made of aluminum or the like formed in a honeycomb shape, and is rotationally driven by a motor (not shown) via a belt or the like (not shown). The rotary sensible heat exchange element 4 has a shape as shown in FIG.
[0005]
The dry air that has risen in temperature from the adsorption zone 3 exchanges heat with the rotary sensible heat exchange element 4 in the cooling zone 5, and the temperature of the dry sensible heat exchange element 4 decreases as the temperature of the dry air decreases. To do. This dried and cooled air is supplied into the room as product air SA.
[0006]
The atmosphere RA from the room is humidified and cooled by the spray 6. The air whose humidity has increased and the temperature has decreased passes through the rotary sensible heat exchange element 4 and exchanges heat with the rotary sensible heat exchange element 4 in the heating zone 7. That is, the temperature of the air rises while the rotary sensible heat exchange element 4 is cooled.
[0007]
The humid air whose temperature has risen is further heated by the heater 8 and enters the desorption zone 9 of the dehumidifying rotor 2. Here, the moisture adsorbed by the dehumidifying rotor 2 is desorbed and discharged to the atmosphere as exhaust EA by the fan 10. Here, the heater 8 is a heat exchanger or an electric heater to which steam is sent.
[0008]
[Problems to be solved by the invention]
Since the dehumidifying air conditioner as described above uses the rotary sensible heat exchange element 4 as a cooling means for dry air, there is a problem that a part of the air humidified by the spray 6 is brought to the product air SA side. .
[0009]
That is, the rotary sensible heat exchange element 4 is a honeycomb body, which has a shape in which thin tubes (flutes) are gathered, and performs heat exchange between the air passing through the flute and the sheets constituting the honeycomb body. In the heating zone 7, low temperature and high humidity air passes through the flute. Low temperature and high humidity air remains in the flute immediately after moving from the heating zone 7 to the cooling zone 5. The moisture contained in the low-temperature and high-humidity air like the high-temperature dry sky passing through the cooling zone 5 and gives the high-temperature dry air moisture.
[0010]
For this reason, although the temperature of the supplied air falls, there existed a problem that humidity became high and it became not very comfortable air. In particular, if the temperature of the heater 8 is lowered as much as possible to increase the energy efficiency, an effort is made to lower the absolute humidity of the dry air produced by the dehumidifying rotor 2 even by 1 g / Kg. In such a situation, if moisture is mixed in the dry air, there is a problem that the overall energy efficiency is lowered. The present invention is intended to solve the above-described problems, and an object of the present invention is to provide a dehumidifying air conditioner that can supply air with high efficiency and high comfort.
[0011]
[Means for Solving the Problems]
In order to solve the above-described problems, the present invention includes a dehumidification rotor that is desorbed by heated air and a heat exchange element that exchanges heat between the two flow paths, and heat-exchanges the air that has been dried by the dehumidification rotor. The air is supplied to the room through one passage of the element, and the air from the room is supplied to the other passage of the heat exchange element through the other passage of the heat exchange element.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
The invention according to claim 1 of the present invention includes a dehumidification rotor that is desorbed by heated air and a heat exchange element that exchanges heat between the two flow paths, and heats the air dried by the dehumidification rotor to the heat exchange element. The air is supplied to the room through one of the passages, the air from the room is passed through the other path of the heat exchange element, and water is supplied to the other path of the heat exchange element. When the water in the other passage of the heat exchange element is vaporized, one passage is cooled together with the other passage, and the air passing through the one passage is cooled without being humidified.
[0013]
【Example】
Hereinafter, a first embodiment of the dehumidifying air-conditioning apparatus of the present invention will be described in detail with reference to FIGS. Here, the blower 1, the dehumidification rotor 2, the adsorption zone 3, the spray 6, the heater 8, the desorption zone 9, and the blower 10 are the same as those shown in FIG. In order to avoid this, duplicate explanation is omitted.
[0014]
Reference numeral 11 denotes an orthogonal sensible heat exchange element, as shown in FIG. 2, in which the corrugated aluminum foil or synthetic resin film and the flat aluminum foil or synthetic resin film alternate and the wave directions alternate. It is constructed by laminating. Accordingly, the orthogonal sensible heat exchange element 11 has a first passage 12 and a second passage 13 which are orthogonal to each other, and sensible heat exchange is performed between the respective passages. Further, the gases passing through the two passages are not mixed.
[0015]
One passage 12 of the orthogonal sensible heat exchange element 11 communicates with the adsorption zone 3 of the dehumidification rotor 2, and the air exiting from one passage 12 of the orthogonal sensible heat exchange element 11 becomes product air SA. The spray 6 is provided to spray water on the other passage 13 of the orthogonal sensible heat exchange element 11, and the outlet of the other passage 13 of the orthogonal sensible heat exchange element 11 communicates with the heater 8.
[0016]
The outlet of the heater 8 communicates with the desorption zone 9 of the dehumidification rotor 2, and the outlet of the desorption zone 9 communicates with the suction port of the fan 10.
[0017]
The first embodiment of the present invention is configured as described above, and the operation thereof will be described below. First, the blower 1 and the blower 10 are energized to supply water to the spray 6. Further, the dehumidifying rotor 2 is rotated and the heater 8 is energized or steam is sent to bring the heater 8 into a heat generating state.
[0018]
The outside air OA is sent to the adsorption zone 3 of the dehumidification rotor 2 by the blower 1 and becomes dry air, and the temperature rises due to heat of adsorption. The dry air whose temperature has risen passes through one passage 12 of the orthogonal sensible heat exchange element 11.
[0019]
The dry air that has exited one passage 12 of the orthogonal sensible heat exchange element 11 exchanges heat with the air that passes through the other passage 13, and the temperature drops. The dry air whose temperature has decreased is supplied to the room as supply air SA.
[0020]
The indoor air RA is sucked by the blower 10 and first passes through the place where the spray 6 is installed. Since indoor air generally has a relative humidity of about 60 to 70%, water is vaporized and cooled by the spray 6.
[0021]
The air cooled by the spray 6 passes through the other passage 13 of the orthogonal sensible heat exchange element 11. The amount of water sprayed by the spray 6 is set to be equal to or greater than the amount of vaporization by spraying. As a result, water droplets enter the other passage 13 together with air. The water droplet having a small diameter floats in the air and enters the other passage 13, and the water droplet having a large diameter falls into the other passage 13.
[0022]
The small diameter water droplets suspended in the air are vaporized when the temperature in the other passage 13 is increased by heat exchange. Moreover, the big water droplet which fell in the other channel | path 13 wets the other channel | path 13 inner wall, and forms a thin layer of water. This thin layer of water is vaporized as the temperature of the inner wall of the other passage 13 increases due to heat exchange.
[0023]
Thus, the temperature in the other passage 13 of the orthogonal sensible heat exchange element 11 is lowered by the heat of vaporization of water. Since heat exchange is performed between the other passage 13 and the one passage 12, the temperature of the one passage 12 decreases.
[0024]
The air that has passed through the other passage 13 of the orthogonal sensible heat exchange element 11 enters the heater 8. Here, the heater 8 is a gas burner for burning a combustible gas such as natural gas or propane gas, a radiator for passing steam or hot water, or an electric heater. Alternatively, as long as the heater 8 is a heating unit, it may be a unit such as high-temperature exhaust gas from another combustion device or a mixed gas of high-temperature exhaust gas and air.
[0025]
The air heated by the heater 8 passes through the desorption zone 11 of the dehumidification rotor 2, desorbs moisture adsorbed by the moisture absorbent of the dehumidification rotor 2, and is released to the atmosphere by the blower 10 as exhaust EA. In this way, the outside air OA is supplied into the room as dry cold air, and the ambient air RA from the room is discharged into the atmosphere as hot and humid air.
[0026]
Hereinafter, a second embodiment of the dehumidifying air conditioner of the present invention will be described in detail with reference to FIG. Here, the blower 1, the dehumidifying rotor 2, the adsorption zone 3, the desorption zone 9, the blower 10, the orthogonal sensible heat exchange element 11, the first passage 12, and the second passage 13 are the same as those in the first embodiment. Therefore, a duplicate description is omitted.
[0027]
In the second embodiment, an exhaust passage 14 extending from the outlet of the second passage 13 of the orthogonal sensible heat exchange element 11 to the suction port of the blower 10 is provided. Further, a high temperature exhaust gas communication port 15 for introducing exhaust gas such as a gas turbine generator is provided in a region communicating with the desorption zone 9. Further, the bottom surface of the exhaust passage 14 is inclined, and a drain pipe 16 is provided at the lowest portion.
[0028]
The dehumidifying air conditioner of the second embodiment of the present invention is configured as described above, and the operation thereof will be described below. First, the blower 1 and the blower 10 are energized to supply water to the spray 6. Further, the dehumidifying rotor 2 is rotated and high-temperature exhaust gas such as a gas turbine generator is introduced into the high-temperature exhaust gas communication port 15.
[0029]
The outside air OA is sent to the adsorption zone 3 of the dehumidification rotor 2 by the blower 1 and becomes dry air, and the temperature rises due to heat of adsorption. The dry air whose temperature has risen passes through one passage 12 of the orthogonal sensible heat exchange element 11.
[0030]
The dry air that has exited one passage 12 of the orthogonal sensible heat exchange element 11 exchanges heat with the air that passes through the other passage 13, and the temperature drops. The dry air whose temperature has decreased is supplied to the room as supply air SA.
[0031]
The indoor air RA is sucked by the blower 10 and first passes through the place where the spray 6 is installed. Since indoor air generally has a relative humidity of about 60 to 70%, water is vaporized and cooled by the spray 6.
[0032]
The air cooled by the spray 6 passes through the other passage 13 of the orthogonal sensible heat exchange element 11. The amount of water sprayed by the spray 6 is set to be equal to or greater than the amount of vaporization by spraying. As a result, water droplets enter the other passage 13 together with air. The water droplet having a small diameter floats in the air and enters the other passage 13, and the water droplet having a large diameter falls into the other passage 13.
[0033]
The small diameter water droplets suspended in the air are vaporized when the temperature in the other passage 13 is increased by heat exchange. Moreover, the big water droplet which fell in the other channel | path 13 wets the other channel | path 13 inner wall, and forms a thin layer of water. This thin layer of water is vaporized as the temperature of the inner wall of the other passage 13 increases due to heat exchange.
[0034]
Thus, the temperature in the other passage 13 of the orthogonal sensible heat exchange element 11 is lowered by the heat of vaporization of water. Since heat exchange is performed between the other passage 13 and the one passage 12, the temperature of the one passage 12 decreases. The air that has passed through the other passage 13 of the orthogonal sensible heat exchange element 11 passes through the exhaust passage 14 and is released to the atmosphere by the blower 10.
[0035]
High temperature exhaust gas enters the high temperature exhaust gas communication port 15, passes through the desorption zone 9, and desorbs moisture adsorbed by the dehumidifying rotor 2. The exhaust gas that has passed through the desorption zone 9 becomes a humid gas and is released to the atmosphere by the blower 10.
[0036]
Water droplets dropped from the orthogonal sensible heat exchange element 11 accumulate at the bottom of the exhaust passage 14. Since the bottom of the exhaust passage 14 is inclined, the dropped water moves to the lower side and is led out from the drain pipe 16.
[0037]
Hereinafter, a third embodiment of the dehumidifying air conditioner of the present invention will be described in detail with reference to FIG. Here, the blower 1, the dehumidification rotor 2, the adsorption zone 3, the desorption zone 9, the blower 10, the orthogonal sensible heat exchange element 11, the first passage 12, the second passage 13, and the heater 8 of the above-described first embodiment The exhaust passage 14 is the same as that of the second embodiment, and a duplicate description is omitted.
[0038]
In FIG. 4, reference numeral 17 denotes a partition plate that divides a part of the entrance of the other passage 13 of the orthogonal sensible heat exchange element 11. A spray 6 is provided in a part of the other entrance of the other passage 13 to constitute a cooling passage 18. The amount of spraying by the spray 6 is such that water fine particles float in air having a relative humidity of 100%.
[0039]
The exhaust passage 14 extends from the outlet of the cooling passage 18 to the suction side of the blower 10. A valve 19 that opens / closes the exhaust passage 14 or adjusts the amount of air passing therethrough is provided in the middle of the exhaust passage 14.
[0040]
The dehumidifying air conditioner of the third embodiment of the present invention is configured as described above, and the operation thereof will be described below. The blower 20 is started, then a heater 8 such as a gas burner is ignited, and water is sent to the spray 6. Then, the outside air OA is sucked into the blower 1 and enters the blower 1, and is pushed out to the blower 1 and enters the adsorption zone 3 of the dehumidifying rotor 2. Here, the humidity of the outside air is adsorbed by the dehumidifying rotor 2 to become dry air, and the temperature rises due to the heat of adsorption.
[0041]
The dry air whose temperature has increased enters one passage 12 of the orthogonal sensible heat exchange element 11. Here, the dry air gives the sensible heat to the orthogonal sensible heat exchange element 11 and the temperature drops. That is, the temperature of the dry air that has exited one passage 12 of the orthogonal sensible heat exchange element 11 is lowered by the heat of vaporization of the water sprayed by the spray 6, and is supplied to the room as comfortable supply air SA.
[0042]
The indoor air RA enters the other passage 13 of the orthogonal sensible heat exchange element 11 by the suction of the blower 10. At this time, since the exhaust passage 14 has a negative pressure, the indoor air RA also enters the cooling passage 18. The air in the cooling passage 18 is humidified by the spray 6 to lower the temperature, and water fine particles are floating. The inner surface of the cooling passage 18 is wet with water.
[0043]
While passing through the cooling passage 18, the water fine particles and the water that wets the inner surface of the cooling passage 18 are vaporized by the air passing through one passage 12 of the orthogonal sensible heat exchange element 11, depriving the heat of vaporization into the exhaust passage 14. enter. Since only the sensible heat exchange is performed between the one passage 12 and the other passage 13 of the orthogonal sensible heat exchange element 11 and there is no mixing of both gases, the air in the one passage 12 and the cooling passage 18 are naturally. There is no mixing with the air inside. Therefore, the air passing through one passage 12 of the orthogonal sensible heat exchange element 11 is cooled without being humidified.
[0044]
The air that has exited the other passage 13 of the orthogonal sensible heat exchange element 11 undergoes heat exchange with dry air whose temperature has been increased by the heat of adsorption of the dehumidifying rotor 2, and the temperature rises. Become hot air. This high-temperature air passes through the desorption zone 11 of the dehumidification rotor 2 and desorbs moisture contained in the dehumidification rotor 2. The hot and humid air exiting the desorption zone 11 of the dehumidifying rotor 2 passes through the blower 10 and becomes exhaust EA, which is released to the atmosphere. Also, the air that has passed through the exhaust passage 14 is discharged into the atmosphere as exhaust EA together with the hot and humid air that has exited the desorption zone 11 of the dehumidifying rotor 2 by the blower 10.
[0045]
By adjusting the valve 19, the amount of air flowing into the exhaust passage 14 can be adjusted, and the temperature of the supply air SA can be controlled by this adjustment and the amount of spray from the spray 6.
[0046]
FIG. 5 is a sectional view showing a fourth embodiment of the present invention. Compared with the third embodiment shown in FIG. 4, the fourth embodiment of FIG. 5 is provided with a dedicated blower 20 for sucking out the air in the exhaust passage 14 and the outside air introduction pipe 21. However, the point that the valve 19 is not provided is different.
[0047]
That is, by providing a dedicated blower 20 for the exhaust passage 14, the amount of air flowing into the exhaust passage 14 can be controlled by controlling the blower 20.
[0048]
5 also has an outside air introduction pipe 21 that directly introduces outside air OA into the cooling passage 18. When a ventilation fan or the like (not shown) is installed in the room and the amount of return air RA from the room is smaller than the amount of air SA supplied to the room, the outside air OA is directly supplied to the cooling passage 18 from the outside air introduction pipe 21. It is good to supply.
[0049]
Alternatively, if there is a source of a large amount of moisture in the room, the humidity of the return air RA from the room is higher than the outside air. In such a case, if the outside air OA is supplied directly to the cooling passage 18 from the outside air introduction pipe 21, the cooling passage 18 The cooling effect is high.
[0050]
Furthermore, what is shown in FIG. 5 is provided with a humidifying element 22 at the outlet of one passage 12 of the orthogonal sensible heat exchange element 11. The humidifying element 22 has air permeability such as a non-woven fabric and has a high water retention capability. The tip of the humidifying element 22 protrudes into the cooling passage 18, and water is supplied by the spray water from the spray 6. .
[0051]
As a result, the air exiting from one passage 12 of the orthogonal sensible heat exchange element 11 is humidified and cooled, and the temperature further decreases. In other words, the supply air SA slightly increases in humidity but further decreases in temperature. This embodiment is suitable when the humidity of the outside air is low and the temperature is high.
[0052]
In this embodiment, an example of a non-woven fabric is shown as the humidifying element 22, but other than this, for example, if the non-woven fabric is hydrophilic, for example, a non-woven fabric formed in a honeycomb shape, or a felt-like one with a coarse mesh, A sponge having a large opening can be used.
[0053]
In each of the above embodiments, the orthogonal sensible heat exchange element 11 is used as a stationary heat exchange element. However, other than this, a counter flow type heat exchange element, a heat exchange element using a heat pipe, or the like can be used. .
[0054]
【The invention's effect】
Since the dehumidifying air conditioner of the present invention lowers the temperature of the supplied air by sensible heat exchange, the humidity of the supplied air does not increase, and highly comfortable air can be supplied. If the room air that has passed through the stationary heat exchanger does not pass through the dehumidification rotor as in the embodiment shown in FIGS. 3 to 6, for example, a lot of contaminants such as cigarette smoke are present in the room air as in a game hall. Even if it is used in a place where it is included, the room air does not come into contact with the dehumidification rotor, so that contamination of the dehumidification rotor can be prevented and indoor pollutants are not mixed into the supply air.
[0055]
In addition, both the recovery of exhaust heat (cooling of supply air by indoor cool air) and indirect evaporative cooling are performed by the static sensible heat exchange element, and the entire apparatus can be realized in a compact and low cost.
[0056]
In particular, since a static sensible heat exchange element is used as a heat exchanger, moisture is not brought in between the gases that exchange heat, and the humidity of the supply air can be kept low.
[0057]
When the humidity of the outside air is low, humidification cooling can be added. In this case, the temperature of the supply air can be further lowered.
[0058]
Furthermore, when there is a source of moisture in the room and the room air has a higher humidity than the outside air, the cooling effect is enhanced by passing the outside air through the other passage of the heat exchange element.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a first embodiment of a dehumidifying air conditioner according to the present invention.
FIG. 2 is a perspective view of an orthogonal sensible heat exchange element used in the dehumidifying air conditioner of the present invention.
FIG. 3 is a sectional view showing a second embodiment of the dehumidifying air conditioner of the present invention.
FIG. 4 is a cross-sectional view showing a third embodiment of the dehumidifying air conditioner of the present invention.
FIG. 5 is a sectional view showing a fourth embodiment of the dehumidifying air conditioner of the present invention.
FIG. 6 is a cross-sectional view of a conventional dehumidifying air conditioner.
FIG. 7 is a perspective view of a dehumidification rotor used in the present invention and a conventional dehumidification air conditioner.
[Explanation of symbols]
1 Blower 2 Dehumidification Rotor 3 Adsorption Zone 6 Spray 8 Heater 9 Desorption Zone 10 Blower 11 Orthogonal Sensible Heat Exchange Element 12 First Passage 13 Second Passage 14 Exhaust Passage 15 Hot Exhaust Gas Communication Port 16 Drain Pipe 17 Partition Plate 18 Cooling Passage 19 Valve

Claims (5)

A dehumidification rotor having a desorption zone so as to be desorbed by heated air, and a stationary heat exchange element that exchanges heat between the two flow paths, and air that has been dried by the dehumidification rotor Supplying air into the room through the passage, allowing air from the room to pass through the other passage of the heat exchange element, and supplying water to at least a part of the other passage of the heat exchange element , A dehumidifying air conditioner characterized in that air passing through a part of the passage passes through a passage different from the desorption zone of the dehumidifying rotor . The dehumidifying air conditioner according to claim 1, wherein hot air from the exhaust heat source is applied to a part of the dehumidifying rotor. The dehumidifying air-conditioning apparatus according to claim 1, wherein air discharged from one passage of the heat exchange element is humidified. The dehumidifying air conditioner according to claim 3 , wherein the air discharged from one passage of the heat exchange element is humidified by a water spray nozzle that creates air in which fine particles of water passing through the other passage of the heat exchange element are suspended. The dehumidifying air conditioner according to claim 1, wherein fine particles of water are suspended in the outside air and passed through a part of the other passage of the heat exchange element.

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